1
15
67
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/dd54d0d8b08bd4b0a13131e293534381.pdf
016cd5ce8b4d704ede36eba15677adcb
PDF Text
Text
Item H) Number
Author
00052
Boyer, Lester W.
Author
U.S. Army Biological Laboratories, Director of Biological
Research, Crops Division, Fort Detrick, Frederick,
Maryland
RUOrt/ArtlCto TiUfl Supplement II to Technical Report 46: Basic Data From H-34/Hidal Calibration Trials,
1963
Journal/Book Titio
Year
1964
Month/Day
June
Color
'
NumboroflmaDos
266
DOSCriptOn NOtOS
Project Agile under ARPA Order 256, some pages missing throughout the document
Friday, December 01, 2000
Page 62 of 91
�Cto\CAFT
Otvfl^ \CVvn
V
AD
c,
.
�THIS REi'CST HAS BEEN DELIMITED
AND ci ':A",EJ) pea pt. LIC RELIASB
oMSirri i so DIRECTIVE 5200,20 O
NO f;^sT;ncTic;;s A^E I^OSCD UPON
ITS l(,V£ /ED DISCLOSSfREi
T»t ••>•!*••• t v i . ' V f ««.r
PT'Tf1
'T
*
IiI:j|..i..JlICiI Si,',Id.:..!! A
/.. ;-;:OV.D FC« PU. i.ic u^LC
UNLIMITED,
�UNCLASSIFIED
2479
AD
DEFENSE DOCUMENTATION CENTER
FOR
SCIENTIFIC AND TECHNICAL INFORMATION
CAMERON S T A T I O N A l E X A N D R I A . VlhGINIA
UNCLASSIFIED
�NOTICE: When government or other dravlngs, specifications or other data are used for any purpose
other than In connection with a definitely related
government procurement operation, the U. S.
Government thereby Incurs no responsibility, nor any
obligation whatsoever; and the fact that the Government may have formulated, furnished, or In any way
supplied the said drawings, specifications, or other
data Is not to be regarded by implication or otherwise as in any manner licensing the holder or any
ether person or corporation, or conveying any rights
or permission to manufacture, use or sell any
patented invention that may In any way be related
thereto.
�2479
SUPPLEMENT
II
TO
TECHNICAL
REPORT
BASIC
46
DATA
®M H-34/HIDAL CALIBRATION TRIALS
1963
iO
Sponsored by
A d v a n c e d Research P r o j e c t s A g e n c y
Project Agile
D D C
ARPA Order 256
.IUU71G64
* i *
.
JUNE
1964
ODCIRA C
UNITED STATES ARMY
BIOLOGICAL LABORATORIES
FORT DETRICK
�U . S . AR' i BIOLOGICAL LABORATORIES
Fort r. trick, Frederick, Maryland
SUPPLEMENT II
to
TECHNICAL REPORT 46
BASIC DATA FROM
H-34/HIDAL CALIBRATION TRIALS
1963
This research was supported by the
Advanced Research Projects Agency
Project Agile under ARPA Order 256.
Lester W. Boyer
Jamos W. Brown
Crops Division
DIRECTOR OF BIOLOGICAL RESEARCH
1'rojecL ARPA Order 256
J-.-ne 1964
�This publication or any portion thereof may
noi be reproduced without specific authorization from the Commanding Officer, U. S. Army
Biological Laboratories,
AITN:
Technical
Releases Branch, Technical Information Division, Fort Detrick, Frederick,
Maryland.
However, DDC is authorized to reproduce the
publication for U. S. Government purposes.
The information in this publication has not
been cleared for release to the public.
DDC AVAILABILITY XOriCE
Q'l.iJtfied requestors may obtain copies of this
publication directly from DDC.
Foreign announcement and di-semination of this
publication by DDC is limited.
�INTRODUCTION
This supplement concerns the calibration of a modified H-34/HIDAL spray system
and presents the basic data and spray deposit patterns obtained in 100 test flights
c.t Eglin Air Force Base between 27 June and
16 July 1963. The data are presented in the
sequence of ground flow determinations, mass
median diameter calculations, and mass deposit measurements.
�SAMPLE AND EXPLANATION OF METEOROLOGICAL DATA
0°
Jib
•D 1
'rt
()
i
()
2
/
/ i 1
s«
n
row",
I *>.!'
(3)
(1)
(la)
Aircraft course
r~
7-, .
•
Station No. aircraft crossed
Calm
Met. data
station
c
JL_i ,
c
4
1C
(2)
/— • Wind current
/
()
3
150fc
()
6
Wind direction in
degrees
Altitude in •
feet, met.
data obtained
•Jalm
Met. data
station
(7)
£)£, (
\^ *^ ~* )
b
Q10
,_•
. ^
.
1 *'
1
1
•)
~
Wi-d
r-pped
W:.^d
speed
moV.
�Sky Conditions
Example:
100
25
1
3
1 - Cloud cover height in hundreds of feet
2 - Cloud Amount
0 - No clouds
Cp- Fair weather cumulus
OP - Variable sky
3 - Second cloud cover height in hundreds of feet
4 - Cloud Amount
5 - Barometric Tendency
/ Rising
- Steady
6 - Overcast
7 - Visibility in miles
Remarks
GFH - Ground Fog Heavy
N - North
OCNL - Occasional
E - East
C - Clouds
S - South
CLR - Clear
CU - Cumulus
CB -. Cumulo-nimbus
FQT - Frequent
W - West
LTG - Lightning
H - Haze
S - Smoke
�4.
H-34/HIDAL GROUND FLOW & FLIGHT DATA
DATE CM.IBRATED;
26 June 1963
DATE TEST FLOWN:
LIQUID SPRAYED;
Fuel Oil
TOTAL NOZZLES OPEN:
NOZZLE TYPES
LIQUID TEMP: _
8010
DURATION OF SPRAY:
30
Sec.
26
Gal.
•
BOOM PRESSURE:
60
^ F.
PS.:
PUMP PRESSURE:
TOTAL AMOUNT SPRAYED:
27 Tune 1963
FLOW RATE CALIBRATED:
OPERATIONAL DATA DURING FLIGHT
Run 1 - Shakedown flight
Run 2 - Pin sheared in pump
32
PS1
CPM
�s &:. IAN DlAMKTKIi
•!•
2i June 1963
DATE :
Si'liEAU rACl'OK:
o.O
FLIGHT #:
1
CONVERSION FACTOR:
SAMPLE LINE:
B
PAPER:
FLOW RATE .
•v •
Kromekote, white.
MATERIAL:
Fuel Oil
SYSTEM:
STA,
?8
n
78
78
78
78
78
79
79
79
DROP #
i
2
4
3
5
6
7
8
9
10
SIZE
3500*
3400
3300
3200
3100
3000
2900
2800
2700
2600
STA.
77
DROP *
1IIDAL
SIZE
75
:<KI) •= Spot U Max
= 3500
= 265.2 Microns
Spread Factor x Con. Factor 6.0x2.2
Max. Sph. Dia. - 3500 = 583.3 Microns
6.0
\\in. Sph. Di.i. -- 1°>_ - I/:.5 Microns
(S.O
2.2
�MAS:; DICPOSIV
'•.MJ-r.IAI.:
.\W.:;
i'i.:l Oil
I-'LOH K A T E :
27 June Iyo3
SYSTEM:
liIDAL
VMC.IT -v:
1
AIRSPEED:
55
.-.VJM-; LINE:
B
ALTITUDE:
100
i j X E Or RELEASE:
0437
PITIATION:
10
.NATION G . P . A .
STATION
b i ^ t i o n i i i - 50 lUank
Hours
AIRCRAFT COURSK:
rV'"t
.U5
Ddjjrcos
Sec.
G.P.A.
STATION C.P.A.
51
0.5
52
(1.5
53
0.3
5'i.
O./,
55
0.3
56
0.2
57
0.4
5&
0.3
V)
0.3
v"
0.2
61
o2
.'•3
iV.
1.3
iC
o7
K"
(-.-)
Vfi
/I
11
0.3
0.3
0.3
0.2
0.2 .
,) . 2
0.2
O.. 1
0.2
0.1
0.1
i/.l
;i
/j
Tot.-'l
l/..'i
%
i-. i
(i.i
j.i
STATION
7 to
1i
O..J
0.!
O.I
r)
o.r
<•(>
i'.l
O.J
;.2
o5
r.i
(.')
86
r./
fia
r,9
j()
91
92
•JJ
;'.
0:i
•M,
'J/
'.';>
•jj
(nii
i
B
.',
' ' • '*
(1.5
•'i. '•
0.
0..'.
0.3
0. >
0.',
O.'i
0.5
().'••
').•••
I).'.
0.1
I'."
'1. <
I'.l
''. »
o.>
�. ii 4..
.Lie ^.' *.„".'<].si ;....
'VE-,- 1 - 1 J^ ; J Si ; _
'CO !z-' 5 .''< 'i I ?•! :
:
.
c'
i I
1000
brili IM
int
2! J«» lt»l
Purl O i l . I'.!! >*V»
�MASS Mt'lLAN DIAMETER
27 June 196J
DATE.
SPREAD FACTOR'
6.0
r LIGHT #:
2
CONVERSION FACTOR-
SAMPLE LINE:
B
PAPER:
MATERIAL-
FLOW RATE:
SYSTEM:
STA.
DROP *
28
28
28
28
23
28
28
28
28
28
28
1
3
4
2
5
6
7
8
10
9
11
SIZE
4500
4000*
3900
3800
3700
3600
3500
3400
3300
3200
3100
HMD = Spct D Max
Spread Factor x Con. Factor
STA.
50
= 4000
6.0x2.2
Max. Sph. Dia. = 4500 = 750 Microns
6.0
Min. Sph. Dia. = 100
6.0
DROP #
16.7 Microns
2.2
Krcmckote. white
Fuel Oil
H7DAL
SIZE
100
= 303.0 Micr;;ns
�10
MASS DEPOSIT
MATERIAL:
DATi:
Fuel Oil
FLOW RATE:
27 June 1963
SYSTEM:
l:UGaT *:
2
AIRSPEED:
SAMPLE LINE:
B
ALTITUDE:
TIME OF RELEASE:
0440
DURATION:
Hours
14
55
Kn.-ts
100
AIRCRAFT COURSE:
Foot
315
Degrees
Sec.
STATION G.P.A.
STATION
Stations 1 - 2 6 Blank
•
HIDAL
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
44
46
47
48
49
50
G.P.A.
STATION G.P.A.
STATION
Stations 51 - 100 Blank
0.2
0.2
0.7
0.7
1.0
0.9
1.3
1.2
0.8
0.9
0.6
0.6
0.6
0.6
0.7
0.7
0.8
0.7
0.7
0.7
0.5
0.4
0.3
0.5
Total
12.4
G.l'.A.
�"T"
,».
\
r:i«M *
SMp.t
.li
T-p- A - ifll'r-* •
^
A . * 1! urt«
<*\
ex
•I,
. _i
—I—
ix
m
ixa
MM
lac
IMC
I
I
l*m* (l«ll
L
'
I
I
\at
1—
IUO
1«0
�12
H-34/HIDAL GROUND FLOW & FLIGHT DATA
DATB CALiaHATED:_ 1 July 1963
DATE TEST FLOWN;
LIQUID SPRAYED;
TOTAL NOZZLES OPEN:
2 Fuel Oil, 1 Purple
NOZZLE TYPE:.
GO 10
2 July 1963
60
LIQUID TEMP:
DURATION OF SPRAY; 30
TOTAL AMOUNT SPRAYED: 30
s«.c.
cai.
37° C
PUMP PRESSURE:
BOOM PRESSURE:
40
36
60
FLOW RATE CALIBRATED:
PSI
' PSI
GPM
OPERATIONAL DATA DURING FLIGHT
Above information same for Runs 1 - 6 .
DATE CALIBRATED;
1 July 1963
DATE TEST FLOWN.
LIQUID SPRAYED: 2 F.i?l 0*1. 1 Purple
TOTAL NOZZLES OPEN.
NOZZLE TYPE:
LIQUID TEMP:
2 July 1963
C'icck valves only
DURATION OF SPR/flf;
^0
TOTAJ. AMOUNT SPRAYED: . 40
Sec.
PUMP PRESSURE-
Gal.
60
37° C
16
BOOM PRESSURE:
FLOW RATE CALIBRATED:
OPERATIONAL PATA DURING FLIGHT
Above infoiintion sano fo- Runs 7 - 12.
PSI
14
PSI
80
GPM
�13
SJ :;:•:» JAN
FACTO1*:
r July 1J63
. ViMtT M).:
1
FAPurt:
J-'AM^r^ i.i:;;i:
C
?'Ari^."IA'u:
i-I.O., 1 KATE:
6t
STA.
n
77
77
77
7S
77
77
77
77
77
GPM
DROP *
2
1
6
5
C
7
3
4
10
9
K>:D --- 67.72-i-j . 142;<
SIZE
44 Ju*
43viO
4200
4100
2.2
Kro.-.iel<otc, white
SYSTEM:
'-' 1'ii'Jl Oil,
i. Fi.vpl-.'
• IBAL
STA.
DROP v'
76
1
bl/.K
4:;ou
3RL.O
3700
3600
3500
3400
(Spot D Ma::) ^
/j^:^.
75 '.-lall.'.-L)
- 314.7 Uirron;;
Max. Sph. Dia. = i)7.72+.').142i; (4'00) = 44C3 = 692.4 Microns
. 6.355
Kin. Sph. Dia. = 43 Microns
�14
MASb
i* ,>.•[•:;::•; I.M
2 r uc >i o i l . i F-orpir
l.'.l .
FLO".1 RAlt:
SVSI.-:M-
">. J u l y 1<X>3
FLIGiiT - '
1
SAhi'LS L I M B :
T;M;-: o.T K.-:LSASI-:;
DURAIIO*;
60
IIIDAL
Knots
AIRSPEED:
0437
12.5
G.P.A.
Sro'.ions 1 - 7 2 Blank
STATION'
55
ALTITUD:::
C
C-PM
100
AIRCRAFT CO'JRSK:
Foot
360
Degrees
Sec.
C-.P.A.
STATION
G.P.A.
73
74
75
76
77
78
79
80
81
82
83
Stations
3.0
l.S
0.6
0.4
1.0
1.4
1.3
1.1
0.4
0.4
0.0
84 - 100 Blank
Total 11.5
STATION
G.P.A.
�«y
;4:
tMnl». Sfi*j*£
. ttr. 01..
1.11 Dy*
*:• i jd»
Mn?**rt
Aluu.'r L'HIC**
i
t
i
.
:<YI r.-t
it Kaon
>*lO UrRrrri
i
i
t
wo
we
1X6
1100
WOO
IUO
17QO
IMC
�17
:-<A:J£ \-IHA:.* DIAMETER
:;AV: :
••.
2 July i:6'j
.7 #:
PAP^A:
2
C
:'. PLE LINE:
• '' I
- • iU \
coxvjui.-v: r^c-.'OR;
GTA.
30
30
28
29
28
30
31
25
25
2£
'.vorel-.oCe, wliite
flATrUA;,:
60
•» A T 7 •
CUt i i •
G1".-J
Dl'.CP -:
3
«
1
2
S\SV:»1:
SI^S
5-Ju
47->J
/'iiOJ*
',3 0 j
0
• • • ! . .•
VJ'.-;
3 J .0
3Ci.'':
37.0
!.'.Cr *
: ruc.1 O i l , 1 Purplo
'-JIDAL
SIZ3
' "*' J
5
&
1
9
lj
STA.
2.2
3P
1
100 (smallest)
i-^a = 67.72-. J . I ^ ' i (b^ot 1' Kax^ = 4400 -- :.H,.l Klcrons
•:.:-.
~"
6.355x2.1
Max. Sph. Die. =-- 6 7 . 7 2 - - J . l'-i2.;(5000) = 5J _^
6. A 3 .
Min. Sph. D i n . - o3 llicrons
777.6 Microns
�18
MASS DEPOSIT
MATERIAL: 2 Fuel Oil, 1 Purple
FLOW RAT.£:
DAT,1: :
SYSTEM:
FLIGHT :J:
2 July 1963
2
SAMPLE LIME :
TIKE OF R".:.3ASE:
DURATION:
60
55
ALTITUDE:
0439
Hours
11
STATION
STATION G.P. A.
oc.it ions 1
23 Clank
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
«1 .
Stations
Knots
HIDAL
AIRSPEED:
C
GFM
IOC
AIRCRAFT COURSE:
Kect
360
Degrees
Sec.
G.P.A.
0.0
1.1
1.0
0.6
0.6
0.9
1.0
1.1
0.6
1.0
0.6
0.8
0.7
0.4
0.2
0.1
0.1
0.1
STATION
42 - 100 Blank
Total
1U.O
G.P.A.
STATION
G.P.A.
�k
if
___.J...
"j
:•'. .-. 1 '. ':
;
^ .;'.•!..'• J
•ui«n«. I,r.r^i
' ".
. ...
l r » . w:
0.11 U««
«'"'•"•
Alr<p*M
A l r r i a l i Court*
TIB* 01 IrlcM*
I'xi r..-
:
•
ij in.,.
]»Q UVRI...
(MM Bovr*
vvk
IX
230
UL
BO
W
1100
UOO
IW
i«o
ITOI
noo
i«oo
lot
�21
MASS MEDIAN DIAME1ER
DATE:
2 July 1963
CONVERSION FACTOR:
3
FLIGHT #-.
SAMPLE LINE:
PAPER. Kromiikote, white
C
60
FLO'./ RATE:
STA.
75
79
79
78
79
78
78
78
78
78
MATERIAL: 2 Fuel Oil, 1 Purple
GPM
DROP #
4
3
2
1
5
6
7
8
10
9
SYSTEM:
SIZE
3700
3200*
3100
3000
2900
2800
2700
2600
2500
2400
STA.
- DROP *
78
1A
HMD = 67 72-fO .1420 (Spot D Max) = 3200
Max, Sph
Mm.
2 .. 2
HI DAL
SIZE
ICO (smallest)
= 237.3 Microns
Dia. = 67.72-f-O 1420(3700) = 3700 = 593.0 Micror.s
6.430
Sph, Dia. - 63 Microns
�22
MASS DEPOSIT
1-Y,T'CIiTA'.:
FLOU RATE :
: Fuel Oil. 1 Purple
-AT'
2 July 1963
SYSTEM:
FMC'.iT : =
3
6J
AIRSPEED:
oAMl'L3 LIKE:
TIME OF RELEASE:
DUIl/'-'ION':
11 IDA L
ALTITUDE:
0459
7.5
JTATION G.P.A.
STATION
Stations 1 - 7 3 Blank
Hours
CTM
AIRCRAFT COURSE:
75
1)3
Knot «;
Foo*
36 J _ ??croc5
Sec.
G.P.A.
STATION
74
G.P.A.
STATION'
1.4
0.9
75
0.6
76
0.4
77
0.4
78
79
0.5
0.7
8J
81
0.5
82
0.7
0.1
S3
Stations 84 - 100 Blank
Total
6.2
G.P.A.
�T
-if
HO-
2oc
to
;s
inc
«x
ut
me
iiao
na
1200
m
1400
ISM
IMO
inc
�25
MASS MEDIAN DIAMETER
? July 1963
DATi:
COWERS ION FACTOR:
/
FLIGHT #:
PAPER:
SAIL":.*: LIN ~.
C
FLOW KATE:
60
STA
29
24
29
29
29
29
29
29
29
29
2.2
Kromckote, white
MATERIAL: 2 Fuel Oil. 1 Purple
GPM
DROP #
1
4
2
3
5
6
7
8
9
10
SIZE
3AOC*
3300
3100
3000
2900
2800
2700
2600
2500
2400
SYSTEM:
STA.
26
MM = 67. 72 :-3. 1420 (Spot D Max) = 3430
DROP #
1A
HIDAL
SIZE
100 (smallest)
= 250.2 Microns
M.-ix. Sph. IHa. = 67.721-0.1423(3400) = 3400
6.430 = 550.4 Microns
M i n . jiph. IHa. = 63 Microns
�26
MAbS DEPOSIT
XAT.'IKIAL:
2 Fuel Oil. 1 Purple
FLOW RATS:
2 July 1963
DAYf- :
SYSTEM:
6.)
HIliAL
Fl I GUY •» :
4
AIRSPEED:
75
SAMPLii LINE:
C
ALTITUDE:
1C")
0500
TIME OF RELEASE:
7
DURATION:
STATION
Hours
G.P.A.
Stations 1 - 2 3 Blank
,;i->[
AIRCRAFT COURSE:
Knots
360
Feat
B'^rcos
Sec.
STATION
24
25
26
27
28
29
30
31
32
33
Stations
G.P.A.
STATION G.P.A.
0.9
0.9
0.0
0.0
0.0
0.3
0.5
0.4
0.4
0.4
34 - 100 Blank
Total
3."
STATION
G.P.A.
�. . . f ^
KT
| On •.!» I B^ ft.* I •«, « . j
.
-.' ." i :•• - J "
-•'-... L- •: •/
I July IMJ
'J. .1 >r>
', ,- r.f
,
Al'KMlt Conn*
TIM of li I.M*
JOO
100
SK
600
7X
«X
WC
100C
1109
IX
i«e
IM
iuo
;TOC
MIUr||r»ti
'lili luur*
iuo
..
�29
MASS MEDIAN
!.-»•:..:
CONVERSION FACTOR:
2 July 1063
:--LL;::T*:
5 •
PAPSR:
C
MATERIAL:
GPM
60
.-..0,; i<ATE:
STA.
DROP #
79
78
80
78
78
78
79
78
8C
80
5
1
6
2
4
3
8
7
10
9
SIZE
4800
4300*
4200
4100
4000
3900
3700
3600
3500
3400
Kronekotc, white
HIDAL
STA.
DROP 4
78
1A
SIZE
100(amallesr.)
308.2 Microns
Hex. S;;h. Via. - 67 .72+0 . 1420 (4C30) = 4800 =«
6.430
Kin. Sph. Dia. = 63 Microns
2 Fual Oil, 1 Purple
SYSTEM:
j.
MND - 67.72+; 1420(spot D Max)= 4300 =
2.2
74D.2 Microns
�30
MASS DEPOSIT
•,i.T'..v]AL:
2 Fuel Oil, 1 Purple
•:'.T.i:
2 July 1963
1: LIGHT >::
'•MIFU: LINK i
SYSTEM:
AIRSPEED:
5
C
ALTITUDE:
3513
TIMS Or' RELEASE:.
DURATION:
FLO'.J RATE:
09
STATION
.•TATIOK G.P.A.
it ions 1 - 7 3 Blank
Hours
AIRCRAFT COURSE:
fcO
GPM
HIOAl
5}
Knots
75
Feet
36J
Ujgrflcs
Sec.
STATION'
l>t
7^
76
77
78
79
80
01
32
.T>
G.P.A.
84
li.P.A.
2.7
1.7
0.9
.,.6
'."' . >'
!. !
l.c
o . ;•;
1.1
0.6
;;.:>
85
0.-.
36
r-. r,
Station:; 6 7 - 1 .
Total
12.0
�i;< t -*<_
._ -" - ,
«ll
I »r •*•
•»*•.*
'
M * j
.
' ""
IUc>rl«l Cprqwd
:
d. 60 CM
7 'Ml Oil. 1 f»r»l*
G.llDy.
A l i c r « f i CAUI-M
:
*0 D*BIM*
IIK
ing
I
ion
r,
n
N
is
nag
�33
MASS MEDIAN DIAMSTKR
DAT.C:
CO;;IFUISIOX FACTOR:
: July 1-J63
FLIGHT --?:
6
C
SAMPLE LINE :
FLOW KATE:
PAPER:
MATERIAL: 2 Fuel Oil, 1 Purple
60
STA.
24
29
29
27
2-3
29
29
29
24
29
GPM
DROP #
1
6
3
7
2
SIZE
5000
4100*
4000
3900
3800
3700
3600
3500
3400
3333
SYSTEM:
STA.
DROP *
34
1
MID = 67. 72 H). 1420 (spot D Max) = 4100
=
Max.
Krosi?kotc, white
5
4
8
9
10
HIDAL
SIZE
IGO(araallest)
295.3 Microns
:5ph. Dia. = 67.72-1-0.1420(5000) = 5000 = 777.6 Microns
6.430
Mia. Sph. Dia. - 63 Microns
�34
MASS PEl'OSIT
; Y/:"I\'.: " :-u-i on, I purple
FLO'/.' RATE:
.. . .:
SYSTEM:
2 July 1383
: •.!.,:.•< •:
SAMI'I... LINE:
6
DIJi'ATI 0"*J j
ALTITUDE:
0520
A1KCRAFT COURSE:
Hours
08
'JIAi'lGK C.F.A-.
STATION
.jt.itions 1 - 2 3 ulank
24
25
26
27
28
29
30
31
32
33
34
35
36
37
Stations
G?M
HIDA1.
AIRSPEED:
C
V !•• OP PLEASE:
!;:
6')
55
Knots
75
Feet
360
Degrees
Ssc.
STATIC:;
G.P.A.
1.4
1.5
0.7
0.8
1.0
1.0
0.9
3.9
0.7
:.
)4
0.4
0.5
0.2
0.3
3C - l.n> HlanU
Total
lii.7
G.P.A.
STATION I;.P.A.
�34
MASS DFJ-OSIT
I vm\:,: " L-uol nil, l Purple
FLOW RATE:
2 July U63
...,.:
SYSTEM:
6
n.Ti,: '. ' -:
s/j-iri.r. !,i:;&:
ALTITUU£;
DlV.ATT<v::
0520 Hours
08
GPM
HIDA1.
AIRSPEED;
C
•ni>: or KELEASE :
6'!
55
Knots
75
AIKGRAFT COURSE:
Feet
360
Degrees
Sec.
/•
STATiGK
G.P.A.
STATION
.: Cations 1 - 2 3 3 lank
24
25
26
27
28
29
30
31
32
33
34
35
36
37
G.P.A.
1.4
1.5
0.7
0.8
1.0
1.0
0.9
0.9
0.7
0.4
0.4
0.5
0.2
0.3
STATION' G.P.A.
-
Stations 3C - l.)0 Blank
Total
10.7
&1ATION
G.P.A.
�e,,,
I
I !•
1
WC
u
»
K
too
IMC
-* < i » i—> - I »
HOD
IX
im
mo
ino
IKC
TOM
�37
MASS MEDIAN
DAT;::
- July
CO'..'Y£K.S 1Q£ F ACTOR:
1963
2.2
FLIG.iT i>:
7
PAPES:
SAVPLE LINE:
C
KATERlAL: "• Fuel Oil, 1 Purr IT
e:
tU)1..1 HATi:
STA.
77
77
77
77
77
77
75
77
77
11
Gi'H
DROP ')'
1
i
2
5
3
4
6
3
3
7
KroiM'Koto, whita
.\STaM:
SIZE
5100*
50C-3
49- •
4800
4700
4600
4500
4400
4300
4100
olA.
83
DROP •(
1
MIJAL.
SIZE
13v~(cir..illest)
IT!i! •= 67 . 72-h'i . l'4r:;)(;
:-pot D M.-.X) - 51--'
=- 35J.J r-icrons
Con . t-.etcr = :'..?
6. 155::-':. P-
::.-::. :s.,;i. u ia.
* 6V .7::: ..R-.J(Sl-o) - 5_L'.'l - "'--" ."icroi::.
K i n . iiph. r;i<->. -= 6'j Microns
�38
MASS i)hPOSIf
MATERIAL:
2 Fuel Oil a 1 Purple
DATE
t'LOiv RAl.-I:
2 J _ L y 1963
SYSTEM:
8-;
GPM
HIDAL
FLIGHT -»:
7
AIRSPEED:
75
Kr.o: s
SAMPLE LINE:
C
ALTITUDE:
75
Foe t
riMii OF RELEASE.
DURATION-
0539
08
•STATION' G . P . A .
STATION
S t a t i o n s 1 - 7 1 Bla.ik
Hour
AIRCRAFT COURSE-
360
Drurc.'T,
STATION
72
71
77rj
76
77
G.F..\.
0.3
.J.5
l.v
(-,.••)
Sec.
G.P.A.
STA.'ICN
G.P.A.
v'.^
1
•'
7-)
:'.:
3'.)
1.1
?l
J.S
82
.).<>
Ci
0.5
^ /
Si
lit -jt ;cn : 8-, - 100
Blank
•. .5
�.*•«
ft'
e i
— 0-
no'
:
Hirer* It Cnur*«
7lM 01 !•>•«••
.1-
Wf, 0«|if»*
01 M HOMF*
;t
V1
100
toe
low
noo
im
iioo
IHO
I6«
1700
2 July 1*6 1
nao
�41
MASS MEDIAN DIAMETER
DATS:
2 July 1963
CONVERSION FACTOR:
8
FLIGHT *:
PAPER:
C
SAMPLE LINE:
STA.
28
28
24
27
27
24
25
25
25
27
24
24
27'
K.romekote, white
MATERIAL: ?. Fuel Oil. 1 Purplo
80
FLOW RATE:
2.2
GPM
DROP •t
2
3
1
6
4
11
8
7
10
5
12
9
13
SIZE
5000
490C
4800
460C
4230*
AIO'J
4000
3900
3800
37UO
3600
3500
3400
SYSTtM:
STA.
28
HMD = 67. 72+0. 1420 (Spot D Max ) = 4200
DROP #
1
UIDAL
SIZE
100 (smallest)
= 301.8 Microns
Max. Sph. Dia. = 67.72-i-0.1420(5000) = 5000 = 777.6 Microns
6.430
Min. Sph. Dia. = 63 Microns
�42
MASS DEPOSIT
IV.TSRfAL:
2 Fuel Oil, 1 Purple
HAT.-:-
2
'.•TIGHT -?:
SAMPLE LI::E:
TIM.i OF PLEASE:
ai'UATICX:
FLOW RATfi:
SYSTEM:
July 1963
f
8J
OI'M
HIDAL
AIRSPE3D:
0540
Hours
07
STATION
iviAT10N G.P.A.
Jtatians 1 - 2 1 Blank
22
23
24
25
26
27
23
29
30
31
32
33
Stations
"nots
ALTITUDE:
C
75
75
Frrr
AIRCRAFT COURSE:
360
Degn..--j
Sec.
G.P.A.
STATION
J.I
3.1
1.6
0.8
0.5
1.4
1.1
0.5
0.8
0.7
0.3
0.3
34 - 100 Blank
Total
K-.2
G.P.A.
STATION
G.?.A.
�two
.X
2*
ino
IBM
i9cc
�45
MASS KEDIAN DIAMETER
DATS:
CONVERSION1 FACTOR:
2 July 1063
FLIGHT '?:
PAPER:
3
1)
SAMPLE LINE:
FLOW RAT2:
24
24
24
24
24
24
24
24
24
24
24
Kromekote, white
MATERIAL: 2 Fuel Oil, 1 Purple
SO
STA.
2.2
GPM
DROP #
1
2
4
5
3
6
8
7
10
11
9
SYSTEM:
SIZE
5900
5500*
5300
5200
5000
4900
4800
4700
4600
4500
4400
STA.
DROP *
4
1
MMD = 67.72+0. 1420 (Spot D Max) = 5500
SIZE
100 (smallest)
= 383.3 Microns
Max. Sph. Dia. = 67.72+-.1420(5300) = 5300
6.558
Min. Sph. Dia. = 63 Microns
HIDAL
= 893.7 Microns
�MASS DEPOS IT
\ATiiR JAL:
2 i'uol Oil. 1 Purple
LATE:
2 July 1963
."LIGHT ?:
TIME OF RELEASE:
DURATION:
AIRSPEED:
D
0553
OS
0.3
0.3
0.5
0.5
0.3
0.6
SJ
lilDAL
75
ALTlTTDii:
STATION G.P.A.
STATION
Stations 1 - 7 Blank
23
24
25
SYSTEM:
0
SAMF'j: LINE:
8
9
1.)
11
12
13
14
15
16
17
10
19
FLOW RATE:
Hours
AIRCRAFT COURSE-.
Knots
Uil
CAS
Feet
Dcgrc-c-a
Sees.
G.P.A.
STATION
Stations 26 - ICC Blank
l.v)
0.7
1.3
1.5
1.5
1.1
1.1
1.2
1.5
•£. 2
1..:
Total
17.0
G.P.A.
STATION
C.P.A.
�;so
IS
ix
X
1700
»
10
1100
I90C
O»
�49
MASS MEDIAN DIAMETER
DAT,::
CONVERSION FACTOR:
2 July 1963
FLia:;r #:
10
SAMPLE LINE:
PAPER: Kromakote, white
D
MATERIAL: 2 Fuel Oil. 1 Purple
80
"LCi,; RATS:
STA.
75
75
75
75
75
75
75
75
75
75
75
I>;KD= 67.72+
2.2
DROP *
1
2
3
4
5
6
7
10
9
8
11
GPM
SIZE
5200
4600
4200*
4100
4000
3900
3800
3700
3600
3500
3400
SYSTEM:
HIDAL
STA.
DROP *
51
1
0.1420 (Spot D Max) = 4200
SIZE
100 (smallest)
= 301.8 Microns
Max. Sph. Dla. = 67.72+3.1420(5200) = 5200 = 800.9 Microns
6.493
Mill. Sph. Dia. = 63 Microns
.
�50
MASS DEPOSIT
:*.\T;:;;,.L-.__.: i-'uai oil. 1 Purple
FLO'.-; KAT.i:_
JJAI.I:
SYSTEM:
-"* July 1363
V.TIIIT -••':
10
3.'
il IOAL
AIRSPEED:_
03
STATION
G.I 1 .A.
•lat-io'KS 1 - 54 Blank
Hours
Knots
AT.TITUDE:
C600
75
1. ,
Foot
AIRCRAFT COU.ISE:
Sac.
G.P.A.
STATION
55
56
57
53
50
60
61
62
63
64
65
66
67
60
69
7.')
71
72
73
74
75
76
Stnt iors
Total
15.J
G.F.A.
a. 3
STATION
0.1
0.3
0.3
0.3
0.3
0.4
0.5
0.5
r.5
0.7
1.1
1.3
l.;j
1.5
l.l
1..T
0.7
1.3
'..7
1.0
.,.1
11 - 1.,. .; l.".;;
G.r.A.
�.i.l _H •(_.. ; . ! . • _ •
.««.-.«,::.'
..-_,.
•.vi..- • • « . - • • ; • ' ..
• .
;
\ '.'
fJl(hl f
f«Vl* Hi*
.ivinil, 1(1 «W
Pl.l.rnl i,T.rM
r»«i on. :
.11 [*.
00 rr.t
: Couri*
j^l Ii«(f*«i
v\
1 J
(c;
>x
I3C
100
I'/OK
MM
IM>
I IN
MOO
IMC
IUO
1710
IMC
�53
MASS MEDIAN DIAMETER
DATE:
CONVERSION FACTOR:
2 July 1963
11
FLIGHT NO:
PAPER:
C
SAMPLE LIN3:
STA.
72
74
73
74
72
73
72
73
71
73
DROP #
3
1
7
2
5
6
4
8
10
9
Kroroekote, white
MATERIAL: 2 Fuel Oil, 1 Purple
GPM
80
FLOW SATE:
2.2
SIZE
5400
4300*
4200
4100
4000
3900
3800
3700
3600
3500
SYSTEM:
STA.
DROP •/
73
1
HIDAL
SIZE
lOO(cmallest)
= 308.2 Microns
MMD = 67. 72+0. 1420 (Spot D Max) = 4300
Con. Factor = 2.2
6.355x2.2
Max. Sph. Dia. = 67.72+0.1420(5400) = 5400 = 829.1 Microns
6.430
Min. Sph. Dia. a 63 Microns
�54
::.Vr:"IAL:
DAY .:
FLO:; RATE:
I: Fuul Oil. 1 Purple
SYSTEM:
2 July U63
V'.KIIIT ?:
8:)
!11DAL
. AIRSPEED:_
11
Knot:
75
ALTITUDE:
III:; 01? RELEASE:
DURATION:
'-618
OS
STATION
:.TATION (J.P.A.
.*>t aliens 1 - 6 6 Dlank
Hours
AIRCRAFT UHJRSE:
360
Sec.
G.P.A.
Total
STATION
67
68
69
70
71
72
73
74
75
76
77
78
79
Stations
1/-.1
C.P.A.
STATION
U.4
1.3
0.4
1.6
1.4
1.5
0.7
0.3
0.7
2.8
1.8
3.5
.1.2
C.- - l< 0 blank
G.P.A.
�r
«*
| If
r r r.-
InwIaJ, Su CPW
; fuel 01 i , i Pi
I
i
<>. II 0y*
*r
TIM ot ••!•••«
.
J6J8 Ibwr^
- '\
C J
BOO
•
900
IMG
1100
IMO
i*»
1700
IBOD
!90T
?50C
�57
MASS MEDIAN DIAMETER
DATE:
2 July 1963
CONVERSION FACTOR:
12
FLIGHT */:
PAPER: Kronokoto, white
C
SAMPLE LINE:
MATERIALS Fu^l Oil, 1 Purple
GPM
80
FLOW RATE:
2.2
STA.
DROP »
21
25
23
20
24
22
23
20
20
24
24
1
4
2
6
3
5
3
8
7
11
10
SIZE
4400
3700*
3600
3500
3400
3300
3200
3100
3000
2900
2800
SYSTEM:
STA.
DROP i?
24
1
HMD = 67. 72+0. 142') (Spot D Max) =3700
=
HIDAL
SI2U
IJO(smallest)
269.5 Microns
Max. Sph. Dia. 67.72+0.1420(4400) = 4400 = 692.4 Microns
6.430
Min. Sph. 2ia. = 63 Microns
�58
i • ii.. K.-1,:
..1 :
..'
I .ii.ly i jo't
.. .I!'.:
i i . ' . ; »;! .li'U.'.AJii:
:>\:>i->i:
£
j j . i ' l l'U>'
JS1J
.-lours
"7
Sec.
l i l ' I i A i i "•!.':
yiVU_,<; . .'^.-..A_.
J t a t i o i i " I -"i6 jL.ink
J TAT I ON
Ali\«J:<Ai-
P.P. A .
17
IS
10
2;)
21
12
V.3
'..'I
1..;
1.4
1.0
.j./ r
24
25
-6
...';
'.7
:.5
.:?
23
i.;i.-:.
Recovery - A2.7
��61
H-34/HIDAL GROUND FLOW g. FLIGHT DATA
DATE CALIBRATED:
1 July 1963
DATE TEST FLOWN;
LIQUID SPRAYED: 2 Fuel Oil. 1 Purple
TOTAL NOZZLES OPEN;
NOZZLE TYPE:
LIQUID TEMP:
DURATION OF SPRAY:
8015
30
5 July 1963
60
——
PUMP PRESSURE;
32
PSI
Gal.
BOOM PRESSURE:
30
PSI
FLOW RATE CALIBRATED:
TOTAL AMOUNT SPRAYED; 38.5
Sec.
77.0
GPM
OPERATIONAL DATA DURING FLIGHT
Above information same for Runs 1 - 8 .
�62
.
MASS DEPOSIT
,:
.:
SYSTEM:
5 July 1963
•;I;T ; r
08
55
Knot-.
ALTITUDE:
:iours
HO
Feet
AIRCRAFT COURSE:
360
Degrees
S>;c.
STATION' G.P.A.
:"TA710:: fl.P.A.
i tot ions 1 - 9 Blank
STATION
.1.3
:. i
HIDAL
AIRSPEED:
T.: LliJIl:
11
12
13
14
15
16
17
18
13
77.>")
FLOW RATS:
:\T r.i.-.L: 2 Fuel OU. I Purple
:>.2
0.2
0.5
•;..J •
1.6
2.3
2.7
2.6
1.3
i. i
?2
1.7
21
2.3
24
1.3
:t.-.tion£ 25 - 1. 0
Total
21.5
G.P.A.
STATION C.I'. A.
�"T
!
j
i
i A
!
i
-I.
I
A':lluJr
Alri|i**il
Alrcr.ft
T;M »f ••
I
•\!\r
•jr v
UK
inc
i»o
uoo
IMC
1730
�65
MASS MEDIA:: LIAJ^TZK
DATE:
5 July 1963
FLIGHT #:
2
SAMPLE LINE:
FLOW RATE:
CONVERSION FACTOR:
PAPER:
Krorickote, whito
MATERIAL: 2 Fuol 0*1, 1 Pwrplo
C
77 .0
STA.
75
75
75
75
75
75
75
75
75
75
2.2
DROP #
1
3
2
6
5
4
7
8
9
10
GPM
SYSTEM:
SIZE
5200*
5100
5000
4800
4700
4600
4400
4300
4200
4100
1ITDAL
STA.
DROP #
SIZE
62
1A
100
HMD --- 67 . 2 . . . 1420 (Spot D Max) = 5200
7'''
= 36/..D Microns
Ma\. Sph. Dia. - 67.72-H).U£0(523J) = 5.200 = 800.9 Microns
6.430
M i n . Sph. D i d . = 63 Microns
�66
MASS DEPOSIT
.".\i""IAL:
2 Fu^l Oil, 1 Purpl-2
7 •;-.:
Fi.TGIIT *:
FLOW SATE:
SYSTEM:
5 July 1963
T3M!C OF UiiLEASE:
C441
10
STATION G.P.A.
STATION
Scations 1 - 5 8 Blank
Hours
55
ALTITUDE:
C
0PM
UIDAL
AIKSPEED:
2
3AMPLK LINli:
PUPATION:
77.0
100
AIRCRAFT COURSE:
360
Knots
Foot
Degree;
Sec.
G.P.A.
Total
STATION
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
Stations
21.7
G.P.A.
STATION
0.3
0.5
0.6
04
.
0.9
0.7
0.8
1.3
2.0
2.5
1.5
1.8
1.2
1.6
1.0
4.3
0.6
0.2
77 - 10J Blank
G.P.A.
�I
f
' 0., A. .
r • \ At'
I
.
,
.
:1 ••
•
p. • .
,V -j..
V
-V-t» A-X
^y•'-•'•
.-:>-T-T-^-^ '
— • i-
:
I
V"
t->
-"..I-.
•i \ \v
'*• v
i
\
J . _ ..
A.-I-.1.T
••'
f,'-tyrfAd
*"•
'.'• KIHI. .
—-.1—- ^L
Uig-ir
X- i
r«n
Tl-w . ' l< !••!<•
I
r«f
•"-
"i".i
I
_J
i
J
�PL:-* RAVI
"...
* .-li 1363
SYSTEK-
:-.::: > .
\ __.
77.0
AIRSPEED
LA::?:;: L:W ; -
?
;:M-: OF REIEASE.
C-JRAiIOS:
^^^^^_.
o'oo
"lT~ilaprc
HTDAl
ALTITL'Di."
Hr^r
A l B W A F I COVSSS
Se -. .
•:*
sm I_JN _j_: ..^..Ai
S*~2-i~£s 1
_..._
11 ill Li .
18
" ;9
: .r.A.
'CTo
O.i
O.i
v~-.5
1.9
3.1
1.5
3.0
2.6
1.4
2.9
:o
21
>2
23
24
?s
26
27
28
29
30
:1
32
%«
', i.
; -
;*6
if.
?.7
3.1
3. V
0.7
C.3
0 .3
0.1
c.c
- 100 s::-.
% Recovery - 89.8
T;-,i
GFM
?5
""•
Kr.Dt s
Fort
MS
Decree 5
�.T-
"1 ...
\
.\
wind, t, 'j c •*
Piwl O i l , 1 p.. i
II Dre
1 b.n •
I
IX
ICC
J.v
KL
I
6JC
!X
00 Num.
fX
i . i--.-;
IX
>XK
HOC
1200
1100
1400
ISOO
1UO
17*
IUC
IWC
?UO
�71
MASS MEDIAN DIAMETER
DAT-i :
5 July 1963
FLIGHT J:
SAMPLE LINE:
CONVERSION FACTOR:
4
PAPER:
B
FLOW KATE:
KromeKote, white
MATERIAL 2 Fuel Oil, 1 Purple
77.0
STA
78
79
78
79
79
78
75
73
79
78
2.2
DROP #
5
2
4
3
1
6
7
9
10
8
GPM
SIZE
4300*
4100
4000
3900
3800
3700
3500
340G
3300
3200
SYSTEM:
STA.
82
MMD = 67 .72-i-O .1420 (Spot D Max) = 4300
DROP #
1A
HIDAL
SIZE
100
= 308.2 Microns
Max. Sph. Dia. = 67.72+0.1420(4300) = 4300 = 678.? Microns
6.430
Min. Sph. Dia. = 63 Microns
�72
MASS DEPOSIT
lY.TSRTAL:
2 Fuel Oil, 1 Purple
OAfil:
SYSTEM:
5 July 1963
TLIGiir^:
4
SAMPLE Lit-:::
B
DURATION:
11
STATION
Hours
GPI
HIDAL
ALTITUDE:
v,502
.'...-.A.
77.0
AIRSPEED:
TIMK Or liL'.ASS:
tiTATIO::
FLOW RATE:
AIRCRAFT COURSE :
55
Knot.'
75
315
Feet
Degrees
Sec.
G.P.A.
STATION
G.P.A.
STATION
72
0.1
3.6
73
74
2.2
1.7
75
C.9
76
0.9
77
78
1.5
79
.1.5
80
1.3
2.4
81
0.2
82
0.0
83
Stations 84 - IOC Blank
7. Recovery - 5 .
21
Total
16.3
G.P.A.
��74
MASS DEPOSIT
MATtRIAL-
2 Fuel Oil, 1
DATE.
FLIGHT #:
SAMPLE LINE:
FLOW RATE:
5 July 1963
SYSTEM:
5
AIRSPEED:
B
TIME OF RELEASE :
DURATION:
Purple
77.<J
HIDAJ,
75
ALTITUDE:
0520
Hours
GPM
AIRCRAFT COURSE:
Knots
100
315
Feet
Degrees
Sec.
08
STATION G.P.A.
STATION
21
Stations 1 - 2 0 Blank
22
23
24
25
26
27
28
29
30
31
32
33
G.P.A.
STATION
G.P.A.
0.3
0.8
2.9
1.4
0.9
0.6
0.3
0.6
1.6
1.3
1.6
06
.
0.5
Stations 34 - 100 Blank
7. Recovery - 58.3
Total
13.4
STATION
G.P.A.
�•T
. (h,',. *
« * ,*
• r~ i T
f
~r
; i\
V
i
-i
,:
:
M
i
Jtoi.ii • •.. •
'..'.•
"i
i
J
1
i
^oo
noc
inc
IMC
uoo
isoc
.L.
IMC
mo
noc
�77
MASS MEDIAN DIAMETER
DATE:
5 July 1963
FLIGHT #:
CONVERSION FACTOR:
6
SAMPLE LINE .
PAPER:
B
Kromekote, white
MATERIAL: 2 Fuel Oil, 1 Purple
77.0
FLOW RATE:
2.2
STA.
DROP #
78
78
77
78
78
77
78
78
78
78
1
2
3
5
7
4
6
8
9
10
GPM
SIZE
3700
3200*
3100
3000
2900
2800
2700
2600
2500
2400
SYSTEM:
IIIDAL
STA.
DROP #
SIZE
77
1A
100
MMD = 67.72H).1420(Spot D Max) =3200
=237.3 Microns
Max. Sph. Dia. = 67.72+0.1420(3700) = 3700 = 593.0 Microns
6.430
Min. Sph. Dia. = 63 Microns
�78
MASS DHPOSI1
;:/.T• KJAL:
2 Fuel Oil. 1 Purple
:-AX:; :
FLO'.J RAT£:
5 July 1963
KLJO.IT ?>:
SYSTEM:
H1DAL
AIRSPEED-.^
6
SAMPLE LINE:
0521
10
STATION 3. P. A.
STATION
Stations 1 - 7 2 Blank
Hours
Knot r-
75
ALTITUDE:
TIMii OF RELEASE:
DURATION:
77..T
AIRCRAFT COURSE:
l.i.'
Fool
315
Sec.
G.P.A.
STAT ION
73
74
75
76
77
7R
7-i
80
81
82
83
84
85
G.P.A.
STATION
•J.8
2.2
1.5
0.8
1.0
1.0
1.1
1.2
' 1.2
J;.6
J.5
>.3
:..5
Stations Go - 10u illa.ik
Total
12.7
G.P.A.
�i
i
S^l* LineTypr Al'npltMl
•Ur.fl*: S|>r«]red
I
:
la.lnd, 7 7 . , <
I Furl 01., 1
fi.it DJ«
A.Slta.,1-
2JC
!X
40C
S«
1200
1100
iOO Ft*!
AIr«M«(!
7* I»r.
�81
MASS ' 'JDIAN DIAMETER
DATE:
5 July 1963
CONVERSION FACTOR:
7
FLIGHT i«:
PAPER;
C
SAMPLE LINE:
FLOW RATS:
Kromekote, white
MATERIAL: 2 Fuel Oil, 1 Purple
77.0
SYSTEM:
GPM
STA.
DROP *
25
1
2
3
4
25
17
18
25
18
25
18
15
15
2.2
6
5
8
7
9
10
SIZE
3000*
2900
2800
2700
2600
SiTA.
DROP #
18
1A
HIDAL
SIZE
100 (smallest)
2500
2400
2300
2200
2100
MMD = 6;.7 2+0. 1420 (Spot I) Max) =" 30i".0
- 224.4 Microns
Max.
iph. D i a . = 67.72-H).1420('."100) = 3000 = 493,7 Microns
6.430
Kin.
Sph. Dia. = 63 Microns
�82
: i »•.
S\:
A- i III:::-.:
:J.ours
0-3
. iA ._; ( ) ._ : ..[- .A. _____ s
.- L." ;.::i2 1 - 10 .'! ink
7>
A C - C i t A t i COURbt:
SPC.
1
;,
O.P.A.
.'.f.A.
11
r?
13
i«,
15
16
I/
IS
i;
__
.../
Recovery - 27.8
SU.
..,..-..
�I
I
I
i
i
!
}
_L .
110C
1400
�84
MASS DEPOSIT
MAIER IAL
2 FJ< 1 Oil __1 ._Py_.'j.U
F^OW RATE'
DA IE
IJL'iil^iil3_
SYSTEM
"LIGHT # • _
SAMPLE LINE1;
TIME CF RELEASE.DUXAII:*
'~.0
HIDAL
AIRSPEED:
C
0632
Hours
12
7
ALTITUDE:
8_
75
Fee--
Sec.
STATION
STATION C-.P.A.
Star ions 1 - 65 Blank
AIRCRAFT COURSE;
C-.P.A.
STATION
C.P.A.
66
t?
68
£"»
70
0 3
'2
:
0.2
0.2
v.
76
••?
75
STAIICN
0.1
0.4
0.7
0.8
0.4
7'.
3*0
0.3
0.3
0.1
0.0
7
5-5:1.::r.s 79 - 100 S l a - k
% Recovery - 18.3
',.2
DC-*-
G P.
�H 'L/^.'
nr-~,-.l-<Ti. .-1. .
D4IC
Plllhi I
POIM. il n >.m
} rn«l 01:, i m > »
I'. It Dy*
•
Alrcr^it fon
Tl» of I.I,
IjC
«K
Sfc.
•*
'X
BC
WC
IMC
eld ('•«*)
'»
«
ngg
I no
im
MOO
iuo
.
1«< M||i...
JftU Nuwrt
�86
H-34/HIDAL GROUND FL9W & FLIGHT DATA
DATE CALIBRATED:
6 July 1963
DATE TEST FLOWN.
LIQUID SPRAYED: 2 Fui-i Oil. 1 Purple
TOTAL NOZZLES OPEN:
NOZZLE TYPEr
8C10
LIQUID TEMP:
DURATION OF SPRAY;
30
7 July 1963
TOTAL AMOUNT SPRAYED:
60
39 C
Sjic.
Gal.
35.5
BOOM PRESSURE-
54-55
FLOW RATE CALIBRATED;
PS I
71
GPM
OPERATIONAL DATA DURING FLIGHT
Above infomntlor. same for Runs 1 - 6 .
DATE CALIBRATED:
6 July 1963
DATE TEST FLOWN
LIQUID SPRAYED. 2 Fuel O i l , 1 Pu rp 1 e
TOIAL NOZZLES OPEN
NOZZLE TYPL:
8015
LIQUID TFMP:
DURATION OF SPRAY:
30
7 J u l y 1963
TOTAL AMOUNT SPRAYED
60
33.5° C
Sec.
39. 5
PUMP PRESSURE..
Gal.
FLOW RATE CALIBRATED
38-28
30
PS!
GPM
OPERATIONAL DATA Dl'RINC FLIGHT
Above ii;form;it ion saire lor Runs 7 - It).
REMARKS. Pump cr.vHal ing after 20 soconds duo to iow lovol «l l i q u i d in tanks
on run #16.
�87
MASS MEDIAN t
coi;v2Rsiot: FACTOU:
7 ,
I\j\v 1-J63
DAT.-::
FLIGHT KO.:
SAMPLE LINE;
1
PAPER:
A
STA
72
70
72
72
72
70
70
72
70
70
KroneUoto, white
MATERIAL: 2 fuel Oil, I P«Vplo
71.0
FLOW KATc:
2.2
GPM
DROP #
1
2
6
5
3
3
4
7
lu
9
siza
3900
3 ICO*
3003
2900
2800
2700
2600
2500
2400
2300
SYSTEM:
STA.
DROP #
70
1A
U = 67. 72+6.1420 (Spot D Max) = 310o
Nrt,
iilDAL
SIZE
I. (tallest)
= 23u.S Microns
M.IX. Sph. Dia. = 87.72+0.1420(3900) = 3930 = 621.4 Microns
6.430
Min. Sph. Dia. = 63 Microns
�88
MASS
cti i
MATERIAL
ri:-W RATE'
i 9* 3
^l.
SYSTEM
-::n.
FLIGHT rf
A3SPEED
SAMFL? L:..--
«L T::VD:
T:ME or us
0413
?__
;oo
AIRCKAF: COURSE
Hours
C-FM
Tt f
DC «"
DURATION
SIAT1CN
C .F.A.
1
63Blank
STATION
G.P..A,
SIA^^ON G.,?^.,
o.?
0.2
0.'
G.?
0.=)
0.
I..
103
7. Recovery -
52.0
l:.-ilI^__-_j.f-ji-_
�/ - J-.L 1 1. j r
,
.
NT
, Q.. B.I.
(.
tftmltt
••• rt*. i
••. r ,
.
In*
1
.... 4 . ; , „«•,
—
•..•.»
: J»ir "»i
: I
: A
.
1 ri*l « l l , I '-".'.
... it ;v.
Alrcr«(
Tin af
•x
:»
i-jo
V
ix
Sti
>x
.<x
KC
TO
1000
Sxrii "»i|
»
K
1100
1200
I HO
1400
IUO
IUO
1730
IUC
>HC
7090
�90
» ESPIED:
3- •-*
,: ;\
.F .
1'
-"
•o
20
C.. 0.
o •
!^ •
Rocovorv -
23.0
�T"
"T
1 - 8. t
•- t. »
wr
._!
L--L
i
_p._
0 . ! X Dyr
!i)0 r». i
.'% bio*>
:
•f-
i\ /«-..
I"
I>C
MX
inc
IMO
i;ac
1
1—
•.- *—
�93
MASS MEDIAN DIAMETER
DATE:
7 July 1963
,-IGHT •
;
CONVERSION FACTOR:
3
PAPER:
SAMPLE LINE:
A
FLOW RATE:
71.0
STA.
70
72
72
69
74
71
70
74
72
70
2.2
Kromekotc, white
MATERIAL: 2 Fuel Oil, 1 Purple
DROP #
3
1
2
4
5
7
6
8
9
10
GPM
SIZE
3200*
3100
3000
2900
2800
2700
2600
2500
2400
2300
SYSTEM:
STA.
DROP *
73
1A
MMD = 67. 72+0. 1420 (Spot D Max) = 3200
HIDAL
SIZE
100 (smallest)
= 237.3 Microns
Max. Sph. Dia. = 67.72+0.1420(3200) = 320J = 522.1 Microns
6.430
Min. Sph. Dia. = 63 Microns
�MASS DEPOSIT
MATTRIAL-
2 Fuel O i l , 1 Purple
DAIE.
7 J u l v 1963
FLIGHT *:
SAMPLE LIN::TIKi; OF R£1.!LASE:
DURATION
FLOW RATE:
SYSTEM:
j
8
ALTITUDE:
0435
13.5
STATION 1 G . P . A .
STATION
Stations 1 - 65 fclar.k
Hours
CFM
HIDAL
AIRSPEED:
A
71
55
Kn^'
75
AIRCRAFT COURSE:
Fee".
270
Degrees
Sec.
G.P.A.
STATION'
66
67
68
69
70
71
72
73
7i
75
76
77
78
79
80
Stations
Total
13.2
G.P.A.
STATION G . P . A .
0.0
0.1
0.6
1.1
1.0
1.1
1.1
0.8
0.6
1.0
1.0
1.8
2.9
0.1
0.0
81 - 100 Blank
�r •
*!«
I*
f'
•j.
I
r
i
I
:
' July ll*
S«^lr LIB*
Typ* Ai ••^f-
UL
IOC
IK
WC
1000
••III ((•««)
noc
1201
IMC
MOO
iioo
luc
ino
1100
i»o
�96
MASS DEPOSIT
2 Fuel Oil, 1 Purple
MATERIAL:
DAIE:
FLOW RATE:
7 July 1963
SYSTEM:
FLIGHT *:
4
A
ALTITUDE:
TIME OF RELEASE :
12.5
DURATION:
STATION
0437
G.P.A.
STATION
Hours
55
Knots
75
AIRCRAFT COURSE:
Feet
270
Dodoes
Sec.
G.P.A.
STATION
Stattcns 1 - 11 Blank
12
13
14
15
16
17
18
19
20
21 .
22
23
24
25
?6
27
. ' 28
29
Stat ions
CtM
HIDAL
AIRSPEED:
SAMPLE LINE:
71
0.0
0.1
0.1
0.3
0.4
0.4
0.3
0.4
0.8
0.8
1.0
1.3
2.0
1.0
1.9
1.5
0.4
0.0
30 - 100 Blank
Total 12.7
G.P.A.
STATION
C-.P.A.
�1 T*r
0. It
'^ F«
All itvlr
:
«X
/x
»3C
<OC
1199
HOC
1200
IJOO
ItX
IMC
»
Allculc CmirB*
TIM of •»>••••
.
770 b*Kr*«
Ok)7
1790
lUt
tVjC
I'M
�99
MEDIAN DIAMETER
CONVERSION FACTOR:
7 July 1363
DATE:
PAPER:
5
T 4:
,E LIKE:
STA,
27
:i
24
27
24
27
27
27
27
27
Kromekotc, white
MATERIAL: 2 Fuel Oil, 1 Purple
A
71.0
RATE .
2.2
DROP #
2
1
A
5
3
7
6
9
10
8
SYSTEM:
GPM
SIZE
A 600
3800
3200*
3100
300U
2VOO
2800
2700
2600
2500
STA.
27
HMD = 67 .7 2+0. 14 2 3 (Spot D Max)- 3200
DROP #
1A
HIDAL
SIZE
lC;;(::mallost)
= 237.3 Microns
Ma?:. Spu. Dia. = 67.72+0.1420(AoOO) = 4600 = 723.8 Microns
6.430
Min. Sph. Dia. = 63 Microns
�100
MASS DEPOSIT
:-!ATIRIA'_:
2 Fuel Oil, 1 Purp1*
:JA!.-.
FLOU RATE:
7 .Tuly 1963
SYSTEM:
-LI:HT->
5
A
ALTITUDE:
1IIDAL
AIRSPEED:
SAMPLE L:\.-.-.
:iMi CY UiL.-'ASE:
0456
".. Ki. ::-.•:.
13
'LATI5N
17
IS
19
?0
21
22
23
?->
2i>
26
G.P.A.
STATION
1 - 1 6 Blank
Hours
AIRCRAFT COURSE:
G.P.A.
STATION
G.P.A.
•.. . 4
•:..8
ij.'J
1.1
JS
3-
1.
J <-
:3
i'..-i-.io
55
so
Knots
Feet
270
Degrees
Sec.
2.1
1.8
l.'J
1.8
1.3
l.S
i.7
2.5
"/
GPK
71
- 100 blank
7. Recovery - 93.6
Total
26.0
STATION
G.P.A.
�T"
M'LX'
!ij
U?';
...
...
M *
f
i—
'T'
f
I
.
;>ji: P
I
r i i KI>.
1::
LI
S-n>l' ' a*
Alllcu.
i
jjc
\i .; :
«:.
v.
1
1 •
. , ..
. 1 . . -^ t 1 t
113C
1 1 11
1290
-J-- 1-
I1X
. ..
-1 . .
:
UC
i . I
;
.
-• , ' u .
i
i
-
- -
|
v. ?••••
«f«f.-.
-
-"
1
j
t
,
i l »»
l
•
tr ,r««r
I
,
1
^
A
Atrapw-
1
.
7 )u. * ! ' • ! > '
l
--J
.
- - - • -!--»-- J
ISM
- '
IUC
' --
....
I70C
i ...
I'.X
!
. . .!
�102
MASS DEPOSIT
MATERIAL: 2 Fuel Oil. 1 Purple
FLOW RATE:
DATE:
SYSTEM:
FLIGHT #:
7 July 1963
6
AIRSPEED:
SAMPLE LINE:
TIME OF RELEASE:_
DURATION:
HIDAL
10
STATION G.P.A.
STATION
Stations 1 - 6 8 Blank
Hours
Knots
55
ALTITUDE:
0457
GPM
71
Feet
50
AIRCRAFT COURSE:
270
Degrees
Sec.
G.P.A.
STATION
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
G.P.A.
STATION
0.5
1.1
2.7
2.0
1.7
0.5
0.9
1.0
1.7
1.8
2.3
1.8
0.6
0.5
0.3
Stations 84 - 100 Blank
Recovery - 6 . 8
9.
Total
19.4
G.P.A.
�:__i
j
•/i
i . ._K.I
j
;
!
i
.1i
!
'00
IBS
IHC
1
1
i
.
_
u»
__
1
!
.
•
'
'i:
.^
nx
�104
MASS DEPOSIT
MATER IAL : 2 Fuel. Qjl. 1 Purple
FLOW RATE:
DATE:
SYSTEM:
7 July 1963
FLIGHT # :
SAMPLE LINE:
7
DURATION:
ALTITUDE:
0518
13
STATION G.P.A.
STATION
Stations 1 - 7 1 Blank
Hours
GPM
HIDAL
AIRSPEED:
A
TIME OF RELEASE:
80
75
Knots
75
AIRCRAFT COURSE:
Feet
270
Degrees
Sec.
G.P.A.
Total
STATION G.P.A.
17.8
STATION G.P.A.
72
0.0
73
0.1
2.4
74
2.0
75
76
1.5
77
1.3
78
1.1
1.2
79
80
1.5
81
1.2
82
1.9
83
0.5
84
0.8
1.0
85
0.6
86
0.4
87
0.2
88
0.1
89
0.0
90
Stations 91 - 100
Blar.k
�.r i~
U-U
t"
•L-
i
i
L
i
L
_J
;
;
N-
i
i
J
i
i
I
7 jg;,
*
;.:•>•
Ha: r t t t
I S]>rijTrt
;:;
7 Pur ',i
. ' .' »
.I
/) Prrr
Al-l'ud r
—ir
g
J
A
l
•
i
i
.L ..
s.c
i
i
\
I
!
| --
.-'
ncc
me
1110
1401
IVK
isoc
i'jc
I..
J
�107
MASS MEDIAN DIAMETER
7 July 1963
DAT£:
CONVERSION FACTOR:
8
FLIGHT #:
PAPER:
80.0
FLOW RATE:
STA
24
29
24
29
29
29
26
24
24
24
DROP #
1
3
2
4
5
6
7
8
9
10
Kromekote, white
MATERIAL: 2 Fuel Oil, 1 Purple
A
SAMPLE LINE:
2.2
GPM
SIZE
3700*
3500
3300
3200
3100
3000
290C
2700
2600
2500
SYSTEM:
STA.
DROP #
29
1A
MMD = 67. 72+0. 1420 (Spot D Max) = 3700
Con. Factor =2.2
HIDAL
SIZE
100 (smallest)
= 263.5 Microns
. 6.355x2,2
Max. Sph. Dia. = 67.72+0.1420(3700) = 3700 = 593.0 Microns
6.430
Min. Sph. Dia. = 63 Microns
�108
MASS DEPOSIT
J-iVflii.lAL:
? Fuel Oil, 1 Purple
."ATi-:.
7 July 1963
r LIGHT >:
SAMi'LE LINE:
DURATION:
G.P.A.
GPM
3.5
STATION
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
Stations
Hours
75
Knots
ALTITUDE:
0520
HIDAL
AIRSPEED:
£
Stations 1 - 2 2 Blank
80
SYSTEM:
8
LIMt OF Ril.EASE:
STATION
FLOW RATE:
75
Feet
AIRCRAFT COURSE:
270
Degrees
Sec.
G.P.A.
STATION
0.0
0.3
2.6
1.0
0.9
0.7
0.7
1.0
0.6
0.2
1.0
0.6
0.5
0.5
0.3
0.3
0.1
0.0
41 - 100 Blank
Total
11.5
G.P.A.
STATION
G.P.A.
�a
:»
�Ill
MASS MEDIAN DIAMETER
7 July 1963
UA :.-.-:
CONVERSION FACTOR:
9
FLIGUT #:
PAPER:
SAMPLE LIKE:
A
FLOW dATE:
80
STA
75
75
75
73
75
75
76
75
75
75
MATERIAL:
GPM
DROP #
3
1
2
4
5
9
10
6
8
7
SIZE
4100*
3900
3800
3700
3600
3500
3400
3300
3200
3100
MMD = 67. 7 2+0. 14 20 (Spot D Max)
SYSTEM:
STA.
DROP #
90
1A
= 4100
Kromekotc, white
2 Fuel Oil, 1 Purple
HIDAL
SIZE
100 (smallest)
= 295.3 Microns
. Sph. Dia. = 67.72+0.14 ^.(4100) = 4100 = 649.8 Microns
6.430
Min. Sph. Dia. = 63 Microns
2.2
�112
MASS DEPOSIT
MAIliKIAL: 2 Fuel Oil. 1 Purple
FLOtf RATS:
7 July 1963
SYSTEM:
FLIGHT -:
AIRSPEED:
SAMPUi LINK:
ALTITUDE :
TIMJi OF KJ-:LEASE:
DURATION:
0533
Hours
11
GPM
80
HIDAL
55
Knots
75
Feet
Sec.
STATION
STATION G.P.A.
Stations 1 - 7 3 Blank
AIRCRAFT COURSE:
G.P.A.
STATION
G.P.A.
270
STATION
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
n
92
Degrees
G.P.A.
0.0
1.0
1.8
1.2
1.6
1.5
1.8
0.9
0.8
1.2
0.9
0.8
0.7
i.. 5
;).6
-.5
.!'.1•
'.
.I
Jt.lt l u l l .
Total
16.3
I
�1'
T
•
I
'
I
__J
h_
L
T"
i
-t-
.1"
I
t
I
1
• -
-
!>•(•
Julv
nifht f
S^l« Lin*
1 " "
'9M
.
Trpv Ait*-,-'"
1
•wind, iw cm
Nit«rl*l !>pr«»«t
•
A t : KIM!*
Alriprrd
Alrerafl CMrta
•
•
PJ«: Oil. 1 Pti.t.'
.l£Dy.
!> r**i
« bo' •
<u ^^rr**
j
j
|
j
1
"•-
A
'
1
I
—
j..
'X
120:
TUG
isco
i
- -
-<uc
i?oc
luc
�114
MASS DEPOSIT
MATERIAL:
2 Fuel Oil. 1 Purple
DATE:
7 July 1963
FLIGHT #:
SYSTEM:
10
DUR AT ION:
ALTITUDE:
0535
Hours
GPM
UIDAL
55
AIRSPEED:_
SAMPLE LINE:
TIME OF RELEASE;
80
FLOW RATE:_
AIRCRAFT COURSE:
75
Knots
Feet
270
Degrees
Sec.
13
STATION
STATION G.P.A.
Stations 1 - 2 3 Blank
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
G.P.A.
STATION
0.0
0.7
1.6
1.3
1.1
0.7
0.8
1.1
1.1
1.1
1.0
0.3
1.0
0.6
0.5
0.5
0.4
0.3
0.1
0.1
0.1
0.0
Stations 46 - 100 Bla.ik
Total
14.4
G.P.A.
STATION
G.P.A.
�HI
T~T—r
i i
-t-
*>•, H.U
•••
'<; ;-.v.i : • • = • • i -.; .
. c«d
—
•
ta.
>-
>• ••• i F
r
-••!'.
,
,
v* _
!
D"«
"itf" '
100
«c
IMO
1109
1200
1100
ItiO
1100
• : July mi
i 10
!«*!• U»
Tn« »l-.^,,d
IUI*|I«I Sptcycrf
: 1
Infltf. «0 cm
• 2 r.Ml oil. 1 Fu-n:-
1600
1700
». •: D,.
III
HOC
2300
�116
MASS DEPOSIT
MAT5&IAL:
2 Fuel Oil, 1 Purple
DAJE:
FLIGHT #:
FLOW RATE:
7 July 1963
SYSTEM:
80
GPM
HIDAL
11
AIRSPEED:
55
Knots
B
ALTITUDE:
100
Feet
SAMPLE LINE:
TIME OF RELEASE:
0605
DURATION:
19
Hours
AIRCRAFT COURSE:
315
Degrees
Sec.
STATION G.P.A.
STATION
Stations 1 - 2 3 Blank
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
G.P.A.
STATION
00
.
0.9
0.7
04
.
0.8
0.7
0.5
0.4
0.5
0.3
0.9
1.1
04
.
0.2
0.0
Stations 39 - 100 Blank
Total
7.6
G.P.A.
STATION G.P.A.
�J_j-!
i
�119
MASS MEDIAN DIAMETER
DATE:
7 July 1963
CONVERSION FACTOR:
12
FLIGHT #:
PAPER:
SAMPLE LINE:
B
FLOW RATE:
80
GPM
DROP #
SIZE
4100*
4000
3900
3800
3700
3500
3400
3200
3100
3000
STA.
81
84
77
77
77
87
86
78
78
79
2.2
Kroraekote, white
MATERIAL: 2 Fuel Oil, 1 Purple
4
5
1
2
3
9
8
6
7
10
SYSTEM:
STA.
90
MMD = 67. 72+0. 1420 (Spot D Max) = 4100
DROP #
1A
HIDAL
SIZE
75 (smallest)
= 295.3 Microns
Max. Jph. Dia. = 67.72+9.1420(4100) = 4100 = 649.8 Microns
6.430
Min. Sph. Dia. = 48 Microns
�120
MASS DEPOSIT
MATERIAL:
DATE:
FLIGHT #:
FLOW RATE:
2 Fuel Oil, 1 Purple
7 July 1963
"*
SYSTEM:
ALTITUDE:
B
TIME OF RELEASE:
DURATION:
0607
Hours
14
GPM
HIDAL
AIRSPEED:
12
SAMPLE LINE:
80
AIRCRAFT COURSE:
55
Knots
100
Feet
315
Degrees
Sec.
STATION G.P.A.
STATION
Stations 1 - 7 6 Blank
G.P.A.
STATION
•
Total
10.1
STATION
G.P.A.
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
Stations
•
G.P.A.
0.0
0.4
1.0
0.8
0.4
1.4
0.7
0.9
0.6
0.6
0.7
0.6
0.2
0.5
0,2
0.2
0.2
0.1
0.3
0.2
0.1
0. 0
99 - 100
Blank
�-i.i-
\ f /'
I
. ' juir mi
t 17
;
•
I
ImrtfHf, «J CFN
. -' F"! on. : r U '»i.
O . J I l^n
I
A l r c n r r Cm.it*
TlH of «•:••••
I
L
\
)J.
9oc
<OC
f)
IOC
I:M
1100
1200
IMC
HOC
1500
uoo
CM
'ico
:vx
�122
MASS DEPOSIT
MATERIAL:
7 July 1963
DATE.
SYSTEM:
13
FLIGHT #:
SAMPLE LINE :
TIME OF RELEASE:
DURATION:
GPM
80
HIDAL
AIRSPEED:
0644
11.5
Hours
75
Knots
ALTITUDE:
B
STATION G.P. A.
STATION
Stations 1 - 1 6 Blank
17
18
19
20
21
22
23
24
25
26
27
28
29
FLOW RATE:
2 Fuel Oil, 1 Purple
100
Feet
AIRCRAFT COURSE:
315
Degrees
STATION
G.P.A.
Sec.
G.P.A.
STATION
0.3
0.1
0.7
0.9
0.6
0.6
1.3
0.8
0.9
O.I
o.y
0.5
O.I
Stations 30 - 100 Blank
Total
7.8
G.P.A.
�r-
'—r
j
L2J
___
-
i /•
\J
.1
D"*
Fllghr 9
SMplr Lin*
T»p* Arr<«ptHl
fUivrlal bpi«jF^
AltlcuJ.
Alr«p*«d
A i r c r a f t CowrM
TIM *r >»!••••
: I July 19*1
. 1 1
I
loirlad. IS CTH
; r<*l Ml. 1 Pvrpl-.
0. Il Dy.
100 FM(
:
: 7} Uoti
: 11% D*|r>«i
; 0644 lour*
:
.
•
1
i MO
noo
1200
1700
1100
1«C
�125
MASS MEDIAN DIAMETER
7 July 1963
DATE:
CONVERSION FACTOR:
14
FLIGHT #:
PAPER:
B
FLOW RATE:
80
GPM
DROP *
STZE
3100
3000
2700
2400*
2300
2200
2100
2000
1900
1800
1
2
10
9
3
4
6
5
7
8
Kromckote, white
MATERIAL:
SAMPLE LINE:
STA
74
74
72
70
73
73
73
74
73
73
2.2
2 Fuel Oil, 1 Purple
SYSTEM:
STA.
62
MMD = 67.72+0. 1420 (Spot D Max) = 2400
DROP #
1A
HIDAL
SIZE
100 (smallest)
= 185.7 Microns
Max. Sph. Dia. = 67.72+0.1420(3100) = 3100 = 507.9 Microns
6.430
Min. Sph. Dia. = 63 Microns
�126
MASS DEPOSIT
MATERIAL:
DATJ::
FLOW RATE:
2 Fu=l Oil, 1 Purple
SYST£M:
SAMPLE LINE:
B
TIM,; OF RELEASE:
C646
DURATION:
09
STATION' G.P.A.
STATION
Hours
75
ALTITUDE:
14
100
GrVi
H1DAL
AIRSPEED:
7 July 1963
KLIG:IT >>:
80
AIRCRAFT COURSE:
i\noto
Fee:
315
Degrees
Sec.
G.P.A.
STATION G.P.A.
STATION G.P.A.
Stations 1 - 69 Blank
70
71
72
73
7A
75
76
Stations
0.3
0.3
O.A
0.4
C.9
0.7
0.0
77 - lJv< Blank
% Recovery - 15.6
Total
3.6
�;
P
'[
,
.
/
" i - /
-
-
IK
soc
900
130
MOO
1200
IJU
1430
1JM
IM»
inc
�128
MASS P£POSIT
MATERIALDATE :
SYSTEM
7 Julv 1963
FLIGHT rf:
A
TIME OF RELEASE.
0658
ALTITUDE:
16
STATION G.P.A.
STATION
Stations 1 - 6 9 Blank
Hours
GFM
S5
Knc«. s
HIDAL
AIRSPEED:
15
SAMPLE LINE:
U-JRATION-
80
FLOW RATE-
2 Fuel Oil. 1 Purple
AIRCRAFT COURSE
Fi>£.
50
270
fcp.OiS
Sec.
C.P.A.
STATION
70
71
72
73
7'»
75
76
77
78
79
80
81
G.P.A.
STATION
0.5
0.3
2.5
2.4
1.6
1.6
1.3
0.9
1.6
2.,
.'
o.:;
0.5
Stations 82 - 100 BldiA
% Recovery - 52.7
Total
16.5
G.P.A.
�UC
900
I3UO
HO
IMC
IttO
�131
MASS MEDIAN DIAMETER
7 July 1963
DATE:
CONVERSION FACTOR:
16
FLIGHT #:
PAPER:
SAMPLE LINE:
A
FLOW RATE:
80
CPM
DROP *
SIZE
40*
00
3900
3800
3700
3600
3500
3300
3200
3100
3000
STA
29
25
29
28
29
25
27
25
25
30
MATERIAL:
9
4
3
1
2
5
10
7
6
8
SYSTEM:
STA. . DROP *
43
MMD = 67.72+0. 1420 (Spot D Max) = 4000
1A
Kromekote, white
2 Fuel Oil, 1
Purple
UIDAL
SIZE
100 (smallest)
- 288.9 Microns
Max. Sph. Dia. = 57.72+0.1420(4000) = 4000 = 635.6 Microns
6.430
Min. Sph. Dia. = 63 Microns
2.2
�132
MASS DEPOSIT
MATERI.AL:
2 Fuel Oil. 1 Purple
DAT £:
SYSTEM:
7 July 1963
FLIGHT ./:
80
FLOW RATE:
16
GPM
HIDAL
AIRSPEED:
SAMPLE LINE:
ALTITUDE:
TIME OF RELEASE;
0700
DURATION:
16
Hours
AIRCRAFT COURSE :
55
50
Knots
Feet
270
Degrees
STATION
G.P.A.
Sec.
STATION
STATION G.P.A.
Stations 1 - 2 5 Blank
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
G.P.A.
1.3'
STATION
1.0
1.5
1.4
0.8
1.4
0.5
0.5
0.8
0.4
0.5
0.8
0.8
'0.6
0.7
0.7
0.4
0.5
0.9
0.5
Stations 46 - DO Blank
Total
16.0
G.P.A.
��135
H-34/HIDAL GROUND FLOW & FLIGHT DATA
DATE CALIBRATED;
6 July 1963
DATE TEST FLOWN:
8 July 1963
LIQUID SPRAYED; 2 Fuel Oil. 1 Purple
TOTAL NOZZLES OPEN.
NOZZLE TYPE:
_^
LIQUID TEMP:
Sec.
PUMP PRESSURE:
Col.
FLOW RATE CALIBRATED:
8015
DURATION OF SPRAY.
30
TOTAL AMOUNT SPRAYED
39.5
60
33.5° C
38-28
PS I
80
GPM
OPERATIONAL DATA DURING FLIGHT
Above Information is for Runs 1 - 10.
DATE CALIBRATED-
6 July 1963
DATE TEST FLOWN.
LIQUID SPRAYED; 2 Fuel Oil. 1 Purple
TOTAL NOZZLES OPEN:
NOZZLE TYPE:
8 July 1963
LIQUID TEMP:
Chock Valves
DURATION OF SPRAY:
TOTAL AMOUNT SPRAYED;
20
27.5
60
36° C
Sec.
PUMP PRESSURE:
Gal.
FLOW RATE CALIBRATED-
OPERATIONAL DATA DURING FLIGHT
Above information is for Runs 11 - 14.
20.5
83
PSI
GPM
�136
MASS DEPOSIT
MATERIALS
DATE:
FLIGHT ':
'
8 July 1963
SYSTEM:
TIM!-: OF RELEASE:
c
HIDAL
ALTITUDE:
0410
12
STATION G.P.A.
STATION
Stations 1 - 3 0 Blank
Hours
C-PM
80
AIRSPEED:
1
SAMPLE LINE:
DURATION:
FLOW RATE:
2 Fuel Oil, 1 Purple
Knots
55
Feet
75
AIRCRAFT COURSE:
360
Degrees
Sec.
G.P.A.
STATION
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
Total
27.3
G.P.A.
0.2
0.3
0.8
0.6
0.6
0.4
0.3
0.3
C.4
0.4
C.4
0.4
0.5
0.8
1.1
1.0
1.4
I.'}
2.1
2.1
1.3
2.3
1.4
1.2
3.0
G.P.A.
76
1.9
Stations 77 - 100
Blank
STATION
�_ __[_._.
I
•
_
-
D«rr
J
1
/-T
i
_.J
7.-C
IOX
S-oi- f'wil
. .
!„ .
.
:
o.!l BT»
• 71 rrrr
. 1% £»»'.
Jft i £»••(
'
L..1
I . 11
1
11
: ft Juiy !
J-Ji. L:..
*!• U-»*
Alrapavrf
A J r i K . t ^our»
•
HOC
i 1 . . .i
1MO
IWC
1 1 . 1
I4X
ISOO
I6X
17%
HX
1KC
--t.J
:,•»
�138
MASS DEPOSIT
MATERIAL:
2 Fuel Oil. 1 Purple
DATE :
FLIGHT #:
8 July 1963
SYSTEM:
2
55
ALTITUDE:
TIME OF RELEASE:_
0413
13
STATION G.P.A.
STATION
Stations 1 - 1C Blank
Knots
Feet
75
AIRCRAFT COURSE:
Hours
GPM
HIDAL
AIRSPEED:_
SAMPLE LINE:
DURATION:
80
FLOW RATE:
360
Degrees
STATION
G.P.A.
Sec.
G.P.A.
STATION
G.P.A.
11
C.I
0.2
0.3
0.4
0.6
0.7
0.8
1.1
1.0
l.J
•21 • 2.7
22
1.8
23
1.9
4.J
24
2.0
25
2 .4
26
Otstior.s 27 - 100 Slanl..
12
13
14
15
16
17
18
19
20
'
Total
22.2
�!
1
•
i
\
1
.. —
\.
/%
— •
:
i
•
*
•
i
i
i
1
•
;
1
]
i
i
.
••
—'
—
•
— • •
_;
X
•
:
. ._,!
i
,_
i
.. — i . " :.
—
i
!
'
;i•
4il
!
i
!
i _,
».!nk: *
;
.. . ' .... .1 _ ! . 1_ J .
i
~jf •
\
K.-..,.
L
'.;.
i
j
i
UK
,,
- v
. • • '.,.!..
' Xe.tlttf
I
1
i
i
!
.—..-i
1.
i
i- ,
IJK
utc
i
.. i
i
...i
'i:::.. !
: 1..U-,
(
1
;::
iPr.~d
X
IS c:
! cc
•'::
i
.j
i
|
! i i
'IX.
�141
MASS MEDIAN DIAMETER
8 July 1963
DATE:
CONVERSION FACTOR:
PAPER:
3
iT *:
,E LINE:
,B
I
\ 80
RATE:
,
STA.
24
24
20
20
20
20
20
20
20
20
2.2
Kromekote, white
MATERIAL: 2 Fuel Oil, 1 Purple
GPM
SYSTEM:
HIDAL
I
DROP #
2
1
3
4
5
6
7
10
9
8
SIZE
4000
3200*
3000
2900
2800
2700
2600
2500
2400
2300
STA.
DROP 0
20
1A
HMD = 67. 72+0. 1420 (Spot D Max)= 3200
SIZE
lOO(smallost)
= 237.3 Microns
Max. Sph. Dia. = 67.72+0.14iO(4000) = 4000 = 635.6 Microns
6.430
Min. Sph. Dia. = 63 Microns
�142
MASS
MATERIAL: 2 Fuel Oil, 1 Purple
*LOW RATE:
DATE:
SYSTEM:
8 July 1963
FLIGHT #:
3
SAMPLE LINE:
TIME OF RELEASE:
DURATION:
B
ALTITUDE:
0432
13
Hou?s
GPM
FIDAL
AIRSPEED:
STATION G.P.A.
STATION
Stations 1 - 9 Blank
10
11
12
13
14
15
16
17
18
1-3
20
21
22
23
24
25
26
27
Stac-on3
SO
AIRCRAFT COURSE:
75
Knots
75
Fc«.-»
315
D^rees
Sec.
G.P.A.
STATION
0.3
0.2
0.4
0.4
0.2
0.3
0.4
0.5
1.4
1.0
0.9
1.5
2.1
2.3
!..«
1.7
5.3
0.2
28 - loO Blank
Total
2;i. 3
G.P.A.
STATION
G.P.A.
��144
MASS DEPOSIT
MATERIAL:
2 Fuel Oil, 1 Purple
DATE:
FLIGHT #:
SAMPLE LINE:
FLOW RATE :
8 July 1963
SYSTEM:
4
GFM
80
HIDAL
AIRSPEED:
TIME OF RELEASE:
0434
DURATION:
11
STATION G.P.A.
STATION
Stations 1 - 6 1 Blank
Hours
Knot
ALTITUDE:
B
75
75
Feet
AIRCRAFT COURSE: 315
Degrees
S°c.
G.P.A.
STATION
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
G.P.A.
STATION
0.5
0.5
0.3
0.7
0.5
0.8
1.0
1.4
1.7
2.2
1.6
2.2
1.4
1.2
1.1
0.5
Stations 78 - 100 Blank
Total
17.6
G.P.A.
�"L
- r
,
K\
i
N
•
i
•
'
.
i
•
'
:
•
:
I
i
i
'
t
I
i, , ; , ,1
;
1
.
i
-
t
I
l
i
i
. , . . " ! : , :
t
-
r
1
i
1
..."
... I . -
-
.J
. .,0
�146
MASS DEPOSIT
MATERIAL: 2 Fuel Oil, 1 Purple
FLOW RATE:
DAIE: '
SYSTEM:
8 July 1963
FLIGHT *':
SAMPLE LINE:
5
AIRSPEED:
A
TIME OF RELEASE:
DURATION:
ALTITUDE:
0455
12
STATION G.P.A.
STATION
Stations 1 - 6 3 Blank
Hour
8J
GPM
HIDAL
75
Knots
Feet
50
AIRCRAFT COURSE:
270
Degrees
STATION
G.P.A.
Sec.
G.P.A.
STATION
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
G.P.A.
0.2
0.8
1.9
1.0
0.7
0.7
1.8
1.7
1.7
1.1
1.0
0.7
0.2
0.5
0.2
Stations 79 - 100 Blank
Total
14.2
�i
j
:
:
i
i
i
.1
...
i
;
t
'
:
!
• ••; M i ,
;
I
!
f --
'
i
i
!
i
!
1
:
i
i
1
I
!
!
,
!1
!
'
•
i
i
^_
: /
'
I
'
i
i
1
1
i
i
~r~-
i /I A
^ . J
'7X
njc
-if.
rat
�149
MASS MEDIAN DIAMETER
DATE;
8 July 1963
CONVERSION FACTOR:
IT #:
6
PAPER:
.E LINE:
A
MATERIAL:
RATE:
80
STA
22
22
22
23
22
24
21
21
22
22
GPM
DROP *
1
3
2
4
6
5
8
7
10
9
SIZE
290J*
2800
2700
2600
2500
2400
2300
2200
2100
2000
SYSTEM:
STA.
22
MMD = 67. 72+0. 1420 (Spot D Max) = 2900
DROP #
1A
Kromekote, white
2 Fuel Oil. 1 Purple
HTDAL
SIZE
100 (ctnal lest)
= 217.9 Microns
Max. Sph. Dia. = 67.72+0.1420(2900) = 2900 = 479.5 Microns
6.430
Min. Sph. Dia. = 63 Microns
2.2
�150
MASS DEPOSIT
MATERIAL:
2 Fuel Oil, 1 Purple
IMTC:
8 July 1963
FLIGHT *:
0457
DURATION:
'3
G.P.A.
GPM
HIDAL
STATION
Hours
75
Knots
ALTITUDE:
A
50
Feet
AIRCRAFT COURSE:
270
Degrees
STATION
G.P.A.
Sec.
G.P.A.
STATION
Bl?-'
St.ations
80
AIRSPEED:
TIME OF RELEASE:
15
16
17
18
19
20
21
22
23
24
25
26
27
SYSTEM:
6
SAMPLE LINE:
STATION
FLOW RATE:
0. 4
0.4
0.5
0.7
1.0
1.6
2.0
J.7
O.-J
il.9
i> . 7
I.-.)
3.1
- 100 Blank
Total 14.8
G.P.A.
�'
.
-I 1 ',
1
/'"""SaX *•'•:•] ik. / -**• •*• •*». '^
.--iT'"^.'
*^^
•' A~
f — -
�152
MASS DEPOSIT
MATERIAL:
2 Fuel Oil. 1 Purple
DATE:
8 Ju ly 1963
SYSTEM:
FLIGHT #:
TIME OF RELEASE;
DURATION:
GPM
HIDAL
AIRSPEED:_
0515
12
STATION
STATION G.P.A.
Stations 1 - 9 Blank
Hours
75
Knots
ALTITUDE:
SAMPLE LINE:
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
Stations
80
FLOW RATE:_
75
Feet
AIRCRAFT COURSE;
270
Degrees
Sec.
G.P.A.
STATION
0.0
0.7
04
.
0.5
1.0
0.7
0.7
0.8
0.8
1.2
0.9
2.3
0.0
28 - 100 Blank
Total
10.8
G.P.A.
STATION
G.P.A.
�"T
I
-i
111
i
h-ft-v- fI M 1V
* —
Lj-a_L_L- . - ~.i i_L
-C
�154
MASS DEPOSIT
MATERIAL:
FLOW RATE:
2 Fuel Oil, 1 Purple
DAT.-;:
SYSTEM:
8 July 1963
80
GFM
HIDAL
FLIGHT #:
8
AIRSPEED:
75
Knots
SAMPLE LINE:
A
ALTITUDE:
75
Feet
TIMS OF RELEASE:
DURATION:
0517
15
STATION G.P.A.
STATION
Stations 1 - 6 1 Blank
Hours
AIRCRAFT COURSE:
270
Degrees
STATION
G.P.A.
Sec.
G.P.A.
STATION
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
Stations
Total
11.7
G.P.A.
0.1
0.2
0.2
0.5
0.7
Missing
0.7
0.9
1.2
1.0
0.9
1.1
0.3
0.7.
2.6
0.0
78 - 100 Blank
�f"
!
. . . . . . . . .j
" "
:
j
i
!
i i
,
!
i
—•-
Ii
i
|
i
1
•
•
i
•
"
._
i
i
(
..
i
i
'
'
.
.
j
i
j_
1
f
j
•
'
.
;
i
:
i
'•
.
i
i
\j
j
i
j
•
ii
--Ii •
i
i
;
!
^.-H
i
.- .
L_L1^L_\_.
S.
i
: ' -ii '
i
•
^
. :
_i_ ._....! ... L-
!
i
^"''l
'*
!
i
:
i
•
- - :-
!
--.
;
;
*•
.
|
.._.
'
!
i
_ :
!
-
i
i-Li.a.j «
�156
MASS DEPOSIT
MATERIAL: 2 Fuel Oil, 1 Purple
FLOW RATE:
DATE:
SYSTEM:
8 July 1963
FLIGHT #:
9
SAMPLE LINE:
HIDAL
0548
16
Hour
55
Knots
ALTITUDE:
A
STATION G.P.A.
STATION
Stations 1 - 1 4 Blank
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
GPM
AIRSPEED:
TIME OF RELEASE:
DURATION:
80
75
Feet
AIRCRAFT COURSE:
27Q
Degreea
Sac.
G.P.A.
STATION
0.1
0.4
0.4
0.3
0.5
1.2
1.9
1.6
1.1
1.3
0,7
1.6
1.6
3.0
C.3
Stations 30 - 100 Blank
Total
16.0
G.P.A.
STATION
G.P.A.
�.
-I..
I
i
1
y
i..
^
.1
II
/•
/\
1
I. .
i
1
^
1
-
1
r
— i
i
;
!
•
•
-
Ju.*
r'l'f.. r
SMll*
,
•
i
\
•
•
r
... !ii ..;ir .!' ..;
i
I
i.
i
"
]
_
t
!
'
— •-•?!
1
\
'
llnr
•U rrl
fv J 0
. i UY»
l
J P-r:
i\ r«w >•
A •1 u
Altuff n1
.
,
,M*
1
°*"* .—••
**"*""
"
1
.
•
1'
-
i . ,
1100
- -I—
19
:
I2X
1MO
I«C
IS*
-
.:."
IUC
i;»
1IX
:«X
�MASS MEDIAN DIAMETER
DATE:
8 July 1963
COWERSICN FACTOR:
10
FLIGHT #:
PAPER:
SAMPIJi LINE:
A
FLOW RATE:
80
STA
77
76
77
73
77
77
79
77
71
75
2.2
Kromekote, white
MATERIAL: 2 Fuel Oil, 1 Purple
GPM
DROP #
4
2
3
1
5
6
8
10
9
7
SIZE
3300*
3800
3700
3600
3500
3400
3300
3200
3100
3000
SYSTEM:
STA.
75
MMD = 67. 72+0. 1420 (Spot D Max) = 3900
DROP #
1A
HIDAL
SIZE
lOO(smallest)
= 282.4 Microns
Max. Sph. Dia. = 67.72+0.1420(3900) = 3900 = 621.4 Microns
6.430
Min. Sph. Dia. = 63 Microns
�160
MASS DEPOSIT
MATERIAL:
RATE:
2 Fuel Oil, 1 Purple
8 July 1963
FLIGlir *:
SAMPLE LINE:
SYSTEM:
80
C-PM
HIDAL
10
AIRSPEED:
55
Knots
A
ALTITUDK:
75
Feet
TIME OF RELEASE:
DURATION:
FLOW 3ATE:
0550
14
STATION G.P.A.
STATION
Stations 1 - 6 4 Blank
Hours
AIRCRAFT COURSE:
270
Degrees
Sec.
G.P.A.
STATION
65
66
67
68
69
70
71
72
73
76
75
76
77
78
79
80
Stations
Total
18.8
G.P.A.
STATION
0.3
0.3
0.4
0.9
0.9 .
1.3
1.5
2.0
2.0
0.9
1.1
1.7
1.5
2.3
1.2
0.5
81 - 100 Blank
G.P.A.
�X.
i
•
~
�162
MASS DEPOSIT
MATERIAL:
2 Fuel Oil, 1 Purple
DATE:
FLIGHT 4:
SAMPLE LINE:
TIME OF RELEASE:
DURATION:
FLOW RATE:
8 July 1963
SYSTEM:
11
AIRSPEED:
A
ALTITUDE:
0606
19
Hours
AIRCRAFT COURSE^
83.0
GPM
HIDAL
55
k.-icrs
75
Feet
270
Deerets
STATION
C-.P.A.
Sec.
STATION G.P.A.
STATION
16
Stations 1 - 1 5 Blank
17
18
19
20
21
22
23
24
25
26
27
28
23
30
31
32
G.P.A.
STATION
0.1
0.4
06
.
2.2
1.3
1.9
2.2
2.0
2.3
1.5
1.3
1.6
6.3
0.3
0.4
0.3
0.2
Stations 33 - 100 Blank
Total
24.9
G.P.A.
��165
MASS MEDIAN DIAMETtiR
8 July 1063
DATE:
CONVERSION FACTOR:
12
FLIGHT #:
SAMPLE LINE:
A
83
FLOW RATE:
MATERIAL:
GPM
STA.
DROP #
77
73
73
2
1
7
3
4
8
6
5
9
10
73
73
73
73
73
73
73
PAPER:
SIZE
7000
6000*
5800
5700
5600
5400
5300
5200
5100
5^oO
Kroir.ek.ote, white
2 Fuel Oil, 1 Purplo
SYSTEM:
STA.
77
MMD = 67. 72+0. iv;o (Spot D Max) = 6000
DROP #
1A
2.2
HIDAL
SIZE
10;) (anal lest)
= 418.0 Microns
Max. Sph. Dia. = 67.72+J. K.IJ (7000) = 7000 = 1061.7 Microns
6.430
Min. Sph. Dia. = 63 Microns
�166
MASS DEPOSIT
MATi-RIAL:
2 Fje] Oil, 1 Purple
L
LATE ;
8 July 1963
SYSTEM:
12
FLIGHT s*:
14
G.P.A.
GPM
HIDAL
STATION
55
Knoc
ALTITUDE:
0608 Hours
TTMH OF RELEASE:
DURATION:
83.0
AIRSPEED:
A
SAMPLF. LINE:
STATION
FLOW RATE:
75
Fc-tt
AIRCRAFT COURSE:
270
Drives
Sec.
G.P.A.
STATION
Stations 1 - 72 Blank
G.P.A.
STATION
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
38
Sr at ions
G.P .A.
1.5
3.2
2.7
2.1
1.5
2.0
3.9
1.1
0.9
0.6
0.3
0.5
0.4
0.6
0.5
0.3
89 - 100
Blank
To'al
22.1
�- -- I
-i
i
;
i
l\
i
i
;i
;
—t— r *— i ~ **~ 1—
i fV
.'
I
.' I'
'
i(
;. '
j \ v ^l~ \
L_^J._JJ
<OC
Vf
v.:
too
inc
ijoc
uoo
not
i«»
1730
it?
�169
MASS MEDIAN DIAMETER
DATE:
8 July 1963
CONVERSION FACTOR:
13
FLIGHT #:
PAPER:
SAMPLE LINE:
A
FLOW RATE:
83
GPM
DROP #
1
SIZE
4100*
4000
3800
3700
3500
3400
3300
3200
3100
3000
2900
STA
79
76
81
77
76
76
76
76
76
81
76
MATERIAL:
2
4
5
11
6
9
3
7
8
10
SYSTEM:
STA.
DROP #
83
1A
HMD = 67.72+0. 1420 (Spot D Max) = 4tOO
Kromekote, white
2 Fuel Oil, 1 Purple
HIDAL
SIZE
100 (smallest)
= 295.3 Microns
Max. Sph. Dia. = 67.72+0.1420(4100) = 4100 = 649.8 Microns
6.430
Min. Sph. Dia. = 63 Microns
2.2
�170
MASS DEPOSIT
MATERIAL:
2 Fuel Oil, 1 Purple
DATE:
FLOW RAT£:
8 July 1963
SYSTEM:
GPM
83.0
HIDAL
13 '
AIRSPEED:
75
Knots
SAMPLE LINE:
A
ALTITUDE:
50
Feet
TIMt: OF RELEASE:
0628
FLIGHT #:
DURATION:
11
STATION G.P.A.
STATION
Star ions 1 - 7 5 Blank
Hours
AIRCRAFT COURSE:
270
Degrees
Sec.
G.P.A.
STATION
G.P.A.
STATION
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
G.P.A.
0.6
0.4
0.3
0.2
O.-i
1.')
1.2
0.3
0.4
l.l
0.6
1 .2
0.8
0.2 •
0.1
0.2
0.1
0.0
Stations 94 - 100
b 1 .ink
Total
10.5
�!
-i
i
4 ..
L-
'
T /"•/;, / T
I
;
1
J\
' M /
i;
;
5J
IS
s:.
1i
I
i.
'
1
!
ji
i
;
14X
IUO
!
•
.
i . . . 1 . -,.!,.,. u._L^J
IMO
DM
-
j
_,
-1; J
�172
MASS DEPOSIT
I!AV•!•:RIA L;
'~'M'-.-
2 Fuel Oil. 1 Purple
8 July 1963
FLIGHT #:
SYSTEM:
14
AIRSPEED:
0629
Hours
G?h
HIDAL
50
ALTITUDE:
SAMPUS LINE:.
T-IMfi OF RELEASE:
83.0
FLOW RATE:
AIRCRAFT COURSE:
75
F.vt
KroiE
270
Degrees
JURATION:
STATION
STATION G.P.A.
Stations 1 - 2 2 Blank 23
24
25
26
27
28
29
30
31
32
33
34
Stations
G.P.A.
STATION
0.0
1.6
1.1
1.3
1.3
0.9
1.0
1.2
0.5
1.4
0.2
0.0
35 - 100 Blank
Total
10.5
G.P. A.
STATION
G.P. A.
�t
[
I
!''
! '•'
I.
UC
�174
H-34/HIDAL GROUND FLOW & FLIGHT DATA
DATE CALIBRATED;
7 July 1963
LIQUID SPRAYED.
Purple
NOZZLE TYPE:
DATE TEST FLOWN;
12 July 1963
TOTAL NOZZLES OPEN:
8015
60
LIQUID TEMP:
36° C
DURATION OF SPRAY-
30
Sec.
PUMP PRESSURE:
40
PS I
70TAL AMOUNT SPRAYED-
34.0
Gal.
FLOW RATE CALIBRATED;
68
CPU
OPERATIONAL DATA DURING FLIGHT
Above information is for Runs 1 - 8 .
DATE CALIBRATED.
7 July 1963
LIQUID SPRAYED.
NOZZLE TYPE
DATE TEST FLOWN;
Purple
12 July 1963
TOTAL NOZZLES OPEN:
Check Valves
60
LIQUID TEMP:
38.5° C
23.5
DURATION OF SPRAY:
30
Sec.
PUMP PRESSURE:
TOTAL AMOUNT SPRAYED;
34.5
Gal.
FLOW RATE CALIBRATED;
OPERATIONAL DATA DURING FLIGHT
Above information is for Runs 9 - 14.
69
PS I
GPM
�175
MASS MEDIAN' DIAMETER
DATE:
12 July 1963
CONVERSION FACTOR:
!T '>:
1
PAPER:
.E LINE:
C
MATERIAL:
RATS:
68
STA.
79
76
76
79
79
79
76
77
80
80
GPM
DROP #
2
6
5
1
3
4
8
7
11
9
SYSTEM:
SIZE
4400*
4300
4200
4100
4000
3900
3800
3700
3600
3500
STA.
88
DROP *
1A
2.2
Kromekote, white
Purple
HIDAL
SIZE
lOO(smallest)
•MD = 70.44+- .1431 (Spot D Max ) = 70.44+0.1431(4400) = 318.2 Micron;
Max. Sph. Dia. = 70.44+0.1431 Max Spot = 70.441-0.1431 ( 4 0 = 700.1
40)
Microns
Min. Sph. Dia. = 63 Microns
�176
MASS DEPOSIT
MATERIAL;
DATE:
FLOW RATE :
Purpi3
SYSTEM:
12 July 1963
HIDAL
FLIGHT >':
AIRSPEED:
SAMPLE LINE:
ALTITUDE:
0403
TIME OF RELEASE:
DURATION:
10
STATION
S TATION G.P.A.
Stations 1 - 7 5 Blank
Hours
GPM
68
AIRCRAFT COURSE:
75
Knots
100
Feet
360
Degrees
Sec.
G.P.A.
STATION
G.P.A.
STATION
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
G.P.A.
1.)
1.0
0.9
0.5
1.0
1.4
1.2
0.8
0.5
0.7
0.4
0.8
0.5
0.7
0.3
0.0
0.3
0.0
Stations 94 - IOC
Blank
Total
12.9
�I
I
L
, - . j.
- t
I _•__]__!_
i
.-Li
i
j
!
1
i
-I— T
-7
J_
.j_.
i
•I . -. i
1
'
LL.1
i
T
;
:
T
!
I
i.
1
t
1
0*1
rn
1
bH
Tyj»
• Li i*
!>••«
•
la•;(.-. ynt
Mi
All
..
. r
A t nx r . f i OMfM
r
inw;«(j,
:
•
'
p,,,.,-,, (I -if Pr«r
'*«•«•
„') D»Kr
Tl»
.
1
j
I
-_ j
.I MO
1400
1KB
•'»
USC
-7.v
~ ,J
'jflO
�178
MASS DEPOSIT
MATERIAL:.
DATE:
Purple
68
FLOW RATE:.
12 July 1963
SYSTEM:
HIDAL
FLIGHT #:
SAMPLE LINE:
ALTITUDE:
75
AIRSPEED:_
TIME OF RELEASE:.
0411
DURATION:
10
Hours
GPM
AIRCRAFT COURSE:
100
360
Knots
Feet
Degree
Sec.
STATION G.P.A.
STATION
Stations 1 - 2 4 Blank
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
G.P.A.
STATION
0.5
1.0
0.8
1.1
1.6
1.5
0.9
0.7
0.8
0.3
0.2
0.3
0.3
0.3
0.1
0.0
Stations 41 - 100 Blank
Total
10.4
G.P.A.
STATION
G.P.A.
�I
!
!
!
r
IX
>JO
i«c
:su
�180
MASS DEPOSIT
MATERIAL:
DATE:
Purple
12 July 1963
FLIGHT #:
SAMPLE LINE:
TIME OF RELEASE:
DURATION:
FLOW RATE:
SYSTEM:
3
HIDAL
AIRSPEED:
D
13
STATION G.P.A.
STATION
Stations 1 - 5 7 Blank
Hours
Knots
75
ALTITUDE:
0430
GPM
68
AIRCRAFT COURSE:
75
Feet
045
Degrees
STATION
G.P.A.
Sec.
G.P.A.
STATION
G.P.A.
58
0.9
59
0.5
60
0.3
61
0.2
62
0.3
63
0.8
64
0.9.
65
0.6
66
1.1
67
0.7
68
1.1
69
1.1
70
1.7 .
71
1.7
72
2.4
73
2.0
74
1.0
75
3.0
76
6.6
Stations 77 - 100 Blank
Total
26.9
�1
1
f
1
r
i. ini* :»(,
•»«*
f
Type A i**
ii
T-..l
Invjixl, 6fl C
m
'"
A • 1 1 : u j*
Almp.ro
ftlrcr*"
C o-ni
-\ Dr^'^r.
T.m* f
.
^ l(f R niri
% KlMH •
.,
t' > .
1 "
'
1
-_.
'UC
1600
,
._-.
180C
I9.A
�182
MASS DEPOSIT
MATER IAL-
Purple
FLOW RATE:
DA It:
12 July 1963
SYSTEM:
68
GPM
HIDAL
FLIGHT .*:
AIRSPEED:
75
Knscs
SAMPLE LINE:
ALTITUDE:
75
F.'t't
0^-5
Degrees
TIME OF RELEASE:
DURA!ION:
.;4i2
ll
STATION
STATION G.P.A.
Stations 1 - 1 0 Blank
10
12
13
14
15
16
17
IS
19
20
21
22
23
24
25
Stations
Hours
AIRCRAFT COURSE:
Sec.
G.P.A.
STATION
0.2
1.4
0.1
0.9
0.5
0.9
1.7
1.4
1.7
1.4
2.1
1.5
0.6
2.1
3.6
26 - 100 Blank
Total
20.1
G.P.A.
STATION
C.P.A.
�I
I
I
Typ* A- f^tcd
H«.«ri«: Sprcjwl
i lot
1200
1100
ua
iioo
iuo
.
•
[mind. *B
Purple, .'r.
�185
MASS MEDIAN DIAMETER
12 July 1963
DATS:
CONVERSION FACTOR:
FLIGHT #:
5
PAP2R:
SAMPLE LINE:
C
MATERIAL:
FLOW RATE:
68
STA.
74
74
73
73
76
74
73
71
74
74
73
74
76
:ttiD
GPM
DROP *
1
2
4
3
6
5
10
9
7
8
11
12
13
Kromekote, white
SYSTEM:
SIZE
6400
6100
6000
5900
5300*
5200
5000
4900
4800
4100
4600
4500
4400
STA.
67
DROP #
1A
2.2
Purple
HIDAL
SIZE
ino(smallest)
= 70.44+0,
,1431 Spot I) Max = 70.44+0.1431(5300) = 378.6 Microns
Max. Sph. Dia. = 70.44+0.1431 Max Spot = 70.44+0.1431(6400)' = 986.3
Microns
Min. Sph. Die,. = 63 Microns
�186
MASS Lt^
MATERIAL:
i'AT.::
Purple
FLOl.' RATE:
12 July 1963
SYSTEM:
CPM
68
•
HIDAL
!• LIGHT •*:
5
AIRSPEED:
55
Knots
SAMPLE LINE:
C
ALTITUDE:
75
Feet
TIME OF RELEASE:
DURATION:
0452
16
STATION G.P.A.
STATION
Stations 1 - 6 6 Blank-
Hours
AIRCRAFT COURSE:
360
Degrees
Sec.
G.P.A.
STATION
67
68
6J
70
71
72
73
74
75
76
77
78
70
80
G.P.A.
-).5
1.0
1.2
1.3
2.7
3.5
2.5
2.7
1.4
1.2
2.7
1.7
2.2
1.1
81
J.J
82
83
..
.8
..)
;•
STATION
Stations G-i - lOi 1 lU.ink
7, Recovery - H 3 9
..
Total
3-.3
G.P.A.
�•1 •
'!
!
'
'
;
'
i
1 ••
-~t
_|_!
!
i-
A |
4/L1JU-;•' v\ i i i i
k. •; • r
i
.:
j
-ir—r.™ — r
:
•
:
•1—A
/
'
\
.1
i
>:o
•.:•
»a
uao
I
I
IMC
{••tK IMI)
—I
1_
1—
IKC
IUO
I7X
IfX
'1JC
J
.XC
�138
MASS DEPOSIT
MATERIAL-
- 'Pur-pie
DArS:
FIOW RATE:
SYSTEM:
12 July 1963
63
CPM
HIDAL
FIIG!1~ #:
6
AIRSPEED:
55
Kr. .->:£•
SAMPLE LINE:
C
ALTITUDE:
T-.
F. . '
.
TIME OF RELEASE:
DURATION:
0452
15
SIAIION C.P.A.
STATION
Sta*. i:/r.3 i - 1J Blank
20
21
22
23
2i
27.
AIRCRAFT COURSE:
Hours
G.P.A.
STATION
G.P.A.
T.i>
i.?
2.S
1.3
3.0
27
28
29
JO
3i
32
33
D.jjircs
Sec.
O.J
0.7
2^
3*0
L.7
1.7
l. c
1.0
u.7
1.0
:<.?
StaMons >i* - 10J Blank
7.- Recovery -112.2
Total
2-5.6
S FAT ..ON 0- .P. A.
�, '.r*. .at.
"T
1
*>•* • !
.•
«l. I. 1
•! • «
.
• .
1'- ..li, -IJ.. •'". ...'
.';_ ;....•:. : i .'.'-. ,
..i...n j. •.; i •: .
"cr__^C.
•~"
/ M.
I
- i
-•t
/
•i
•V
•x
rx
id.
»
?:
<:<
100
noc
i2W
iM
uoo
ISM
im
irx
nx
UK
>:x
�190
MASS DEPOSIT
MATERIAL:
Purple
DATE
12 July 1963
FLIGHT #:
SYSTEM-
7
SAMPLE LINE:
TIME CF RELEASE-
C-.P.A.
68
on.
HIDAL
AIRSPEED:
0310
Kn:'3
"5
Ft PI
AIRCRAFT COURSE;
Hours
75
ALTITUDE:
C
12
DURATION:
STATION
FLOW RATE:
360
Sec.
STATION
G.P.A.
Total
SIAl'IGN
17.9
G.P.A.
STATION
73
72
75
76
DC ::•-•..• .s
G.P.A.
3.5
2.1
1.8
2.5
77
3.3
78
1.*
79
1.0
80
1.3
81
0.5
82
O.i
Sta'i-.r.s 83 • 101
��193
MASS MEDIAN DIAMETER
DATE:
12 July 1963
CONVERSION FACTOR:
FLIGHT «:
8
PAPER:
SAMPLE LINE:
C
MATERIAL;
FLOW RATE:
GPM
68
STA.
28
28
27
27
28
28
28
28
28
28
DROP *
2
1
7
6
3
4
8
5
9
10
MMD = 70.44+0.1431 (Max
SYSTEM:
SIZE
4700
4300*
4200
4100
4000
3900
3700
3600
3400
3300
STA.
29
DROP #
1A
2.2
Kroraefcote, white
Purple
HIDAL
SIZE
100 (smallest)
Spot) = 70.44+0.143114300) = 311.7 Microns
Max. Sph. Dia. = 70.44+0.1431(Max Spot ) = 70.44+0.1431(4700) = 743.0
Microns
Min. Sph. Dia. = 63 Microns
�194
MASS DEPOSIT
M/TSHIAL:
Purple
FLO'..' RAT-i:
DATE:
12 July 1963
SYSTEM:
6:»
iIPM
;!1DAL
FLIGHT --'f.
8
AIRSPEED;
75
Knots
SAMPLE LINE:
C
ALT ITU) (i:
75
Feet
0512
TIME OF RELEASJi:
DURATION:
10
STATION
STATION G.P.A.
Stations 1 - 21 Blank
22
23
24
25
26
27
28
29
30
31
32
Stations
Hours
AIRCRAFT COURSE:
360
Dofirons
Sec.
G.P.A.
STATION
1.5
1.6
2.6
2.7
1.6
2.6
1.9
J.7
0.3
0.5
0.8
33 - 100 Blank
Total
17. t
G.P.A.
STATION G.P.A.
�"T"
.il
8.-,
•• »-
.L.V
• .»
:f
J
I
j"
0-t*
Fllicht #
I / it
i A/
•f
A t r c r . l t CNIM
TIM of ••!•••*
.
r--< ^
-•Si
IX
JOt
IX
:s
;c
tX
;
»
190
KC
I30C
1100
120C
1100
1500
IUO
17DO
IBOt
MO »«II>*B
O i l 1 Imin
�196
MASS DEPOSIT
MATERIAL
DAI!:'
Purple
12 July 1963
FLIGHT //:
SAMPLE LINE:
SYSTEM:
GPM
69
HIDAL
AIRSPEED:
C
0531
10
STATION G.P.A.
STATION
Stat ions 1 - Ti blank
Hours
55
Kn?: -«
ALTITUDE:
9
TIME OF RELEASE:
DURATION:
FLOW RATE:
75
Fof -
AIRCRAFT COURSE:
360
Dear-cs
Sec.
G.P.A.
STAl'ION
G.P.A.
STA'JION
7i
75
76
?7
78
79
80
81
82
83
8i
55
86
87
C-.P.A.
0.0
2.7
J.3
l.S
3.=
3. L
1 .4
;).&
0.3
r\ •
:
^ ^
0.2
0.3
0.2
0.1
Stat i-nsi S3 • 100
Elav.k
Total
19.0
�vr£—zi
\
]
1 Inly I
!
J/-4
;
l
IX
t r-«<
i ••.'.! •
I
>
IOC
7i
iM
i:
i-.x
nx
int
iac
tat
IMO
IMC
<rx
nx
n«
;»o
�198
MASS QEPQSIT
MATERIAL
DATE:
FLOW RATE:
Purple
1? July 1963
FLIGHT *:
SAMPLE LINE:
SYSTEM:
69
HIDAL
10
•AIRSPEED:
55
C
ALTITUDE:
75
TIME OF RELEASE:
0533
DURATION:
13
Hours
CPM
AIRCRAFT COURSE.
'
Kncls
Focr
360
Deere*- s
Sec.
STATION
STATION G.P.A.
Stations 1 - 2 2 Blank
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
G.P.A.
STATION
0.0
0.4
5.9
0.7
1.4
4.2
2.6
1.3
0.7
0.8
0.4
0.2
0.2
0.2
0.0
Stations 38 - 100 Blank
Total
19.0
G.P.A.
STATION
G.P.A.
�1130
IM
1100
"X
IKK
IMC
»X
ICJC
�201
MASS MBCIAS DIAMETER
DATE:
12 July 1J63
FLIGHT •>:
CONVERSION FACTOR:
11
PAPER:
A
SAMPLE LINE:
STA.
30
26
26
26
29
26
26
30
26
30
26
Kromckote, white
MATERIAL:
GPM
69
FLOW RATE:
DROP *
2
1
3
8
4
5
6
10
7
9
11
SYSTEM:
SIZE
7400
7300
6400*
6300
6200
6100
6000
5900
5700
5600
5500
STA.
DROP *
2.2
Purple
HIDAL
SIZE
•
35
1A
103 (smallest)
MMD = 70.44+0.1431 (Spot D Max ) = 70.44+0.1431(6400) = 448.3 Mlcrciv
Max. Jph. Dia. = 70.44+0.1431(Max Spot) = 70.44+0.1431(7400) = 112J.4
Microns
Min. Sph. Dia. = 63 Microns
�202
MASS DiiPOSlT
P'.irplo
DA i1 i :
12 ln'.y 1)63
.JAKi'i..: I-It::::
r
SYSTEM:
AlitSPEHD:
11
I'l.IG'IT =?:
A
nr-t;-: oi R.IL;CASE:
6)
VLQf.l i{AT£:
IT'AT.
75
T>
62'"!
DURATION:
'.A.
STATIO 1 :
STATIC:;
i'taf'OMR '. - 7i. B l a n k
.ours
I'Jgr
AIiiCRAFT COURSE:
Sac.
\P.A.
STATIC:: - ' . r . A .
:-\TIir:
~" .".T
'\P
i n"
7-'.
75
76
7
•*.2
•'•.9
78
7)
81
3.7
3.1
82
83
PA
85
�T"
i". ." J .'
L..J} i? .'• ~s . .'".
-I—
',
1
!
i!
i
i
I
i
i
'
i
I
i
Dae*
_ t
i
-
!
! i !..!..
:
r:ub: t
—
-.:.
! .
ti
!j
!
- —
i
t^f.f MD
Typ* ni'^mt 'r4
•burn. Sf r«»«J
i:[ii*i,
Alr.p.*.A ! r f r « f i c« «'••
. 1 ...
-.
::
.. :
1
is*:
—L_
I
:
lowlwj, i* cm
rurpit. ; . 15 »..
.
'i 7r«l
:\ Knot,
W, ! . , .
>,„
-
-
.
-:"
nx
-.' July iS*l
: i
: A
I7JC
;•"•-
'.rX
-
�204
MASS DEPOSIT
Purple
FLOW RATE :
12 July 1963
DAlE:
AIRSPEED:
TIME OF RELEASE:
STATION
061?
12
G.P.A.
Stations 1 - 2 4 Blank-
I'.ours
75
Knots
ALTITUDE:
SAMPLF. LINE:
DURATION:
GPM
HIDAL
SYSTEM:
12
ELI 'HT >'h
69
75
Feet
AIRCRAFT COURSE:
090
De rces
Sec.
STATION
G.P.A.
25
26
27
28
2?
30
31
32
33
34
35
36
37
38
39
40
41
42
Stations
0.0
1.9
4.2
1.8
2 I
1.8
1 .4
1.3
1.2
1.5
0.8
0.6
0.4
0.3
0.2
0.1
0.3
0.0
43 - 130 Blank
Total
STATION
n.<)
n.P.A.
STATION
(1 P A.
�-—.-. •••' • ' 4 ''/-«. •""-""— ••
>^
JH
•
" i
«, ,
•«
I I •
A
j
isoc
HOC
i;x
i>x
-,
�-:POSIT
>AT:-:&IAI,:
I:*:'
Parplc
FLOtf RAII:
FLI MT •'-'•
SAMPLE LINE:
-.T>1
.1IDAL
AIRSPEED:
D
O645
12
STATION C. P. A.
STATION
Stations 1 - 65 B 1 ank
iiours
55
K.icts
ALTITUD!-:.-
13
TIMi^ OF RELEASE:
DURATION:
SYSTEM-
12 JL.O 1963
6)
75
Fecr
AIRCRAFT COURSE:
0&5
Dogrees
Sec.
G.F..,.
local
STATION
66
67
68
6}
70
71
72
73
74
75
76
' V
Stations
25 I
G.p.A.
STATION
1. 1
L.O
' .8
1.6
i .2
1.7
1.7
4.0
2.6
1.8
6.6
U . i;
77 - 10.1 ill ank
G.P.A.
�r-
I.'Ti
• i
.I •
1
1
. ' 'T
i
--..../ 3
rrr~T
ii • iTr
• „ ;•
. t
. ., .
T,,, A> lnp ,n
—" " ; r
i
».iM»a«
I
-;
;;:. T
i
•;
IX
!
>K
k-
»X
7X
I
£»
<U
-
i,,^,a. ,
. :i r.«t
• I
i _
. I ... !. :
11CC
1IX
1BO
1UC
1700
IX
:m
Jooo
�209
MASS MEDIAN U
12 July 1953
DAT i:
IT '<:
CO.<;c.RdiO\ FACTO.*:
PAPER:
1-j.
,E LINE:
D
MAIaKIAL:
69
RATE :
STA
25
23
23
• 23
22
22
23
23
23
22
Krorvkofe, wliito
GPM
DROP it
1
3
2
4
7
10
5
)
6
3
Pwiplo
SYSTEM:
SIZE
7200
6600*
6500
6400
6300
6200
6100
6000
5300
580U
STA.
DROP *
li>
1A
HT.DAL
SIZE
100 (.-.I-M llcst)
•IMD = 70.4 -',, 0.1431 (Soot i) MJX)= 70. <•''-'. -i-0.14Tl(66:\;) - iiol.j Mi.vcni;
Max. bph. Dia. = 70./i-'i Hi. 143 1 (Max Spot)
, . U U (72u.)) =
M J L l 3R >
Min. Sph. Dia. - 63 Microns
�210
MASS U^I-OS IT
'•'.ATSKIAL:
•.'AT--::
Purple
_
SYST'iM:
12 July 1963
rr.ir.-T -:
'14
Jj.yPLE LIME:
'
DERATION:
AIRSPEKU:
ALTITUDE:
D
fi:!E OF RELEASE:
STATION
H O . RA'iii:
..'
0647
14
G.P.A.
Hours
AIRCRAFT COIUISE:
69
uPM
i!ICAL
55
75
045
Knots
Feet
Degrees
Sec.
STATION
G.P.A.
STATION'
Stations 1 - 1 4 Blank
0.6
15
16
0.7
2.2
17
0.9
18
19
0.5 .
20
0.0
21
1.5
22
3.1
2.3
?3
.4
'
1.1
25
1.9
6.4
26
St. it ions 27 - 100 SUnk
Total 22.1
G.F.A.
SVATIO;: O.P.A.
�"T
f
: c-
"
I
I
Inwlnd. «>« f.m
Purpii. • . i .'«•
l
iv<
IV
•
^
ii
7S
;ooe
?C
IS
�213
H-34/KIDAL GROUND FLOW AND FLIGHT DA1A
DATE CALIBRATED:
7 July 1963
Purple
LIQUID SPRAYED:
NOZZLE TYPE:
DATE TEST FLOWN:
1? July 19t>3
TOTAL NOZZLES OPEN:
LIQUID TEMP:
Check Valves
60
38 .5° C
DURATION OF SPRAY:
30
Sec.
PUMP PRESS IT.E.
23. 5
PSI
TOTAL AMOUNT SPRAYED.
34.5
Gal.
FLOW RATE CALIBRATED:
69
GPM
OPERATIONAL DATA DURING FLIGHT
Above information is for Runs 1 - 18.
�214
Purple
Yl.di.-i RAT:'.:
13 July 1363
oFM
ilCAL
>'.TC"T #•
A1RSPEED:_
SAMPi !i L I N E : D _
Kiu-ts
ALTITUDE:
TIME 01- REUASE;
0351
.iours
AlRCrfAFT COURS2:
73
F.-I-:
-.7.5
prgryi
DERATION:
STATION
STATION C.P.A.
Stations 1 - 7 5 Blank
G.P.A.
STATION
G.P.A.
STATIC-: (.:. P.,A.
7 ft ~ i . J'
�;r
T"
' 3 JUL , .
A, X /'-
HI
: t- 9**
•>%.* •«, MM
7-3--
j
'•i.
\
. r 1 . '« C
!
1"
0«C*>
r:i«t>
A l t l L dl
Alr.p
A i r c r f t Cowr>«
TIM
(Ml Iw|IM«
01)1 ffcwr.
f JUI«M«
\ ./
V
;.;
«s
s:
«oc
ix
?i
IOQC
uu
121
IUO
140B
1MO
1600
I70C
'8»
!90G
�217
MASS MEDIAN DIAMETER
DATE::
13
July 1-J63
CONVERSION FACTOR:
FLIGHT #:
2
PAPER:
SAMPLE LINE :
D
MATERIAL:
Purple
SYSTEM:
2.2
11IDAL
FLOW RATE:
69
STA.
29
26
26
29
29
30
30
26
30
29
26
CPM
DROP #
1
2
3
7
6
8
9
4
10
5
11
SIZE
8500
7200
6500
6100*
6000
5900
5800
5700
5600
5500
5400
STA.
36
Kroi-iekote, white
DROP #
1A
S12E
100 (smallest)
HMD = 70. 4* -i
r;).1431Spot D Max = 70.44+0.1431(6100) = 428.8 Microns
Max. Sph. Dia. = 70.44.0.1431(MJX Spot) = 70.44 K,. 1431(8500) = 12F6.8
Micronu
Min. Sph. Dia. = 63 Microns
�218
MASS DEPOSIT
Purple
MATiiRIfc: :
FLOW RATE:
SVST2M:
13 July 1363
DATE:
FUCl.T "L =
2
SANf'-E LINE :
6J
GPM
HIDAL
AIRSPEr.1):
I 'Mi OF RELEASE:
0353
Hours
Knor
AUITUD,::
D
75
75
tVot
AIRCRAFT COURSE:
C-'.i
Degrees
DURATION:
b TAT I ON
P.
G. A.
Stations 1 - 25 Blank
STATION
G.P.A.
1.7
4.0
1.1
1.6
2.3
2.3
0.3
0.7
0.5
0.5
36
0.6
37
0.5
38
0.0
Stations 3-J - lOu BlanU
STATION
26
27
28
2i
30
31
32
33
34
35
Total 16.1
G.P.A.
STATION
G.P.A.
�i
i
A8-
1—f
i
i
ix
AY<-
ix
tx
i
i
i
•
I
|
;
i
ii
>.
A t r r r c f i Court*
Tlat of ••!«••*
!t
ij.
*:..
HOC
12SO
IJOC
UK
1500
1UO
:
17X
HX
*•* D*(i«»»
OJil Bawn
IttC
2300
�220
MASS DEPOSIT
MATERIAL:
FLOW RATE.
Purple
DAii:
SYSTEM:
13 July 1-J63
6'J
GPM
IIIDAL
FLIGHT #:
3
AIRSPEED:
75
Knots
SAMPLE LINE:
A
ALTITUDE:
50
Feat
rTMi£ OF RELEASE:
0414
DURATION:
12
STATION G.P.A.
STATION
Stations 1 - 7 0 Blank
Hours
AIRCRAFT COURSE:
O'JC
Degrees
STATION
G.P.A.
Sec.
C-.P.A.
STATION
71
72
73
74
75
•
76
77
78
7J
80
?1
F,2
G.P.A.
G.4
3.5
4.7
0.0
1.2
3.3
3.0
2.9
0.7
0.3
0.4
C.I
Stat ions 83 - 100 Blank
Total
2'i.5
�;r
-i
l'
1 I
r
20_<< ,J&.i^ 97..
T " "
i'.^iCjJJp f i 3J
1 C—
"
.
/ fi -7
^ *
i
i .
!
11 J>> H'J
1
rn,h
-»'•«
•l iprtyw
Invfo4. 4V flm
Piirtli. 0. :l »•
T} KMII
OVO »*|TB»*
t
i
1
.
100
HOC
ngo
I2H
*
'
INC
S-.fl. IUMI
I
i
( M f a*
M . e t.
•
�223
MASS MEDIA:. DIAMETER
DAT.-; :
13 July 1J63
CONVERSION FACTOR:
FLIGHT #:
-'i
PAPER:
SAMPLE LIN£:
*
t\
MATERIAL:
Purple
SYSTEM:
2.2
HIDAL
FLOW RATE:
69
STA.
27
27
27
27
27
27
27
27
27
27
27
GPM
DROP #
4
1
4.
y
3
11
6
10
5
8
7
SIZE
7600
7000
5800*
6700
6600
6400
6300
6200
6100
6GOO
5JOO
STA.
DROP #
8
1A
Kromckote, white
SIZE
lOO(traallest)
MMD = 70.4-' : ) I .'.31(Soot D Max) = J',-.'.i iO. 1431(6800) - -'(74.3 Microns
M.IX. Sph. J i c . = 70.^'. j.!431(M.ix Spot ) = 71..1.44+0.1/:31 (7600) = 1158.0
Microns
M i n . Sph. D i a , = 63 Microns
�224
KASS
i'i J.vJAi,:
Putpla_
n.O.; RATii:_
13 Jiuy I J b J
S YbViiM:
iilDAL
AIRSPEED:
i1 AMPLE LINE:
A
ALTITUDE:
TTM::. oir RELEASE?
~.4it>
L- RATION:
11
NATION' G.P.A_.
STATION'
.j'.alions 1 - 1 3 Blank
1:
13
16
17
18
lj
20
/I
22
*i'j
25
"6
aL ions
:iours
AIRCRAFT COURSE:
Sec.
G.P.A.
0.0
i;.3
O.A
1
i) . 6
0.7
1.0
v" . 7
1.3
3.3
2.2
1.7
v''.8
';. .
:;"
7S
3Lani.
ToLal
STATION
(i.f.A.
^JAJL'JL'L ^jL-i>..-.
�we
^o
to.
;x
100
we
IOM
HOC
ing
itto
ITDO
iix
;«M
oat
�226
MASS DbPOSIT
MATERIAL :
DAI£:
Purple
FLOW RATE:
13 July 1363
SYSTEM:
FLIGHT # :
5
AIRSPEED:
SAMPLE LINE:
D
HIDAL
ALTITUDE:
TIME OF RELEASE:
DURATION :
0439
13
STATION
STATION G.P.A.
Stations 1 - 6 3 Blank
Hours
GPM
6)
55
AIRCRAFT COURSE:
Knots
50
Feet
045
DeRrees
STATION
G.P.A.
Sec.
G.P.A.
STATION
64
65
66
67
68
69
70
71
72
73
74
75
76
77
G.P.A.
0.0
0.0
0.0
0.0
0.1
0.5
0.9
1,5
2.6
2.3
1.7
0.3
4.1
4.5
Stations 78 - 100 Blank
Total
18.9
�- —T — -
i
j
- f ' - —.
1 3 J'Jl
":>
-T
|
i
1
R H
I
«Vr
•
' —*
• . 01
. .
,.
' tf
f i
,
NM
i
1
i
;
!
:
"S ..."• * ,JC.£ . '-I1!
;..
.if .si i. ,;^ 4 . ••; .
I
I
1
4-—
SMP'I* UD*
Typ* AitMpiv
1
Aircraft OM
TlM <.* »•!•
-L
ix
ix
IK
Si:
•- 1
>M
IX
IIDO
1290
1100
1400
ISM
1600
1730
: 11 July IVkt
. J
: n
:
:
:
:
Inwlad, M CTH
PHrplr, 0. It ^y»
V. PMI
iS Kaon
. 0*1 DM"**
:
{**!•» Bnuri
IIOC
ItjO
OH
�229
JIAM£T.-:R
U July I,'j3
__
CO:J VERSION FACTOR:
FLIGHT ;>:
6
TAPER:
SAMPL2 L1N£:
D
MATERIAL:
FL(W KATE:
GPM
6J
STA.
23
c-4
2J
23
23
22
22
23
25
2/,
25
DROP V
1
6
3
2
4
j
10
5
8
7
11
SI.iE
S800
7600
7000*
68GJ
C600
65 jO
6400
6300
62CO
61JO
60JO
Krorai'kct,', white
oYSTEM:
STA.'
14
DROP #
1A
Purple
II1DAL
SIZE
1J.. (smallest)
:-»ro - 7 ..;<, ;-L .U31(Spot
D Max; -- 7..i.4A!t;.l'i31(7jJj) = 487.3 Microns
2.2
Con. Factor
Max. Jpli. Dia. = 7C. :,.',:.. 1431 (Max Spot) - 7J.-',' . ,i. 1/.31 (881)0) = 132'J.7
Microns
:iin. S;.h. l)ia. = 63 Microns
�230
MASS DEPOSIT
MATERIAL:
DAVE:
FLOW RA'i'ti:
Purple
13 July 1963
lilDA!.
55
6
AIRSPEED:
SAMPLE LINE:
D
ALTITUDE:
0441
DURATION:
16
liours
AIRCRAFT COURSE:
K.-.ots
50
. for*.
045
Dcgvoes
Sec.
STATION G.P.A.
STATION' G.P.A.
Stations 1 - 1 5 Blank
16
17
18
l-j
20
21
»K
SYSIEM:
FLIGHT #:
TIME OF RELEASE:
t- >
STATION
0.0
0.2
y.2
0.7
2.1
2.7
1 *•)
2.)
23
2.7
24
0.7
1.0
26
7.8
27
1.2
^cations
Total
22.2
C.P.A.
STATION
C'- . P .A .
�I
i~r
i
i
1
•
i
rt
:' 1
.. *
1
.
t
j
1
i
;
!jj*
1
i
~*" " "! "T
1
IKG
IUC
1*X
IUC
IUC
1700
U5C
'«
?MO
�232
MASS DEPOSIT
MATERIAL:,
DA It:
Purple
69
FLOW RATE:
SYSTEM:
13 July 1-J63
GPM
HIDAL
FLIGHT #:
AIRSPEED:
55
Knots
SAMPLE LINE:
ALTITUDE:
75
Feet
TIME OF RELEASE:
0500.
DURATION:
12
STATION G.P.A.
STATION
Stations 1 - 1 2 Blank
13
14
15
16
17
18
19
20
21
22
2J
24
25
26
AIRCRAFT COURSE :
Hours
045
Degrees
Sec.
G.P.A
STATION
0.5
0.3
0.7
1.0
1.5
1.3
1.9
2.3
3.5
2.3
2.2
2.6
5.3
0.0
Stations 27 - 100 Blank
Total
25.4
G.P.A.
STATION
G.P.A.
�!
I
'.M1'-'-*-—^-"-'l:.: .•:,.
»•
'I"i
i
•)•! B. I
•.. 6...
•.
i.
.
-"i .'/- u ..i • , . • : „ .
*j- -..•'" *•. '*• - . '• i
-•; -.: '. ;• 4
;<s>
••<•". /.- £ 7 . . .
T
I
Mi
1
lovlnd, oy O
Pur^:*. 0. It I>
7i F«v
.' [ •
/
f
A i r c r a f t Courir
TIM of *•!••••
...
/
,'V!
!
^
n
i.c
I
j:.
i:t
IJX
S.<4 I'Mi
1100
1200
1100
UK
I10C
l«00
"OC
HU
.T
�234
MASS DEPOSIT
Purple
MATERIAL:
DATE:
FLOW RATE:
13 July 1963
6}
SYSTEM:
GPH
H1DAL
FLIGHT #:
8
AIRSPEED:
55
Knots
SAMPLE LINE:
D
ALTITUDE:
75
Feet
TIME OF RELEASE :
DURATION:
0502
15
STATION
STATION G.P.A.
Stations 1 - 6 3 Blank
Hours
AIRCRAFT COURSE:
045
Degrees
Sec.
G.P.A.
STATION
64
65
66
67
68
69
70
71
72
73
74
75
76
G.P.A.
STATION
0.1
1.
.0
0.9
0.2
0.5
1.2
1.6
2.9
2.7
1.0
2.2
5.L
2.1
Stations 77 - ICO Blank
Total
22.1
G.P.A.
�r
' j. '4
,?;...iP« .". ?„ <:
i"
Dttr
Fllghl
i
i
'
;
I -.
\
i
:
_<_
i
Tlar ol tmlmmm*
:
0»02 Inri
l\
•' I
. . V Ii'
V
I
r
iioc
i no
iioc
1430
is«
r*x
1790
wt.
i>x
�236
S DEPOSIT
FLO*1 RAW;
13 July 1J63
3YST£Hs
GPM
6_2..
HIDAL
AIKSPEED:.
V1ME OF R£LEAS£;
'J520
Hours
DURATION:
13
Knots
ALTITUDE:
SAMPLE LINE:
75
75
Feet
Sec.
•2TATION
G.P.A.
STATION
AIRCRAFT COURSE:
G.P.A.
STATION
G.P.A.
360
Degrees
Total
i.l
STATION
G.P.A.
75
76
77
78
7-3
80
81
82
83
84
85
86
87
88
Stations
;i tat ions 1 - 7 4 Blank
3.0
0.2
1.5
2.7
1.1
0.6
0.2
0.1
0.0
O.I
0.1
O.I
0.0
0.0
8;J - 100
Blank
�"~T
• - ft. »
•.• B. I
"^ "—
..I
11 July 1961
*
C
160 b
I.
s:c
"o;
.t
'-.a
DOC
1200
t*CC
IMC
IIOC
1700
180C
!90C
7900
�238
MASS DEPOSIT
Purple
MATERIAL:
1 i July 1963
DATE:
SYSTEM:
10
FLIGHT #:
SAMPLE LINE:
c
69
ALTITUDE:
0522
DURATION:
15
G.P.A.
jtations 1 - 2 3 Blank
Hours
GPM
H1DAL
AIRSPEED:
TIME OF RELEASE :
STATION
FLOW RATS:
AIRCRAFT COURSE:
75
75
360
Knots
Feet
Degrees
Sec.
STATION
G.P.A.
24
25
26
27
28
29
30
31
32
33
34
35
36
Stations
".8
0.1
3.1
2.2
0.9
0.4
0.2
0.3
0.0
0.0"
0.0
0.0
37 - 100 Blank
«».G
STATION
Total 16.0
G.P.A.
STATION
G.P.A.
�^
i' */>.
l. '
-4
..
'.- *. . " :
£ t . 'ij
.
f ; .T . .
i . ')'. .
/ - •Jl.
» It
i
L,
IX
__u.
I
t
12X
_l
DOC
I
UX
ISOC
T«K
_J
�241
MEDIAN DIAMETER
UA'It:
CONVERSION FACTOR:
13 July 1,-6'j
IT -/:
11
PAPER:
MATERIAL:
C
,E LIN E:
6;
RATE:
STA.
74
74
72
72
74
74
74
73
74
74
DROP =»
1
2
7
6
4
3
5
8
J
lo
GPM
SIZE
71-JO
6400*
6300
6200
6100
5300
5800
5700
5600
5500
SYSTEM:
STA.
74
DROP 4
1A
2.2
Kromokote, whit a
Purple
Ilic.al
SIZE
100(;-.malK:S!.;
1MD = 7 : ' ' i -.J.143U Spot L) Ma:;) --- 70.^4-, J. 1451 (6401.;) f- 44P.3 Mic
...'
-.v
M.-IX. sph. Oia. = 70 .•'-'..-.;. U': 31 (Max Spot) = 70.^4-;-;;. b'.3 1 (71-•)) •= 1086.5
Micron:;
Kin. 5ph. Jia. = 48 Micronu
�242
MASS D£PCS1T
MATERIAL:
DAi^:
FLIGHT #
SAMPLE LINK:
Purple
FLOW RATE:
SYSTEM:
13 July 1963
11
ALI1TUDE:
T1MK oF Rl- LEASE:
0552
DURATION:
15
Si'AllON G.P.A.
S1AT10N
jt at ions 1 - 6 5 Blank
Hours
CPM
U1DAL
AIRSPEED:
C
t)
AIRCRAFT COl':>Sh:
75
Kr.:ts
75
Fee:
160
Dc>pj.»es
SI AT ION
G.F.A.
Sec.
G.P.A.
STATION
G.P.A.
66
67
68
6'J
70
71
72
73
0.4
0.2
1.2
0.6
1.8
2.4
2.4
1.8
74
0.5
75
76
77
73
0.3
3.7
4.1
2.0
&•.; ...5
1
81
C. :
SCdl.rns 82 - 100 21anU
Tocal
23.8
�i
i
i
i
i; • / >
!
i
i
i
;
.
•
a
i
i
;
i
i
i
ii
I_
i
1
i
i
i
:
:
;
i
11
i
»
L«:»
.
#
&MT ' 1:0T>r* « •iMpicd
Njiari A! S|iray»*l
A : 1 1 .;•
u
Atu * .'.
p
Al rr , • II LMr.»
Tlw
1 I July
il
.
:
:
:
.
i
i
——
1
:x
S. I-
'«•!
HOC
IK:
i .i
HOC
.
u*
•
c
lnvla-1. i- ..m
Pif,.'*. . il :m
') Fr«!
J) but*
W. >«•».
• -
;
1
. i:
1
!
i
�244
MASS DEPOSIT
MATERIAL:
-J&IZ:
SYSTEM:
-^Julv 1963
FLIGHT #:
SAMPLE LINE:
12
C
6*
ALTITUDE:
Hours
i'555
GPM
hIDAL
AIRSPEED:
TIME OF RELEASE:
DURATION:
FLOW RATE:
Purple
AIRCRAFT COURSE:
75
75
Knots
Feet
360
Degrees
STATION
G.F.A.
Sec.
11
STATION G.P.A.
STATION
21
Stations 1 - 2 0 Blank
22
23
24
25
26
27
28
23
30
31
32
33
34
35
36
G.P.A.
STATION
o.l
0.8
2.3
3.7
1.6
6.5
5.3
1.3
0.5
0.4
0.7
0.9
0.5
C.5
G.P.A.
•
C.4
0.0
iitation: 1 . 37 - li-0 B l a n k
Total
25.5
�r1
-(--
/!
i n
i ;
'i
i
T.M of I»1«M«
4i
!
i ;\:/
r~ V
/[
. t ,.
!
i ^
>:;
no:
;-a<» -I'M*!
MOO
i2»
isoc
uoo
\m
nx
�247
MASS MEDIAN DIAMETER
DATE:
13 July 1.J63
CONVERSION FACTOR:
PAPEjft;
13
FLIGHT rf:
SAMPLE LINE:
D
MATERIAL:
6,
FLO'..' KATE:
STA.
77
75
77
77
77
75
78
77
78
77
78
LAO? *
1
4
2
5
•
8
)
7
11
3
6
10
GPM
SI2B
8400
6200*
6100
5-JOO
5800
5700
5500 5400
5300
5200
5000
SYSTEM:
-~A.
J4
DROP #
1A
2.2
Krorr.cUte, white
Purple
HIDAL
SIZE
10U (smallest)
MMD = 7v).A4 •«-u 1431 (Spot D Max) = 70.4i-;-i.l431(62;ju) = 435.3 M i c r o
:.2
Con. Factor
Mo;. Sph. Dia. = 70.A-'.-;-'). 1431 (Max Spot) =- 70./.-'i+0.1431 ( 4 0 = 1202..'
80)
Micr.::'".
Min. Sp'.i. Dia. - 63 Microns
�248
MAsS DEPOSIT
MATERIAL'J^I'c..
p^r»ii13 Jjly 1,63
Fl!G"T #.
SAMPLE LIN£:
SYSTEM:
13
AIRSPEED:
D
ALTITUDE:
nMC OF RELEASE :
DURATION:
FLOh1 RATii:
o)5
13
STATION G.P.A.
STATION
SLdLior.s 1 - 7; KlanK
Hours
AIRCRAFT COURSE:
('FM
6>>
I'.IDAL
51!
Kiv ,- :
75
r .-'.
0^-5
n.-,::,. '.
Sec.
G.P.A.
STATION
G.P.A.
STATION
7i
75
76
77
78
79
80
81
82
83
84
85
86
C.P.A.
4. )
1.8
1.0
2.:
^ .«'
l.«
1..
o. •
0.
0.5
(; . ."i
0. ^
0.2
Staticn:; 87 - :
Biar
Total
:;..'.)
�'•- .Hi . « . , ' . '•••'
, .
'- .••» 1 -- ; . "; ,.
'I'. .'IS.;' 5 . I : _ • . _ .
<ioo
:m
loot
�250
MASS DEPOSIT
MATERIAL:
DAT;; :
Purple
13 July 1J63
FLIG'.T 4:
SAMPLE LINE:
TIME OF RELEASE:
DURATION:
FLOW RATE:
SYSTEM:
69
GPM
HIDAL
14
AIRSPEED:
55
Knots
D
ALTITUDE:
75
Feet
0617
Hours
13
AIRCRAFT COURSE:
045
Degrees
Sec.
STATION
STATION G.P
23
Stations 1 - 22 Blank
24
25
26
27
28
29
30
31
32
33
34
35
G.P. A.
STATION
1.5
4.0
2.3
0.7
2.2
4.2
l.J
0.5
0.4
0.3
0.9
0.4
0.2
Stations 36 - IOC Blank
Total
1J.5
G.P. A.
STATION
G.P. A.
�1:1.1.
Aircraft GMTO*
•
20C
KB
' • ' ' ' ' • •
0*) D^|(M.
0*17 k*fc
�252
MASS DEPOSIT
Purple
MATERIAL:
DATE:
13 July H63
[•LTG:IT *:
SAMPLE LINE:
SYSTEM:
GPM
HIDAL
15
AIRSPEED:
75
Knots
1)
ALTITUDE:
75
FCet
AIRCRAFT COURSE:
045
TIME OF RELEASE :
DERATION:
69
FLOW RATE:
''3
.^3
IS
STATION O.P.A.
STATION
Stations 1 - 6 6 Blank
ttours
Degro.v.
Sec.
G.P.A.
STATION
67
68
6J
70
71
72
73
7i
75
76
77
78
G.P.A.
STATION
0.0
11.8
2.0
0.6
1.4
3.2
1.3
0.5
0.4
0.1
0.2
J.I
Stations 1) - 10.) Blank
Total
21.6
G.P.A.
�I
f
• :i j-ij 1^61
. iv
: -I
I
-L/
-.;^r
r.:
M
MX
1200
1100
1400
IW
IOC
I73C
•
'
'
•
)IX
'
<?ji.
•
.-JO
—1
�254
MASS DEPOSIT
Purple
MATERIAL:
DATE:
13 July 1963
FLIGilT #:
SAMPLE LINE:
SYSTEM:
IS
D
ALTITUDE:
6-J
0635
17
Hours
AIRCRAFT COURSE:
GPM
HIDAL
AIRSPEED:
TIMS Or RELEASE :
DURATION:
FLOW RATE:
75
75
Knots
Feot
045
Degrees
STATION
G.P.A.
Sec.
STATION
STATION G.P.A.
24
Stations 1 - 2 3 Blank
25
26
27
28
29
30
31
32
33
34
35
G.P.A.
STATION
0.0
4.5
2.7
1.3
'.
06
4.0
1.5
0.6
0.2
0.2
0.1
0.1
Stations 36 - 100 Blank
Total
15.8
G.P.A.
��257
MASS MEDIAN DIAMETER
13 July 1J63
FLIGHT #:
CONVERSION FACTOR:
PAPER:
17
SAMPLE L1N2 .
FLOW RATE:
A
6j
STA.
28
25
25
25
25
25
25
25
25
27
28
DROP #
1
4
3
5
2
6
8
7
•)
11
10
MATERIAL:
JPM
SIZE
7500
6700*
6600
6500
6400
6300
6200
6100
6000
5JOO
5800
SYSTEM:
STA.
45
DROP #
1A
2.2
Kromekoto, whit?
Purple
KIDAL
SIZE
lOO(smallest)
HMD = 70.4-i-i;; .U3i(Spot D Max) = 70. 44 i^. 143 1(6700) = 467.8 Miciv.v
Max. ..ph. Dia. = 70.44-.-r;. 1431 (Max Spot) = 70.44+0.1431(7500) = 1143.7
Microns
Min. 3ph. Dia. = 63 Microns
�258
MASS DEPOSIT
MATERIAL:
Purple
1-L3W RAI.£:
DATE:
13 July 1J63
SYSTEM-
FLIGHT #:
SAMPLE LINa:
17
ALTITUJE:
TIME OF RELEASE:
DURATION:
0652
14
.lours
(.PK
HJUAL
AIRSPEED:
A
t-J
75
100
AIRCRAFT COURSE:
K-.-^t ;
tV-".
.0
»
Ucar..-c3
S. c .
STATION"
STATION G.P.A.
24
Stations 1 - 2 3 Blank
G.P.A.
0.0
25
26
27
28
29
30
31
32
33
34
35
3&
37
38
39
0.2
3.7
1.5
1.2
40
•J..1
1.4
0.7
2.1
0.3
;).3
0.4
0.3
0.2
0.4
;/.2
0.1
STATION
G.P.A.
STATION
G.P.A.
�f "c •• 1
•.._..
"J I I t 'J JUL.L:- .
. < t • ..,
:v ::,':-.I •:—!±'.*-.':-.
I
!
"•'-•V . /.: S 7
••-i«i
I
I
:
1 3 July IV.!
: A
: Lnwlni. t'l C.l
. rurp!*, O.It
.
t
;.<
:x
06)? •»(•
i
•
!
EL
I) Knoti
:
i
liW F'*'
•
!
140C
IIM
1>JC
I'X
HOC
»X
K«0
�260
MASS DEPOSIT
MATERIAL:
Purple
FLOW RATE:
DATE:
U July 1363
SYSTEM:
FLIGHT #:
SAMPLE LINE:
GPK
69
HIDAL
18
AIRSPEED:
75
Kr.cti
A
ALTITUDE:
100
Foct
0654
Hour
DURATION:
18
DeRts.es
STATION
G.P.A.
0.0
0.1
1.5
.5.3
0.2
0 . '•<
1.3
1.5
1.0
1 .9
0.2
0.2
O.I
0.1
Sec.
STATION G.P.A.
STATION
Stations 1 - 7 1 Blank
AIRCRAFT COURSE;
090
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
Station
TIME OF RELEASE:
G.P.A.
STATION
•
Total
13.9
G.P.A.
0.1
87 - 10M
Blank
�— -'-'- • -
r
- ,-S.S .23 1 ± 2li. 4. _ ..
'.is :.jj.&_Ji-
-j;*..'.' s.^.i'i >
.'51." fo; 12 : ..
'•*.
.!i.t lit 4 i I ] j
..../-© 7 . _ .
Lliw
iiMpi«
l Spra
InvlBd, *t CPU
FwrpU. 0. il ayi
I'* Pr.t
-M4-
V..
I
•x
I ZOO
__l—
I
1«8
•
I73C
'
1100
�26.
H-34/H1DAL CROlTCD FLOW & FLIGHT DATA
DATE CALIBRATED:
16 July 1963
LIQUID SPRAYED:
NOZZLE TYPE:
DATE TEST FLOWN.
16 July 1963
TOTAL NOZZLES OPEN:
8015
60
LIQUID TEMP-
Purple
37° C
DURATION OF SPRAY:
30
Sec.
PUMP PRESSURE.
32
PS I
TOTAL AMOUNT SPRAYED:
28
Gal.
HX)W RATE CALIBRATED:
56
GPM
OPERATIONAL DATA DURING FLIGHT
Above inform.iti.or. is for Runs 1 - 16.
REMARKS'
The pressure readings are from the pressure gauge mounted on the pump
which was subsequently proven to be inaccurate.
�'2 b 3
i'j\SS MEDIAN 1)1AME1'£R
DATE :
s
J j 1 > I if:*
.'
tu
CONVERSION 1* ACTOR:
;-': ICi)T ff .
1
PAPE3:
SAMPLE LINE :
B
M/M'ERIAl.'
5o
V-JOf.! RATE:
STA.
?t>
76
76
73
I'l
77
73
73
77
76
I'VD
,
CPM
DROP ••'
1
2
3
4
£
7
5
6
9
10
SYSTEM:
SIZE
STA.
DROP #
b'fOO*
6200
6100
6000
5:JOO
5 EGO
5o>)()
3500
5400
530u
100
1A
2.2
Kvo"i>'l'-ote, wliito
Purpli".
III DAL
SIZE
100(sinall«st)
ti-O.U. 31 (Spot D M«xJ = 70.44+O.R31(b-'tOO) - ^,46.3 Micrm-.
M..x. Spn. D i a . = 7 0 . 4 4 i 0 . 1 » j l ( M a x Spot) =? 70..;..-'.-:-0. 1431 (6/.00) = 966.3
; ' D . Spli. Oia. - fa3 Microns
�264
Mi'SS DEPCS'.'
KATFRIAL:
DATE:
FLOW R.A;
P -.;
.c .'u1. / 19b3
SYSTEM:
FMC--T # : _
AIRSPEED".
SAMPLE LINE
ALTITUDE:
TIKE OF Si.I EASE •
02.10
Ft*
AIRCRAFT COURSE
DURATION.
STA'TION_ G.P.A.
j rATTT^
G.P.A.
STATION
Stations 1 - 6 9 Biar.k
o.P.A.
S^T-.CV C - . f . f .
"•0 "o'.o""
71
0.2
1>
1.*j __ ;
-" • *
-li.
- ^
'*.
77
a
o.-.
0. i. '
0..=-
3&
(j.*
S3
o!'"
0.:
0..'
.•5 .
•>',
10.
�!
I
1
i
;
i
1
s.
• >
!
!• '• I
•
i
1
i
i
1
.
'
•
'
!
'
i
'
• t
!
'
Nl
Jb.
i
i
'
...
i
1
IX
i
i
1
i
•
f
i
li
i
«.<
>;OC
HOC
IJOC
I1JC
UK
1SOC
lUC
\7X
HOC
�266
MASS
MATERIAL:
DA IE..
Purpl.
Fl "W R^l'E-
ifi Jjlv :963
SYSTEM.
FLIGHT #:
2
.,:*SFEE3:
SAMPLE LINE:
B
H'Df-
/J.inUDE.
TIME OF RELEASE:
0-12
DURATION:
>• • , H
STATION G.P.A.
STATIC^
21
Stations 1 - 20 Biark
22
23
24
25
26
27
28
29
30
• 31
32
Hours
G.P.«.
A:RCR,i.Fr COURSE:
STATICN
0.4
1.5
1.8
1.4
0.8
0.6
1.7
1.7
i.l
0.8
O.f
0.1
S"-at iorsi 3? - ICO EU'k
'7, Rocovory -
C.P.A.
313
�n..i-j./-* .
•s. .-«}.;;.'.
'V- 7-Zi
^s
O.E ..i
t eo
I
-
I
1
t
1
'
1
•
I
1
1
,
'
,
|
i
i
i
i
'
(
r
.
t
I
t
I
i
i
j
4
—
•
i
;
•
i
i
=.:
".
::
t
I
n>;
•;«
1
!
ux
I-
Ijlv
.-.
•j j r-..- 1
H
4
i
t
J
--
1
.
A
; Rvlvltr
t
•
lf>
B
-.„'. »
-
!
:
V .'•
i
i.l.r
1 K1
hl^r
1
•
N
i
X
1
::
I
•
|
, ,1
i
X
.
i
1
;;
:-..}. .
MX
•
J
�268
MASS DEPOSIT
MATERIAL;
DATE:
Purple
FLOW RATU.
16 July 1963
SYSTEM.-
C-PK
if>
HI DA I.
FLIGHT #.
3
AIRSPEED..
SAMPLE LINE:
C
ALTITUDE:
K.
7^
7?
TIME OF RELEASE:
DURATION:
0434
11
STATION G.P.A.
STATION
Stations 1 - 7 2 Blank
Hears
AIRCRAFT COURSE.
1••r-. *
360
Dc-
r
cr s
Sec.
G.P.A.
STATION
G.P.A.
STflTICN
73
7/4
75
G.P .*.
..
i.2
1.3
'-.i
76
C.
* • .
77
0.3
I.-'2.1
0.0.2
T-,
79
80
81
82
0!
.*
Star Lcr. * 83 -
,00
Bl«ir.k
Total
10.9
�:i-i/\
-;—4.
1
i
i
t
!
;
i
!
'
i
i
1
i
!
1
I
i
i
i
;
.
i
|
i
:
:
.
|
.
:
i
1
(
:
\
:
•
i
i
:
;
!
.
:
.
j
!
.
!
:
:
.
i
i
i
i
•
i
i
i
1
:
t - i
.• k
, \
.
,
\
'
'
:
i
'.
1
\
i
I
1
1
•
,
i
!
1
\
•
•
.
,
i
t
i
:
•
1
•
•
^^y •:.•• ]
•-_._.
'•.i:
HOC
Don
ux
isc;
is.
I'X
;
'SJC
-y. J
�271
MASS MEDIAN DIAMETER
DATE:
16 July 1963
CONVERSION FACTOR:
FLIGHT #:
4
PAPER:
SAMPLE LINE :
C
MATERIAL.
Purple
SYSTEM:
1.2
HIDAL
56
FLOW RATE:
STA.
24
24
24
24
27
24
27
27
23
24
GPM
DROP #
1
4
2
3
6
5
7
8
10
9
SIZE
4300*
4200
4100
4000
3900
3800
3700
3600
3500
3400
STA.
50
DROP *
1A
Kromekote, whit*
SIZE
lOO(smallest)
MMD = 70.44-t0.1431(Spot D Max) = 70.44+0.1431(4300) = 311.7 Micros
Max. Sph. Dia. = 70.44+0.1431(Max Spot) = 70.44+0.1431(4300) = 68'>.8
Micr >ns
Min. Sph. Dia. = 63 Microns
�272
MASS DEPOSIT
P-..rple
MATERIAL:
16 July 1963
DATE:
FLIGHT rf:
SAMPLE LINE:
C
G.P.A.
HTDAl
75
ALTITUDE:
0436
Stations 1 - 2 1 Blank
GPM
AIRSPEED:
9
DURATION:
56
SYSTEM:
4
TIME OF RELEASE
STATION
FLOW RATE:
Hours
AIRCRAFT CO'JRSE-
Kr.o*. s
7S
Foe*.
360
D..£-L-oi
Sec.
STATION
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
3£
39
bG
•4\
G.P.A.
STATION
0.2
1.8
1.4
1.5
0.8
0.9
2.0
1.9
1.4
0.7
0.6
0.2
0.5
0.4
O.S
0.4
0.8
0.7
0.6
0.2
, 'i2 - 100 Blank
T-.-.tal
17. r.
G.P.A.
STATION
G.P.*-.
�"T
' OT »,.*
••••.1
*•
FC t V I. •.«,
I
w
1
>
\ :
I
II
1
1
i
\
!
i
I
i
i
i—^.
—i±
i \ ,• vi
ii
!
>
•.•J,
IX
N«trrI«L Sp:4T«]
A.tuw 1 .*
i
;
t
lib
V.
j
j
j
i
tX
'X
i>C
!
;
.
.
Punt!*. L.'l
:i r*«r
T1«B or •*]•»•
j
4
iito
MOD
isw
iuc
1790
nx
KCC
:x»
�275
MASS MEDIAN DIAMETER
DATE:
16 July 1963
FLIGHT #:
CONVERSION FACTOR:
PAPER:
5
C
SAMPLE LINE:
Kronu-'kcto, white .
MATERIAL:
56
FLOW RATE:
GPM
STA.
DROP »
73
73
72
77
73
73
72
72
72
72
72
72
1
2
7
3
4
12
6
8
5
9
11
10
SIZE
7000
5900
5600
5100*
5000
4900
4700
4600
4500
4400
4300
4200
SYSTEM:
STA.
100
DROP #
1A
2.2
Purplt
IIIDAL
SIZE
100 (smallest)
MMD = 70.44+0.1431 (Spot D Max) = 70.44+0.1431(5100) = 363.7 Microns
Max.
Sph. Dia. = 70.44+0.1431(Max Spot) = 70.44+0.1431(7000) = 1072.1
Mi c re-no
Kin. Sph. Dia. = 63 Microns
�276
MASS DEPOSIT
MATERIAL:
DATE:
Purple
16 July 1963
FLIGHT *:
SAMPLE LINE:
IIME OF RELEASE:
DURATION:
FLOW RATE:
SYSTEM:
5
AIRSPEED:
C
ALTITUDE:
0455
12
STATION G.P.A.
STATION
Stations 1 - 7 1 Blank
Hours
AIRCRAFT COURSE:
GPM
56
HIDAL
55
Knots
100
Fcot
360
Degrees
STATION
G.P.A.
Sec.
G.P.A.
STATION
G.F.A.
72
73
74
75
76
77
78
79
80
81
82
83
84
85
1.3
1.6
2.3
1.9
1.2
2.3
3.7
1.5
0.9
0.2
0.8
0.5
0.4
0.2
Stations 8b - 100
Blark
Total
18.8
�! I i
I:'
\
i
J
:. . i .-
•
•
!
I
•
:
IX
i
i
]
'
'•
»"»«'•
*•* 3-n.n
i•
.
r •'!.. i \
' • .•!
•
«lr>i>.~!
klrin!- CNIH
-
(
t
•
t •
!.
,
\
I..
J....
-
_.
�278
MASS DEPOSIT
MATERIAL:
Purple
DATE:
FLOW RATE:
16 Julv 1963
SYSTEM:
FLIGHT *:
6
AIRSPEED:
SAMPLE LINE:
C
ALTITUDE:
TIME OF RELEASE :
DURATION:
0455
13
Hours
AIRCRAFT COURSE:
56
CPM
HIDAL
55
100
360
Knots
Foot
Deer.^s
Sec.
STATION
STATION G.P.A.
20
Stations 1 - 1 9 Blank
21
22
23
24
25
26
27
28
29
30
31
32
33
34
G.P.A.
STATION
0.2
1.6
1.6
1.9
1.3
1.3
1.3
2.6
2.2
0.8
0.3
0.3
0.7
0.4
0.4
Stations 35 - 100 Blank
Total
16.9
C.P.A.
STATION
G.P.A.
�"T
**f 6. .
••>ft, i •• -
-1 .-1 ' _ • ' -.. '<:
I
1
•«•• i
>>5^
!
i
.
.b Jul, .*!•'
|•
j ,1
!l
.
J^
MOC
i:»
_J
INC
L-
KX
iscc
i'oc
ni,
<>:•
ia
�280
MASS DEPOSIT
MATERIAL:
DATE:
Purple
56
SYSTEM:
16 July 1963
HIDAL
FLIGHT #:
7
AIRSPEED:
SAMPLE LINE:
D
AIRCRAFT COURSE:
TIME OF RELEASE:
DURATION:
GPM
FLOW RATE:
0513
16
STATION G.P.A.
STATION
Stations 1 - 7 3 Blank
Hours
'
ALTITUDE:
55
Knots
045
50
Degrees
Feet
Sec.
G.P.A.
STATION
G.P.A.
STATION
74
75
76
77
78
79
80
81
82
83
84
85
86
G.P.A.
2.8
1.7
0.7
0.4
0.5
1.7
1.4
0.6
0.6
0.9
0.2
O.I
0.2
Stations 87 - 100
Blank
Total
11.8
�1 6 JIM «<u • •"•""•' , , .
••T
•>-. •„.
...a... •. ^..
"JL-!<*_' •".Vi: : .."'ii ."
-r-
!
Alrcrfllt divrf*
Tlar nf It.MM
•w-'
I
I .
I'OC
IfflC
I10C
KM
IUC
�283
MASS MEDIAN DIAMETER
DATE:
16 July 1963
CONVERSION FACTOR:
FLIGHT #:
8
PAPER:
SAMPLE LINE:
D
MATERIAL:
FLOW RATE:
56
STA.
27
26
27
23
27
27
27
25
27
28
23
DROP *
2
1
3
5
4
7
8
6
9
11
10
GPM
SIZE
6100
6000
5900
5100*
5000
4900
4800
4700
4600
4400
4300
Kroirekote, white
Purple
SYSTEM:
STA.
50
DROP #
1A
2.2
MIDAL
SIZE
100 (smallest)
MMD = 70.44+0.1431 (Spot D Max) = 70.44+0.1431(5100) = 363.7 Micron.-
Max. Sph. Dia. = 70.44+0.1431 (Max Spot) = 70.44+0.1431(6100) = 943.'4
Microns
Min. Sph. Dia. = 63 Microns
�284
MASS DEPOSIT
Purple
MATERIAL:
DATE :
FLOW RATE:
16 July 1963
SYSTEM:
56
GPM
HIDAL
FLIGHT #:
8
AIRSPEED:
55
Knois
SAMPLE LINE:
D
ALTITUDE:
50
Foot
TIME OF RELEASE:
DURATION:
0513
12
STATION G.P .A.
STATION
Stations 1 - 21 Blank
22
23
24
25
26
27
28
29
30
31
32
33
34
Stations
Hours
AIRCRAFT COURSE:
045
Dopreos
Sec.
G.P. A.
STATION
2.1
2.1
1.6
0.9
0.4
0.8
0.9
2.3
2.0
0.8
0.2
0.2
0.1
35 - 100 Blank
G.P. A.
% Recovery - $5.7
Total 14.4
STATION
G.P. A.
�*
I
'
•i •3
t
'/ •>
I
riitfi: »
! • • !
!
!'
IX
' i
IX
*
<m
1400
ISOC
IUC
17M
!
U
'KC
nOO
�28 7
MASS MEDIAN DIAMETER
16 July 1963
DATE:
FLIGHT #:
9
SAMPLE LINE:
CONVERSION FACTOR:
A
FLOW RATE:
. PAPER:
MATERIAL:
SYSTEM:
GPM
56
STA.
DROP #
78
77
78
78
79
79
77
78
77
77
1
2
3
9
5
A
6
10
7
8
SIZE
5200
5000
4400*
4300
4200
4100
4000
3900
3700
3600
STA.
DROP #
99
1A
J.2
Kromekoto . white
Purpio
1IIDAL
SIZE
100 (smallest)
HMD - 70.44+0. 1431 (Spot D Max) = 70.44+0.1431(4400) = 318.2 Micicr.s
Max. Sph. D i a . = 70.44+0.1431(Max Spot) = 70.44+0.1431(5200) = 314.6
Micr:v.r
M i n . Spli. Dia. = 63 Microns
�288
MASS D E P O S - :
MATERIAL:
DATE:
purple
FLOW KA.E
16 July 1963
SVSThM:
FLIGHT *:
9
AIRSPEED:
SAMPLE LINE:
A
IT.
':. IOAL
AI.THVDE:
TIME OF RELEASE:
DURATION:
0534
09
STATION G.F.A.
STATION
Stations 1 - 7 4 Blank
Hoars
K'.o:s
75
AIRCRAFT COURSE:
50
Fo?».
0V)
Di_gjrci's
SIAT-.ON
C.P.A.
Sec.
G.P.A.
STAriON
G.P.*.
75
76
'3.1
0. ;
i1'. 0.:
0. •
S'd-
�T
' <h* It.-*
••• ft. »
••• Mv.
i
:
•
KX
II
K.
ICC
soc
:x
K.
w
HOC
IMC
1HO
UX
ISCO
160C
I73C
'•> (*<>• •
W . I cr«
IIJC
UK
K»
�290
MASS DEPOSIT
MATERIAL:,
DATE:
Purple
SYSTEM:
16 July 1963
FLIGHT #:
10
DURATION:
GPM
HIDAL
AIRSPEED:
0535
13
Hours
75
Knots
ALTITUDE:
SAMPLE LINE:
TIME OF RELEASE:
56
FLOW RATE:
50
Feet
AIRCRAFT COURSE:
090
Degrees
Sec.
STATION G.P.A.
STATION
Stations 1 - 2 3 Blank
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
G.P.A.
STATION
2.8
2.0
1.1
1.2
1.7
1.6
1.6
1.2
1.1
1.0
0.9
0.6
0.7
0.6
0.3
0.4
Stations 40 - 100 Blank
Total
18.8
G.P.A.
STATION
G.P.A.
�r•
1 t JUL IS
. _ .;> i .-; t . i* . ,
.; ..j / .;*' t- . :; .
:^.>i
f
f
.«•
Cr
. f '
.
i
I
>x
iy.
i
«x
;x
itoc
ira
1100
u»
iicc
IMC
u«
nx
nx
not
�293
MASS MED UN DIAMETER
16 Julv 1963
DATE:
IT #:
CONVERSION FACTOR
PAPER:
11
,E LINE :
RATE:
MATERIAL:
D
56
STA.
74
75
73
74
74
74
74
75
75
7b
DROP #
1
2
8
4
3
5
6
7
9
10
CPM
SIZE
5000
4600*
4400
4300
4100
4000
3900
3800
3700
3500
Krctr.ckc-lo. white
Purple
SYSTEM:
STA.
89
DROP #
1A
2.2
illDAL
SIZE
: 00 (3i4:i 11 «••:••.'
40
TO = 70.44+0 .1431 (Spot D Max) = 70.44+0.143) ( 6 0 > = 331.2 Ml-. t:r -
Max. Sph. Dia. = 70.4itO. 1431 (Max Spot) = 7 . . , 0 !ii: ( C GOO> = •>S;.9
04'+.
Min. Sph. Dia. = 63 Microns
�294
MASS- DEPOSIT
MATERIAL:
DATE:
Purple
FLIGHT #:
SAMPLE LINE:
HIDAL
11
AIRSPEED:
75
K-ots
D
ALTITUDE:
100
Foot
0555
TIME OF RELEASE:
DURATION:
SYSTEM:
16 July I9o3
GPM
56
FLOW RATE:
12
STATION G.P.A.
STATION
Stations 1 - 7 0 Blank
AIRCRAFT COURSfc :
Hours
045
DegK.es
Sec.
G.P.A.
STATION
71
72
73
74
75
76
77
78
79
Stations
G.P.A.
1.1
2.0
1.5
0.7
0.4
0.4
1.4
2.6
2.3
80 - 100 Blank
°L Recovery - 7 .
72
Total
12.4
STATION
G.P.A.
�:
.
i
i
i
i
i
i
I
1
!
.
•
;
1
.''<
!
j
1
Invlnd. V..a '.r-
\
�296
MASS DEPOSIT
MATERIAL:
Purple
FLOW RATE:
DATE:
16 July 1963
SYSTEM:
FLIGHT #:
SAMPLE LINE:
GPM
HIDAL
12
AIRSPEED:
75
Knots
D
ALTITUDE:
100
Feet
TIME OF RELEASE :
DURATION:
56
0558
12
Hours
AIRCRAFT COURSE:
045
Degrees
Sec.
STATION G.P.A.
STATION
Stations 1- 19 Blank
20
-21
22
23
24
25
26
27
28
29
30
31
G.P.A.
STATION
0.0
2.2
1.5
1.2
1.5
0.8
0.6
2.0
2.4
2.7
0.1
0.1
Stations 32 - 100 Blank
Total
15.1
G.P.A.
STATION
G.P.A.
�Snp!* .10'
' •*
f U i . r l . : Spn,..*:•!•--•
Aln^,r,l
•
> • . i> cm
p',
:-)o p..
,-i [„„,
Pb
.
�298
KAS5 BEPCS II
MATERIAL:
DATE:
Purple
Si1 STEM:
1.6 July 1963
Fl ICHT # :
13
TIME OF RELEASE:
ALTZTJDK:
b6
QfAb
3
STATION I.P.A.
STATIC1*-*
Stations i •- 71 Blank
i!ours
A.'RCRAFT CO'JRSE
CFM
rflDAL
AIRSPEED.
D
SAMPLE LINE:
DURATION:
FLOW RA'ff:
7c
Kri-" C 5
Fee'.
•»3
O^b
0<_atcf5
Sec.
G.P.A.
ST£770N
C.P.A.
_S TAT I r. N _"-.P. A.,_
72
73
78
/9
6C
S'.at i
Rc«.ovory - 87.7
0."?
2.1
.7
1.2
2.3
�r
. . .
—
4
X
*«(.> J*lo»
" mi At.«*pr.«i!
T
•*-•»••••. Hc^v**f>
pjr-)^. *...:
A'-l:ud*
'S^»r-
I
:
.
u
Inwlnd. W . '
�300
MASS DEPOSIT
MATERIAL:
Purple
DATE.
16 July 1963
D
56
ALTITUDE:
TIME OF RELEASE:
0617
9
STATION G.P.A.
STATION
Stations 1 - 1 8 Blank
Hours
CFM
HIDAL
AIRSPEED:
SAMPLE LINE:
19
20
21
22
23
24
25
20
2?
2S
29
Stations
SYSTEM:
14
FLIGHT 4:
DURATION:
FLOW RATE:
AIRCRAFT COURSE:
75
Kr.cts
75
Fi'Ot
045
Decrees
Sec.
G.P.A.
STATION
C.P.A.
0.5
1.0
2.i
2.2
1.6
l.l
0.3
1.3
3.1
3.2
0.6
30 - 100 Blank
1 Recovery - 108.9
r
Total 17.5
STATION' G.P.A.
�-~.zi.i~;-*.?.. ••' .
.••« .-•'S i . .'•
.
'
A.
i
1•
1"
s^>:. Un.
3
/7«A-l«p:Brf
^ rf .' IfTmjfi
Ifiwlnd. %«.%
Purvi*. . . i t ,
:% r~i
> I-.*.
Aliip'fd
A l r i r - ' l Cuur»«
TIM > ' «•••••!
noc
izcc
iioc
tut
•
•
:
') boil
Itbi »«itr**i
'J»17 HAHII
�302
P-jrp'. eDATE:
1C July 196'V
FLIGHT #:
AIRSPEED:
15
TIME OF RELEASE:
P.-...
«.:.?: TJDE ..
SAMPLE LINE:
T COURSE
C633
D',-v =
DURATION:
STATION G.P.A.
Stations 1 - 69 Blank
'X' P.P.A.
AN.
70
cTf
71
0.6
7,
.
C.<)
7?
:.'}
2.;
i j
8'.'
S'-
7 RC-I.OVV.TV - 69.8
C. 3
�' 6 JUL liiuj ••—— ,
XT
! - ) t B. .
•.. a .
•. f^.
i. .2-: ;._2iJ_ :'; .
.-•>£_M . - . " ...
,C~
M
V
' '-1
S !
I
.
It July i*t>
r«pf A tMpird
N j - r r l * Sprayn*
\
Ir.vlni 1 . "*... Cm
Fur^.*. ^. il •"»»
Alr>p~d
A l r e u f t Court*
•
:
)1 Kiwtla
U) D*iri
t
\
*
f
:x
.
.
i
^
M.
•.*
;x
ix
-coo
S-l^ 'f«MI
noc
ino
uoo
isoo
iuc
uoc
nac
:>x
IMI
�304
hA.5'1,
MATERIAL:
DATE:
FLIGHT #:
SAMPLE LINE:
TIME OF RELEASE:
DURATION:
P.ivpV
F-..CU RATt-
j.'j -.iij- .963
.6
GPM
33
Knots
SYSTEM: _ _
16
A-R3PE£D:
D
Ho.-rs
0635
U
A1RCKAI-11 COl SSE -.
O^r
Dcgrc* s
STATION
C-.F.A.
Sec.
STATION G.P.A.
STATICS
18
Stations 1 - 1 7 Blar.k
19
20
21
22
23
24
25
26
27
28
29
30
U
12
33
Gr .
0.2
1.3
1.7
1.
4
1.5
1.3
0.8
C.7
STATION
ST-
v'.P.A.
1.4
i,L
2.1
3.3
0.)
C.2
•'.2
0.0
/.' .Ki-covory - 81.2
Tot.il
�I.C
?iX>
IX
«C
:KC
not
�
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
007
Folder
The folder containing the original item.
0062
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Creator
An entity primarily responsible for making the resource
Boyer, Lester W.
J.W. Brown
Description
An account of the resource
<strong>Corporate Author: </strong>U.S. Army Biological Laboratories, Director of Biological Research, Crops Division, Fort Detrick, Frederick, Maryland
Date
A point or period of time associated with an event in the lifecycle of the resource
1964-06-01
Title
A name given to the resource
Supplement II to Technical Report 46: Basic Data From H-34/Hidal Calibration Trials, 1963
Subject
The topic of the resource
spray equipment
Eglin AFB
herbicide application
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/f7dec7f13438a6e941502d236acb5f7d.pdf
d5c0136a345740e328a4041a78dbd405
PDF Text
Text
Item ID Number:
00090
Author
Young, Alvin L.
CorpOPatB Author
Environics and Flame Munitions Branch, Flame,
Incendiary and Explosives Division, Air Force
Armament Laboratory, Eglin AFB, Florida
Roport/Artido Tltlfl Ecological Studies on a Herbicide-Equipment Test Ares (TA C-52A) Eglin AFB
Revervation, Florida; Final Report: January 1967 to November 1973
Journal/Book Title
Year
1974
Month/Day
January
Color
Number of Images
144
DOSGrlptOn NOteS
Program No. 5154-02
Friday, December 01, 2000
Page 90 of 91
�TECHNICAL REPORT AFATL-TR-74-12
ECOLOGICAL STUDIES
ON A
HERBICIDE-EQUIPMENT TEST AREA
(TA C-52A)
EGLIN AFB RESERVATION/FLORIDA
JANUARY 1974
FINAL REPORT: January 1967
to November 1973
Approved for public release; distribution unlimited.
ENVIRONICS AND FLAME MUNITIONS BRANCH
FLAME, INCENDIARY AND EXPLOSIVES DIVISION
AIR FORCE ARMAMENT LABORATORY
AIR FORCE SYSTEMS COMMAND » UNITED STATES AIR FORCE
EGLIN AIR FORCE BASE, FLORIDA
�UNCLASSIFIED
SECURITY CLASSIFICATION OF THIS PAGE (When Data Entered)
READ INSTRUCTIONS
BEFORE COMPLETING FORM
REPORT DOCUMENTATION PAGE
1. REPORT NUMBER
2. GOVT ACCESSION NO
3. RECIPIENT'S CATALOG NUMBER
AFATL-TR-74-12
4. T I T L E (and Subtitle)
5. TYPE OF REPORT & PERIOD C O V E R E D
Final Report
January 1967 - November 1973
ECOLOGICAL STUDIES ON A HERBICIDE-EQUIPMENT
TEST AREA (TA C-52A) EGLIN AFB RESERVATION,
FLORIDA
6. P E R F O R M I N G ORG. REPORT N U M B E R
8. CONTRACT OR GRANT NUMBERfs.)
7. AUTHORfs.)
Alvin L. Young, Captain, USAF, Ph.D.
9. PERFORMING O R G A N I Z A T I O N NAME AND ADDRESS
10. PROGRAM ELEMENT, PROJECT, TASK
AREA & WORK UNIT NUMBERS
Flame, Incendiary and Explosives Division. (DLIP)
Air Force Armament Laboratory
Eglin Air Force Base, Florida 32542
5154-02
12. REPORT DATE
11. CONTROLLING OFFICE NAME AND ADDRESS
January 1974
Air Force Armament Laboratory
Air Force Systems Command
Eglin Air Force Base, Florida 32542
13. NUMBER OF PAGES
141
14. MONITORING.AGENCY NAME & ADDRESSf/f different from Controlling Office)
IS. SECURITY CLASS, (of this report)
Unclassified
Air Force Systems Command (SDWC)
Andrews Air Force Base
Washington D. C. 20334
15a. DECLASSIFICATION/DOWN GRADING
SCHEDULE
16. DISTRIBUTION STATEMENT (of this Report)
Approved for public release; distribution unlimited.
17. D I S T R I B U T I O N STATEMENT (of the abstract entered In Block 20, It different
from Report)
18. SUPPLEMENTARY NOTES
Available in DDC
19. KEY WORDS (Continue on reverse side If necessary and Identity by block number)
Algal Survey
4-Amino-3,5,6-Trichloropicolinic
Amphibians
Animal Survey Studies
Bioassay
Acid
Blue
Defoliant Testing
Birds
2,4-Dichlorophenoxyacetic Acid
Dimethylarsinic Acid
20. ABSTRACT (Continue on reverse side if necessary and Identify by block number)
This report attempts to answer the major questions concerned with the ecological consequences of
applying massive quantities of herbicides (346,117 pounds), via repetitive applications, over a period
of eight years, 1962 - 1970, to an area of approximately one square mile. Moreover, the report
documents the persistence, degradation, and/or disappearance of the herbicides from the Test Area's
soils and drainage waters and their subsequent effects (direct or indirect) upon the vegetative,
faunal, and microbial communities. The active ingredients of the four military herbicides (Orange,
Purple, White, and Blue) sprayed on Test Area C-52A were 2,4-dichlorophenoxyacetic acid (2,4-D),
(continued)
FORM
73
DD , JAN
1473
EDITION OF 1 NOV 65 IS OBSOLETE
UNCLASSIFIED
SECURITY CLASSIFICATION OF THIS PAGE (When Data Entered)
�IIMPI
SECURITY CLASSIFICATION OF THIS PAGEfHTien Data Entered;
Item 19. Continued
Ecological Investigations
Fish
Herbicide
Herbicide Equipment Test Grid
Histology
Mammals
Microbial Survey
Military Defoliation Program
Necropsy
Orange
Purple
Reptiles
TCDD
Teratogenic
Test Area C-52A, Eglin AFB Reservation
2,3,7,8-Tetrachlorodibenzo-p-dioxin
2,4,5-Trichlorophenoxyaetic Acid
Vegetative Coverage Survey
White
Item 20.
2,4,5-trichlorophenoxyacetic acid (2,4,5-T), 4-amino-3,5,6-trichloropicolinic
acid (picloram), and dimethylarsinic acid (cacodylic acid). It is probable that the 2,4,5-T
herbicide contained the highly teratogenic (fetus deformina) contaminant 2,3,7,8-Tetrachlorodibenzo-p-dioxin (TCDD). Significant herbicide residues were found in 1969. However, analysis
of soil cores in 1971 indicated residues of 2,4rD, 2,4,5-T, picloram, and arsenic to be in the parts
per billion range; no TCDD was found at this detection limit. Soil samples collected in June and
October 1973 showed TCDD (or a TCDD-like chemical) levels ranging from less than 10 parts
per trillion (ppt) to 710 ppt. Direct effects of the herbicides on the vegetative community
were temporary. With the disappearance of residue, vegetative succession was initiated. By
1973, the majority of the test area could not be distinguished from control sites. Analysis
of sample animal populations indicated that no histological or gross abnormalities were
present in adults or their progeny.
UNCLASSIFIED
SECURITY CLASSIFICATION OF THIS PAGEfWhen Data Entered)
�PREFACE
The Air Force project directly related to the information in this report is Air Force Systems
Command Project 5154-02, Ecological Survey of Test Area C-52A, Eglin AFB Reservation, Florida.
This report documents five years of ecological investigations performed between 1967 and 1973.
The assistance provided during portions of this report by the Air Force Environmental Health
Laboratory, Booz-Allen Applied Research, Dow Chemical U.S.A., United States Air Force Academy,
United States Department of Agriculture, University of Alabama, University of Florida, and Vitro
Services is gratefully acknowledged.
Information on the test grid monitoring system and types and amounts of defoliants disseminated on Test Area C-52A from July 1962 to April 1969 was obtained from Armament Development and Test Center working papers, "Defoliant History of Test Area C-52A", by Helen Biever.
After April 1969, this same information was obtained from Vitro Services, Vitro Corporation of
America. Information on soils of Test Area C-52A was obtained from a July 1969 soil survey
of Eglin AFB Reservation prepared by the Soil Conservation Service of the United States
Department of Agriculture.
This technical report hasjpeen reviewed and is approved.
F. RAMON BONNANO, Lt Colonel, USAF
Chief, Flame, Incendiary and Explosives Division
�LIST OF CONTRIBUTORS
Kenneth M. Ayers, Captain, USAF, VC, Staff Veterinarian, Veterinary Pathology Division, Armed
Forces Institute of Pathology
William J. Cairney, Captain, USAF, BSC, Assistant Professor of Life Sciences, Department of Life
and Behavioral Sciences, United States Air Force Academy
Robert W. Clegern, Captain, USAF, BSD, Ph.D., Research Entomologist, Air Force Environmental
Health Laboratory
John H. Hunter,Ph.D., Field Research and Development Specialist, Dow Chemical, U.S.A.
P. Jeffery Lehn, B.A., Biologist, Somerville, New Jersey
John W. Sigler, 1 Lt, USAF, M.S., Project Scientist, Flame Incendiary and Explosives Division,
Air Force Armament Laboratory
Charles E. Thalken, Major, USAF, VC, Assistant Professor of Life Sciences, Department of Life
and Behavioral Sciences, United States Air Force Academy
William E. Ward, Lt Colonel, USAF, Ph.D., Tenure Professor, Department of Life and Behavioral
Sciences, United States Air Force Academy
Edwin A. Woolson, Ph.D., Pesticide Chemist, Pesticide Degradation Laboratory, United States
Department of Agriculture
Alvin L. Young, Captain, USAF, Ph.D., Associate Professor of Life Sciences, Department of Life
and Behavioral Sciences, United States Air Force Academy
�TABLE OF CONTENTS
Section
Page
SUMMARY
I
5
INTRODUCTION
1. Description of Geographical and Environmental Factors
2. Description of the Test Facility
3. Descriptions of Samplings Grids and Herbicide Deposition
4. Description of Pesticides
10
10
12
19
23
BIOASSAY AND CHEMICAL RESIDUE STUDIES OF THE SOILS
OF TEST AREA C-52A
1. Synopsis of Bioassay Research, 1969 - 1970
2. Synopsis of Bioassay Research, 1970 - 1971
3. Results and Discussion
4. Conclusions
5. Chemical Analyses of Soil Cores
28
28
31
33
42
42
III
STUDIES OF THE VEGETATION OF TEST AREA C-52A
1. Synopsis of Taxonomic Studies, 1966 - 1969
2. Synopsis of Growth of Sand Pine, 1969 - 1970
3. Synopsis of Histological Study of Yucca, 1970
4. Current Vegetative Succession Studies
52
53
54
56
57
IV
STUDIES OF THE ANIMALS OF TEST AREA C-52A
1. Synopsis of Qualitative Animal Surveys, 1970 - 1973
2. Current Studies on Animals
3. Materials and Methods
4. Results and Discussion
5. Conclusions
76
76
78
82
83
91
V
INSECT DENSITY AND DIVERSITY STUDIES ON TEST AREA C-52A 92
1. Synopsis of Previous Research, May - June 1971
92
2. Materials and Methods
92
3. Results and Discussion
93
4. Summary and Conclusions
109
II
VI
VII
AQUATIC STUDIES OF TEST AREA C-52A
1. Synopsis of Previous Research, 1969
2. Current Studies of Aquatic Organisms
3. Conclusions
110
110
116
125
STUDIES ON THE MICROFLORA OF TEST AREA C-52A
1. Synopsis of Previous Research, 1967 - 1970
2. Current Studies on Microflora
3. Literature Review
4. Materials and Method
5. Results and Discussion
6. Current Studies on Survey of Aquatic Algae
7. Conclusions
3
(The reverse of this page is blank)
128
128
130
130
133
135
135
139
��SUMMARY
In support of programs testing aerial dissemination systems, a one square mile test grid
on Test Area (TA) C-52A, Eglin AFB Reservation, Florida, received massive quantities of
military herbicides. The purpose of these test programs was to evaluate the capabilities of
the equipment systems, not the biological effectiveness of the various herbicides. Hence,
it was only after repetitive applications that test personnel began to express concern over the
potential ecological and environmental hazards that might be associated with continuance
of the test program. This concern led to the establishment of a research program in the fall
of 1967 to measure the ecological effects produced by the various herbicides on the plant
and animal communities of TA C-52A. This report documents 6 years of research (1967 - 1973)
on TA C-52A and the immediately adjacent streams and forested areas.
This report attempts to answer the major questions concerned with the ecological consequences of applying massive quantities of herbicides (346,117 pounds), via repetitive applications, over a period of 8 years (1962 - 1970) to an area of approximately one square mile.
Moreover, the report documents the persistence, degradation, and/or disappearance of the
herbicides from the soils and drainage waters of TA C-52A, and the subsequent effects (direct
or indirect) of the herbicides upon the vegetative, faunal, and microbial communities.
The active ingredients of the four military herbicides (Orange, Purple, White, and Blue)
sprayed on TA C-52A were 2,4-dichlorophenoyxacetic acid (2,4-D), 2,4,5-trichlorophenoxyacetic
acid (2,4,5-T), 4-amino-3,5,6-trichloropicolinic acid (picloram), and dimethylarsinic acid
(cacodylic acid). It is probable that the 2,4,5-T herbicide contained the highly teratogenic
(fetus deforming) contaminant 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD). From 1962 to
1964, 92 acres of the test grid received 1,894 pounds 2,4-D, 2,4,5-T per acre while, in 1964
to 1966, another 92 acres received 1,168 pounds per acre. From 1966 to 1970, a third distinct area of over 240 acres received 343 pounds per acre of 2,4-D and 2,4,5-T, and 6 pounds
per acre of picloram; and from 1969 to 1970, this same area received 53 pounds per acre of
cacodylic acid (28 pounds per acre of arsenic as the organic pentavalent form; calculated on
weight of Blue applied per acre).
From the rates of herbicides that were applied during the years of testing spray equipment,
it was obvious that TA C-52A offered a unique opportunity to study herbicidal persistence
and soil leaching. Yet the problem of how best to assess the level of herbicide residue was a
difficult one. The herbicides could be chemically present but because of soil binding might
not be biologically active. Thus, both bioassay techniques and analytical analyses were
employed. The first major bioassay experiment was conducted in April 1970. By considering
the flightpaths, the water sources, and the terracing effects, it was possible to divide the one
square mile test grid into 16 vegetation areas. These areas formed the basis for the random
selection of 48 soil cores taken from the surface to a depth of 3 feet. Soybean bioassays
indicated that 27 of the 48 cores were significantly different from control cores (95% probability level). The results indicated that soil leaching or penetration was much more prevalent
along the dissemination flightpaths than in other areas of the test grid. Efforts to quantitate
(chemically) the bioassay were confined to only the top 6 inch increment because of withincore variations. By considering that all phytotoxic effects resulted from 2,4-D and 2,4,5-T,
the average value for the top 6 inches of the eight cores showing greatest herbicide concentration was 2.82 ppm (parts per million) herbicide. Chemical analyses of soil cores collected
from the eight sites showing greatest phytotoxic concentrations were performed in December
�1970. Results indicated that the maximum concentration of either 2,4-D or 2,4,5-T was 8.7
ppb (parts per billion). A 1970 analysis of soil cores from areas receiving the greatest quantities
of Blue indicated maximum arsenic levels of 4.70, 1.30, and 0.90 ppm, respectively, for the
first three 6 inch increments of the soil profile. These same increments were again collected and
analyzed in 1973, and the levels of arsenic were 0.85, 0.47, and 0.59 ppm for the three consecutive 6 inch increments. Leaching of the arsenical from the soils may have occurred. In November
1969, picloram analysis of soil cores from areas receiving greatest quantities of White indicated
maximum levels of 2.8 ppm picloram present in the 6 to 12 inch increment. An analysis of the
same sites in 1971 indicated the picloram had leached further into the soil profile but concentrations were significantly less (ppb). The analyses of soil cores in 1971 showed no residue of TCDD
at a minimum detection limit of less than 1 ppb, even in soils previously treated with 947 pounds
2,4,5-T per acre. However, data from soil analysis (via mass spectrometry) of four total samples
collected in June and October 1973 indicated TCDD levels of <10, 11, 30, and 710 parts per
trillion (ppt), respectively. These levels were found in the top 6 inches of soil core. The greatest
concentration (710 ppt) was found as a sample form the area that received 947 pounds 2,4,5-T
in the 1962 - 1964 test period.
A comparison of vegetative coverage and occurrence of plant species on the one square
mile grid between June 1971 and June 1973 showed that areas with 0 to 60% vegetative cover
in 1971 had a coverage of 15% to 85% in June 1973. Those areas having 0 to 5% coverage
in 1971 (areas adjacent to or under flightpaths used during herbicide equipment testing) had
15% to 54% coverage. The rate of coverage seemed to be dependent upon soil type, soil
moisture, and wind. There was no evidence to indicate that the existing vegetative coverage
was directly related to herbicide residue in the soil: some dicotyledonous or broadleaf plants
that are normally susceptible to damage from herbicide residues occurred throughout the entire
one square mile grid except in a few irregularly spaced barren areas. The square-foot transect
method of determining vegetative cover indicated that the most dominant plants on the test area
are the grasses - switchgrass (Panicurn virgatum). woolly panicum (Panicum lanuqinosum). and the
broadleaf plants - rough buttonweed (Diodia teres). poverty weed (Hypericum gentianoides). and
common polypremum (Polypremum procumbens). In 1971, 74 dicotyledonous species were
collected on the one square mile grid; in 1973, 107 dicotyledonous species were collected. All of
the plant species collected were pressed, mounted, and placed in the Eglin AFB Herbarium.
An evaluation of the effects of the spray equipment testing program on faunal communities
was conducted from May 1970 to August 1973. The extent of any faunal ecological alteration
was measured by assessing data on species variation, distribution patterns, habitat preference
(and its relationships to vegetative coverage), and the occurrence and incidence of developmental
defects as well as gross and histologic lesions in postmortem pathological examinations.
A total of 73 species of vertebrate animals (mammals, birds, reptiles, and amphibians)
were observed on TA C-52A and in the surrounding area. Of these 73 species, 22 were observed
only off the grid, 11 were observed only on the grid, and 40 were observed to be common to
both areas. During the early studies, no attempts were made to quantitate animal populations
in the areas surrounding the grid; however, in 1970 preliminary population studies by trap-retrap
methods were performed on beach mouse (Peromyscus polionotus) populations for a 60 day
period to confirm the hypothesis that it was the most prevalent species on the grid. The
hypothesis was supported by the capture of 36 beach mice from widely distributed areas on
the grid, except in areas with less than 5% vegetation. Eight pairs of eastern harvest mice were taken
to the laboratory and allowed to breed. Six of the eight pairs had litters totaling 24 mice.
These progeny were free from any gross external birth defects. During February - May 1971,
population densities of the beach mouse were studied at eight different locations on the grid
and in two different areas off the grid which served as controls. Populations were estimated
�on the basis of the trap-retrap data. There was no difference in mouse population densities in
herbicide treated and untreated control areas affording comparable habitats. All indications were
that any population differences in other animal species between the test area and the surrounding
area were due to differences caused by the elimination of certain plants, and therefore, certain
ecological niches, rather than being due to any direct toxic effect of the herbicides on the animal
populations present on TA C-52A.
During the last day of the 1971 study, 9 mice were captured and taken to the laboratory for
postmortem pathological examination. There were no instances of cleft palate or other deformities.
Histologically, liver, kidney, and gonadal tissues from these animals appeared normal. In the 1973
study, several different species of animals were caught, both on and off the test grid. These included
beach mice (Peromyscus polionotus), cotton mice (Perorrjyscus gossypinus), eastern harvest mice
(Reithrodontomys humulis), hispid cotton rats (Signodon hispidus), six-lined racerunners
(Cnemidophorus sexlineatus), a toad (Bufo americanus), and a cottonmouth water moccasin
(Ankistrodon piscivorus). A total of 89 animals were submitted to the Armed Forces Institute of
Pathology, Washington, D. C., for complete pathological examination including gross and microscopic studies. Liver and fat tissue from 70 rodents were forwarded to the Interpretive Analytical
Services, Dow Chemical, U.S.A., for TCDD analyses. The sex distribution of the trapped animals
was relatively equal. The ages of the animals varied, but adults predominated in the sample. No
gross or histological developmental defects were seen in any of the animals. Several of the rats
and mice from both groups were pregnant at the time of autopsy. The stage of gestation varied
from early pregnancy to near term. The embryos and fetuses were examined grossly and microscopically, and no developmental defects or other lesions were observed. Gross necropsy lesions
were relatively infrequent and consisted primarily of lung congestion in those animals that had
died from heat exhaustion prior to being brought to the laboratory. The organ weights did not
vary significantly between the test and control animals when an animal with lungs and kidneys
showing inflammatory pathological lesions was removed from the sample. Histologically, the tissues
of 13 of the 26 control animals and 40 of the 63 animals from the test grid were considered normal.
Microscopic lesions were noted in some animals from both groups. For the most part, these were
minor changes of a type one expects to find in any animal population. One of the most common
findings was parasites. A total of 11 controls and nine grid animals were affected with one or more
classes of parasites. Parasites may be observed in any wild species, and those in this population were
for the most part incidental findings that were apparently not harmful to the animal. There were
exceptions however; protozoan organisms had produced focal myositis in one rat and were also
responsible for hypertrophy of the bile duct epithelium in a six-lined racerunner.
Moderate to severe pulmonary congestion and edema was seen in several rats and mice. All
of these animals were found dead in the traps before reaching the laboratory, and the lung lesions
were probably the result of heat exhaustion. The remainder of the lesions in both groups consisted
principally of inflammatory cell infiltrates of various organs and tissues. These lesions were usually
mild in extent and although the etiology was not readily apparent, the cause was not interpreted
as toxic. The analysis of TCDD from the rodents collected in June and October 1973 indicated
that TCDD or a chemically similar compound accumulated in the liver and fat of rodents collected
from an area receiving massive quantities of 2,4,5-T. However, based on the pathological studies,
there was no evidence that the herbicides produced any developmental defects or other specific
lesions in the animals sampled or in the progeny of those that were pregnant. The lesions found
were interpreted to be of a naturally occurring type and were not considered related to any
specific chemical toxicity.
�In 1970, beach mice were not found on the more barren sections of the grid (0 to 5%
vegetative cover). However, some areas of the grid had a population density that exceeded
that of the species most preferred habitat as reported in the literature. In 1973, in an attempt to
correlate distribution of the beach mouse with vegetative cover (i.e., habitat preference) a
trapping-retrapping program of 8 days duration was conducted. The majority of animals (63)
were found in areas with 5% to 60% vegetative cover: Within this range, the greatest number
of animals trapped (28) was from an area with 40% to 60% cover. A similar habitat preference
has been observed along the beaches of the Gulf Coast. In this study, it appeared that the
beach mouse used the seeds of switchgrass (Panicum virgatum) and woolly panicum (Panicum
lanuginosum) as a food source.
Trapping data from 1971 and from 1973 were compared to determine whether an increase
in the population of beach mice had occurred. The statistical evidence derived from that study
showed that the 1.64 beach mice per acre population (based on the Lincoln Index for 1973)
was slightly higher than the 0.8 and 1.4 mice per acre reported for a similar habitat. The population of beach mice was also higher in 1973 than in 1971 in the area of the test grid. The
apparent increase in beach mouse population on the grid for 1973 over 1971 was probably
due to the natural recovery phenomenon of a previously disturbed area (i.e., ecological
succession). Some areas of the test grid have currently exceeded the preferred
percentage of vegetative coverage of the beach mouse habitat, and other areas were either
ideal or fast developing into an ideal habitat. If the test grid remains undisturbed and
continues toward the climax species, a reduction in the number of beach mice will probably
occur simply due to the decline of preferred habitat.
A 1973 sweep net survey of the Arthropods of TA C-52A resulted in the collection of
over 1,700 specimens belonging to 66 insect families and Arachnid orders. These totals
represented only one of five paired sweeps taken over a one mile section of the test grid.
A similar study performed in 1971 produced 1,803 specimens and 74 families from five paired
sweeps of the same area using the same basic sampling techniques. A much greater number
of small to minute insects were taken in the 1973 survey. Vegetative coverage of the test
area had increased since 1971. The two studies showed similarities in pattern of distribution
of arthropods in relation to the vegetation, number of arthropod species, and arthropod
diversity. Generally, the 1973 study showed a reduction of the extremes found in these
parameters during the 1971 study. This trend was expected to continue as the test area
stabilizes and develops further plant cover, thus allowing a succession of insect populations
to invade the recovering habitat.
Two classes of aquatic areas are associated with TA C-52A; ponds actually on the one
square mile area and streams which drain the area. Most of the ponds are primarily of the
wet weather type, drying up once in the last 5 years; however, one of the ponds is spring
fed. Three major streams and two minor streams drain the test area. The combined annual
flow of the five streams exceeds 24 billion gallons of water. Seventeen species of fishes
have been collected from the major streams and three species from the spring fed pond on
the grid. Statistical comparisons of 1969 and 1973 data of fish populations in the three
major streams confirm a chronologically higher diversity in fish populations. However, the
two control streams confirm a similar trend in diversity. Nevertheless, from examining all
of the aquatic data, certain observations support the idea that a recovery phenomenon is
occurring in the streams draining TA C-52A. These observations are difficult to document
8
�because of insufficient data. For example, in 1969 the southern brook lamprey (Ichthyomyzon
gagei) was never collected in one of the streams immediately adjacent to the area of the grid
receiving the heaviest applications of herbicides; however, in 1973 this lamprey was taken in
relatively large numbers. These observations may or may not reflect a change in habitat due
to recovery from herbicide exposure. Residue analyses (1969 to 1971) of 558 water samples,
68 silt samples, and 73 oyster samples from aquatic communities associated with drainage
of water from TA C-52A showed negligible arsenic levels. A maximum concentration of 11 ppb
picloram was detected in one of the streams in June 1971, but this level had dropped to less
than 1 ppb when sampled in December 1971. TCDD analysis of biological organisms from streams
draining TA C-52A or in the ponds on the test area were free from contamination at a detection
limit of less than 10 parts per trillion.
In analyses performed 3 years after the last application of 2,4-D and 2,4,5-T herbicides,
the test grid exhibited population levels of soil microorganisms identical to those in adjacent
control areas of similar soil and vegetative characteristics not exposed to herbicides. There
were increases in Actinomycete and bacterial populations in some test site areas over levels
recorded in 1970. This was possibly due to a general increase in vegetative cover for those
sampling sites and for the entire test grid. No significant permanent effects could be
attributed to exposure to herbicides.
Data on aquatic alga populations from ponds on the one square mile grid (previously exposed
to repetitive applications of herbicides) indicated that the genera present were those expected in
warm, acid (pH 5.5), seepage, or standing waters.
�SECTION I
INTRODUCTION
The Eglin AFB Reservation has served various military uses, one of them having been the
development and testing of aerial spray equipment (e.g., herbicide spray equipment). It was
necessary for this equipment to be tested under controlled conditions that were as near to being
realistic as possible. For this purpose a testing installation was established in 1962 on the Eglin
Reservation with the place of direct aerial application restricted to an area approximately one
mile square within Test Area C-52A (TA C-52A) in the southeastern part of the reservation.
In support of programs testing aerial dissemination systems, TA C-52A received massive
quantities of military herbicides. The purpose of these test programs was to evaluate the
capabilities of the equipment systems, not the biological effectiveness of the various herbicides.
After repetitive applications, personnel involved with the test program expressed concern about
potential ecological and environmental hazards that might be associated with continuance of
these test programs. This concern led to the establishment of an "Environmental Pollution
Control and Monitoring System Task Team". One of the purposes of this report is to document
the efforts of this task team and other personnel who were assigned to or were associated with
the Air Force Armament Laboratory and the Armament Development and Test Center. Their
efforts should serve as an indication of the interest and concern on the part of the Air Force
for pollution abatement as an integral part of weapon systems development. In view of the
controversy associated with the use of herbicides, TA C-52A offers a unique opportunity
for evaluating the ecological effects of repetitive applications of herbicides. Data obtained during
the past six years of research, plus the current research effort, may be of significance in dictating
future programs involving herbicides in military programs, civic action applications, and the public
acceptance of herbicides for continued use in weed and brush control programs.
1. DESCRIPTION OF GEOGRAPHICAL AND ENVIRONMENTAL FACTORS
a. General Area
The Eglin AFB Reservation is located in Northwest Florida where it occupies a portion
of Santa Rosa Island, Okaloosa Island, the southeastern part of Santa Rosa County,
the southern half of Okaloosa County, and the southwestern quarter of Walton County. It
covers an area of approximately 750 square miles. To the south the Reservation is adjacent to
Choctawhatchee Bay and the Gulf of Mexico, while to the north and east it is bordered roughly
by the Yellow River and Alaqua Creek.
The Reservation lies on generally level or gently rolling terrain, all under 300 feet elevation
and sloping to sea level on the west and south. It is drained by small tributaries of the Yellow
River and Alaqua Creek and by smaller streams that flow directly into Pensacola Bay and
Choctawhatchee Bay. The valleys of these streams often are steep sided and terminate abruptly.
The soil of most of the Reservation consists of somewhat excessively drained, deep, acid sands
of the Lakeland series. In the stream bottoms, and particularly along the Yellow River, the soils
are much more heavily organic.
b. Test Area C-52A
Test Area C-52A is located in the southeastern part of the Eglin Reservation. It covers
an area of approximately three square miles (Figure 1-1) and is a grassy plain surrounded by a
forest stand that is dominated by longleaf pine (Pjnus palustris). sand pine (Pinus clausa), and
10
�c 138
HARPSITE
TO C 106
A
B
C
D
E
QA LABORATORY
TEST GRID
300 FOOT TOWER
CONCRETE APRON
CONTROL TOWER
CONTRAVES
INACTIVE
ASKAN1A
SPOTTING TOWER
CONTROL
=—=
=
5,280 FEET
BLDG.
RAVED ROAD
CUtf R040
====
SAM) ROAD
O
TOWER
MTERAN6E BOUNDARr LINE
Figure 1-1. Map of Test Area C-52A, Eglin AFB Reservation, Florida
�turkey oak (Quercus laevis). The actual area for test operations which occupies an area of
two square miles, is a cleared area occupied mainly by broomsedge (Andropogon virginicus).
switchgrass (Panicum virgatum), and low growing grasses and herbs. Much of the center of the
range was established prior to 1960, but the open range as it presently exists was developed in
1961 and 1962.Figures l-2(a)and I-3 are aerial photographs of the one square mile test grid and
the immediate adjacent area as it appeared on 16 March 1971 and 14 June 1973, respectively.
The test grid is approximately 93 feet above sea level with a water table of six to ten feet. The
major portion of this test area is drained by five small creeks whose flow rates are influenced
by a 60.4-inch average annual rainfall (Table 1-1). The average temperature for the area is 64.9°F
(Table I-2). The average maximum and minimum temperatures (°F) by month for the test area
are shown in Table I-3. For the most part, the soil of the test grid is a fine white sand on the
surface changing to yellow beneath. The profile composition for a typical 3-foot soil core is
shown in Table I-4. The soils of the range are predominantly well drained, acid sands of the
Lakeland Association with 0 to 5% slope. Figure l-2(b) shows the location of the
Lakeland, Chipley, and Rutledge sand series of the Lakeland Association as found on the one
square mile grid. The Lakeland sand that covers most of the grid area forms excessively drained
thick deposits that extend to a depth of about seven feet. This sand is characteristically very dry,
even with 60 inches of annual rainfall. The Chipley sand is moderately well drained,and the
water table in this soil may rise to within 20 to 40 inches of the surface for three months during
the year. The Rutledge sand is poorly drained, strongly acid (pH 4.5 to 5.0) soil. The water
table in this sand is within ten inches of the surface for several months during the year.
2. DESCRIPTION OF THE TEST FACILITY
a. Description
Test Area C-52A, the southern most portion of the TA C-52 range complex, is a 3 square
mile cleared area on which a one square mile micrometerological and aerosol/particulate sampling
grid was located (Figure 1-1). Test Site C-1, on the western edge of TA C-52A, was the control
center for operation of the sampling instrumentation, grid support and test data assessment. Test
Site C-102 at TA C-52 Central, provided cinetheodolite time-space-position support and fixed and
mobile communications for TA C-52A mission aircraft control. This test area was closed January
1971.
b. Capabilities and Uses
Test Area C-52A was used for assessing the dissemination and deposition characteristics
of aerially delivered liquid and particulate materials from spray tanks and other systems of a
similar nature. Micrometeorological conditions existing below 300 feet over the test area were
continuously described by the Automatic Meteorological Data Acquisition and Processing
System (AMDAPS) which included wind, temperature, and dew point sensors on a 300-foot tower
at grid center and wind sensors on 12-foot masts located at each of the four corners of the one
square mile grid. A complex of defoliant-grids, intersecting near the central AMDAPS tower and
oriented to eight major compass headings, provided 16 discrete sampling grids which could be
selected for the most advantageous wind conditions prior to and during mission time. These
grids employed glass plates and Kromekote cards for physical collection of test materials in
droplet form. Each of the 250 permanent sampling stations of the TA C-52A basic grid array
employed a wide variety of sampling devices including the above but were also equipped with
individual commercial power and sequencing control lines for remote operation of automatic
vacuum type samples which collected small particle and aerosol test materials. These sampling
stations were arranged on 400-foot centers to form the one square mile grid (see sampling
station array in Figure I-4). Remotely controlled, battery operated, portable samplers were also
available to gather data in special purpose grid configurations anywhere in a 10 square mile area.
12
�(a) Photograph of the One Square Mile Grid Taken at 5,000 Feet Above Ground Level on 16 March 1971
Figure I-2. Test Area O52A
�'-:**. £ * '
>£$ 'A
i£%^
&
p.f\3 4 S 6 f'^9 l
y % *" '/
#"*•
^^/\
".
**. *
%
¥\v;
'%
LAKELAND SAND
* <\ v*
K> CHIP LEY SAND
* v *'/*
r*- <
'* *i * v/ • " t- YI *
\
f
%»\
t
RUTLEDGE SAND
* . '-*^ *,
'*•
,»
^V/
% »\V" 'f*->
',,j
*
(b) Soil Types of the One Square Mile Grid on Test Area C-52A
Figure 1-2. Concluded
14
�Figure 1-3. Photograph of the One Square Mile Grid Taken at 4,300 Feet Above
Ground Level on 14 June 1973
15
�TABLE 1-1.
ANNUAL TOTAL PRECIPITATION FOR EGLIN AFB AND
NICEVILLE, FLORIDA, FROM 1964 TO 1969
YEAR
PRECIPITATION, Inches
EGLIN AFB
NICEVILLE
1964
68.10
72.68
1965
61.85
65.29
1966
51.10
66.95
1967
62.76
73.05
1968
31.68
42.33
60.01
68.96
55.92
64.88
1969
3
Average
a
Average of the two locations is 60.40 inches
TABLE I-2. AVERAGE MONTHLY TEMPERATURES (°F) FOR FOUR YEARS AT
NICEVILLE, FLORIDA
YEAR
JAN
FEB
MAR
APR
MAY
JUN
JUL
AUG
SEP
OCT
NOV
DEC
1966
45.4
50.1
56.1
65.3
73.8
76.1
81.7
79.3
77.1
67.7
56.6
49.6
1967
49.4
48.9
60.8
70.6
72.2
79.2
78.7
72.4
63.5
55.2
56.8
65.4
1968
48.7
45.9
54.5
67.9
72.3
79.9
79.2
81.5
75.5
66.6
55.0
49.3
1969
49.8
52.0
52.1
66.9
73.2
80.5
81.2
78.1
75.2
69.6
54.5
49.2
Average3 48.3
49.2
55.9
67.7
72.9
78.9
80.2
78.3
72.8
64.8
55.7
53.4
3
Average temperature for 4 years is 64.9° F
16
�TABLE 1-3. AVERAGE MAXIMUM AND MINIMUM TEMPERATURES (°F) BY MONTH
FOR FOUR YEARS (1966 - 1969) TAKEN FROM THE SIX FOOT LEVEL
AT THE CENTER TOWER OF TEST AREA C-52A, EGLIN AFB, FLORIDA
MONTH8
TEMPERATURE, °F
MINIMUM
40.05
40.55
48.15
59.96
62.67
68.38
68.82
71.04
66.90
54.24
46.09
42.08
January
February
March
April
May
June
July
August
September
October
November
December
a
MAXIMUM
58.86
60.69
68.32
81.52
82.15
86.04
87.48
87.71
84.06
77.41
68.03
61.67
Average temperature for 4 years is 65.54°F
TABLE 1-4. SOIL PROFILE (6-INCH INCREMENTS) FOR TEST AREA C-52A, EGLIN
AFB RESERVATION, FLORIDA 8
DEPTH, Inches
CLAY, %
O.M., %b
C.E.C.C
SAND, %
SILT, %
1 -6
91.6
4.0
4.4
0.46
1.19
6- 12
90.1
4.3
5.6
0.20
0.81
12- 18
92.1
4.3
3.6
0.20
0.73
18- 24
92.9
3.5
3.6
0.00
0.69
24-30
93.1
2.8
4.1
0.07
0.69
30- 36
92.8
3.6
3.6
0.07
0.69
a
As determined by the Soils Department, University of Florida, Gainesville, Florida.
Soil sample taken within 50 feet of K-9 permanent sampling station.
'-'Percent organic matter.
C
C.E.C. (cation exchange capacity) is the ability of a cation to be displaced or exchanged
from the soil by another cation. The cation exchange capacity of a typical greenhouse
potting soil is 11.43. A soil with a cation exchange capacity of 1 can "bind" or "fix"
10 ppm of a given cation (s).
17
�2
O
A O
3
4
5
6
9
10
II
12
13
14
O
O
O
O
O
O
O
O
O
O
B
O
O
O
O
O
O
O
O
O
O
O
O
O
O
c
o
o
o
o
o
o
o
o
o
o
o
o
o
o
D
O
O
O
O
O
O
O
O
O
O
O
O
O
O
E
O
O
O
O
O
O
O
O
O
O
O
O
O
O
F
O
O
O
O
O
O
O
O
O
O
O
O
O
O
G
O
O
O
O
O
O
O
O
O
O
O
O
rv_i-_
O — 0-
1
T(
TR
400 FEET
H
O
O
O
O
O
O
O
O
O
O
O
O
O
J
O
O
O
O
O
O
O
O
O
O
O
O
O
O
K
O
O
O
O
O
O
O
O
O
O
O
O
O
O
L
O
O
O
O
O
O
O
O
O
O
O
O
O
O
M
O
O
O
O
O
O
O
O
O
O
O
O
O
O
N
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
O
500
1000
1500
2000
GRAPHIC SCALE-FEET
Figure 1-4. Location of the Permanent Sampling Stations on the One Square
Mile Grid
18
�Fixed and portable illuminated flight line markers were available for missions during hours of
darkness. A Quantitative Assessment Laboratory facility, collocated with the Test Site C-1
control center, received the collected samples and performed appropriate chemical analysis or
biological assays providing data for assessment of test item performance. Micrometeorological
data from TA C-52A was both recorded at the AM DAPS master station located at Test Site C-1
and transmitted to the main base Staff Meteorologist Control Center, Eglin AFB, via teletype
on a 24-hour basis.
3. DESCRIPTIONS OF SAMPLING GRIDS AND HERBICIDE DEPOSITION
Descriptions of the sampling grids located on TA C-52A and individual mission data including
herbicide and total gallons sprayed have been compiled by Biever .
a. Grid Descriptions
Figure I-5 shows the location of the various herbicide grids that were located on TA C-52A.
The original sampling grid (Grid!) for spray equipment testing became operational in June 1962.
It consisted of four intersecting straight lines in a circular pattern, each line being at a 45° angle
from those adjacent to it. This grid was discontinued after two years. It was located immediately
south of the one square mile grid.
The second sampling grid (Grid 2) consisted of three parallel lines intersected at right angles
by another set of three parallel lines. These lines were 800 feet apart, thus forming four equal
quadrants. The southwest corner of this grid corresponded to the southwest corner of the one
square mile grid. The parallel line grid was operational during the period May 1964 to November
1965.
The third sampling grid (Grid3) consisted of three concentric circles, with respective
diameters of 1200, 1600, and 2000 feet. This grid was located in the northeast quadrant of
the one square mile grid. The concentric circles grid was operational between October 1967 and
April 1968; however, difficulty in interpreting data from this sampling array caused use of this
grid to be discontinued.
The fourth sampling grid (Grid 4) is a one square mile grid, the center of which was marked
by a 300-foot tower. This was the last testing grid used on TA C-52A and its inwind and crosswind sampling arrays extended into Grid 2 and Grid 3. Figures I-6, I-7, I-8, and I-9 show various
views of Grid 4 at the time the grid was under construction.
The two inwind and four crosswind sampling arrays of Grid 4 became operational in
May 1968. Each inwind array consisted of three parallel rows spaced 400 feet apart, with 297
sampling stations per row. The aircraft flight path crossed the midpoints of the sampling lines.
The crosswind sampling arrays consisted of three parallel rows 400 feet apart, with 253 sampling
stations per row.
b. Deposition Rate
The total amounts of chemicals (including herbicides, insecticides, oils, and simulants)
applied to TA C-52A are shown in Table I-5. All of these materials were disseminated during
the period from June 1962 to December 1970 (Figure 1-10). The total pounds of actual herbicides
^Defoliant History of Test Area C-52A, Working Papers, Vitro Corporation of America and
Armament Development and Test Center, Eglin AFB, Florida, December 1969.
19
�1
A *
2
•
3
•
4
•
5
•
6
•
7
•
8
•
* UOO feet
400 feet
Boundary of major aircraft
flight paths over grid
Boundary of minor aircraft
flight paths over grid
Grid Boundary
2000 feet
Figure 1-5. Location of Test Grids and Major Flight Paths Used during Dissemination
of Herbicides Over Test Area C-52A
20
�Figure 1-6. A View of Grid/Number 4 Looking from the Southeast to the Northwest,
1964
Figure 1-7. A View of Grid Number 4 Looking from East to West, 1964
21
�Figure 1-8. A View of Grid Number 4 Looking from North to South, 1964
Figure I-9. A View of the Western Portion of Grid Number 4 Looking from the
Southeast to the Northwest, 1964
22
�14,000 '
C=3 PURPLE
rUH FUEL OIL
•
• ORANGE
nnnni WHITE
10,000
-
ECS BLUE
-
c
_o
j? 6,000
-
Ul
-
5
.
-
O
^
2,000
3
p
3
1
-
1962
/
a_ ilJa_
.1
63 64 65 66 67 68
^
/
69
70
YEAR
Figure 1-10. Annual Dissemination of Herbicides on Eglin AFB Test Area C-52A
•
deposited on the test area (total of all grids) is shown in Table I-6. The approximate
deposition rate of herbicides, pounds active ingredient per acre, for each grid is shown in
Table I-7.
4. DESCRIPTION OF PESTICIDES
As closely as possible the equipment utilized on TA C-52A was tested under realistic yet
controlled conditions. Most testing programs involving military herbicides and insecticides
actually included the pesticides themselves rather than simulants. The low toxicity associated
with these pesticides was the salient justification for such action.
4
a. Orange
Orange was a reddish-brown to tan colored liquid soluble in diesel fuel and organic solvents, but insoluble in water. One gallon of Orange contained 4.21 pounds of the active ingredient
of 2,4-dichlorophenoxyacetic acid (2,4-D) and 4.41 pounds of the active ingredient of 2,4,5trichlorophenoxyacetic acid (2,4,5-T). Orange was formulated to contain a 50:50 mixture of the
n-butyl esters of 2,4-D and 2,4,5-T. The percentages of the formulation were:
n-butyl ester of 2,4-D
free acid of 2,4-D
n-butyl ester of 2,4,5-T
free acid of 2,4,5-T
inert ingredients (e.g., butyl
alcohol and ester moieties)
49.49%
0.13%
48.75%
1.00%
0.62%
Some of the physical, chemical, and toxicological properties of Orange are listed in Table I-8.
23
�TABLE 1-5. APPROXIMATE TOTAL VOLUME OF HERBICIDES,
INSECTICIDES, AND/OR SIMULANTS APPLIED TO
TEST AREA C-52A, EGLIN AFB RESERVATION,
FLORIDA, 1962- 1970
CHEMICAL
GALLONS DISSEMINATED
19,807
Orange
Purple3
White
Blue
Stull Bifluidb
Fuel Oil
Orange Simulant0
Malathion Insecticide
16,164
4,172
4,395
1,716
10,863
1,460
215
Total
58,792
a
Purple was a mixture of n-butyl 2,4-D (50%), n-butyl 2,4,5-T (30%), and isobutyl
2,4,5-T (20%). The isobutyl portion was included as a measure to depress the
freezing point of 2,4,5-T. This mixture was eventually replaced by Orange.
"Stull Bifluid consisted of Orange (85%) plus a chemical additive, which when mixed
in the spray system pump during agent dissemination produced a gel defoliant.
C
0range simulant consisted of glycerine (68%), sodium thiosulfate (16.8%), and
water (15.2%).
TABLE I-6. TOTAL POUNDS OF ACTIVE INGREDIENTS OF HERBICIDES
DISSEMINATED ON TEST AREA C-52A, EGLIN AFB RESERVATION,
FLORIDA, JUNE 1962 - DECEMBER 1970
HERBICIDE
POUNDS ACTIVE INGREDIENT
2,4-D
169,292
2,4,5-T
160,948
Picloram
2,253
13,624
Cacodylic Acid and
Sodium Cacodylate
24
�TABLE 1-7. APPROXIMATE DEPOSITION RATE OF HERBICIDES APPLIED TO TEST AREA C-52A,
EGLIN AFB RESERVATION, FLORIDA
TEST
GRID 3
1
GRID
AREA b ,
Acres
92
HERBICIDE (POUNDS ACTIVE INGREDIENT/ACRE)
2
584
(1964-1966)
3
92
30
(1967)
4
CJ7
92
240
183
(1968-1969)
PICLORAM
CACODYLIC ACID
8
(1967)
2,4-D
2,4,5-T
947
947
( 1962-1 964)d (1962-1964)
11
(1968)
6
(1969-1970)
53
(1969-1970)
ARSENIC 0
584
(1964-1966)
160
(1968-1969)
6
28
a
The test grids are described in text
^In actuality, grids 2 and 3 fall within the confines of the 640 acre grid 4. However, the positioning of the test arrays on
grid 4 has resulted in most of the herbicide being disseminated within a 240 acre area, with only slight infringement on the
original sites of grids 2 and 3.
°Pounds per acre of arsenic as the organic pentavalent form; calculated on weight of Blue applied per acre.
°Years when the majority of the herbicide was applied.
�TABLE 1-8. PHYSICAL, CHEMICAL, AND TOXICOLOGICAL PROPERTIES OF THE THREE MAJOR
HERBICIDES AND ONE MAJOR INSECTICIDE
CHEMICAL
SPECIFIC
DENSITY
(25C)a
VJSCOSITY
CENTIPOISE
(23C)
MOLECULAR
MASS
WEIGHT OF
FORMULATION
(Ibs/gal)
SOLUBLE
WEIGHT
ACTIVE
IN
INGREDIENT
WATER
(Ibs/gal)
RELATIVE SPECIFIC
TOXICITY TOXICITY
FOR WHITE
RATS
(mg/kg)
Orange
1.282
43
618
10.7
8.62
No
Low
White
1.120
125
1,173
9.4
2.54
Yes
Very Low
3,080
Blue
1.324
14
296
10.9
3.10
Yes
Very Low
2,600
Malathion
1.232
36
328
10.3
9.74
No
Low
1,375
NJ
a
As determined by the Air Force Armament Laboratory
566
�b. White
White was a dark brown, viscous liquid that was soluble in water but insoluble in organic
solvents and diesel fuel. One gallon of White contained 0.54 pound of the active ingredient of
4-amino-3,5,6-trichloropicolinic acid (picloram) and 2.00 pounds of the active ingredient of 2,4-D.
White was formulated to contain a 1:4 mixture of the triisopropanolamine salts of picloram and
2,4-D. The percentages of the formulation were:
triisopropanolamine salt of picloram
triisopropanolamine salt of 2,4-D
inert ingredient (primarily the
solvent triisopropanolamine)
10.2%
39.6%
50.2%
Some of the physical, chemical, and toxicological properties of White are listed in Table I-8.
c. Blue
Blue was a clear yellowish-tan liquid that was soluble in water, but insoluble in organic
solvents and diesel fuel. One gallon of Blue contained 3.10 pounds of the active ingredient
dimethylarsinic acid (cacodylic acid). Blue was formulated to contain both cacodylic acid
(as the free acid) and the sodium salt of cacodylic acid (sodium cacodylate). The percentages
of the formulation were:
cacodylic acid
sodium cacodylate
surfactant
sodium chloride
water
antifoam agent
4.7%
26.4%
3.4%
5.5%
59.5%
0.5%
Some of the physical, chemical, and toxicological properties of Blue are listed in Table I-8.
It should be noted that cacodylic acid and sodium cacodylate contain arsenic in the form of
the pentavalent, organic arsenical. This form of arsenic is essentially nontoxic to animals as
can be noted by the LD§Q value for white rats. Of the total formulation, 15.4% is arsenic
in the organic form, only trace quantities are present in the inorganic (toxic) form.
d. Malathion
Malathion insecticide (0,0-dimethyphosphorodithioate) was a clear brown to colorless
liquid withia slight characteristic odor. The ultra-low-volume (ULV) formulation was very
slightly soluble in water (145 ppmw). Malathion ULV had a minimum purity of 95%. One
gallon of ULV malathion contained 9.74 pounds active ingredient and 0.51 pound inert ingredients.
Some of the physical, chemical, and toxicological properties of malathion are listed in Table I-8.
27
�SECTION II
BIOASSAY AND CHEMICAL RESIDUE STUDIES
OF THE SOILS OF TEST AREA C-52A
From the rates that were applied during the years of testing spray equipment, it was obvious
that Test Area C-52A at Eglin AFB Reservation offered a unique opportunity to study herbicidal
persistence and soil leaching. Yet, the problem of how best to assess the level of residue was a
difficult one. The herbicides could be chemically present but because of soil binding might not
be biologically active. Moreover, as noted in Section I, many chemicals were applied to the test
area, and a biological assessment might be the result of two or more chemicals interacting. Thus,
both bioassay techniques and analytical analysis were employed. The results of the bioassay studies
by A. L. Young and J. H. Hunter have not been published; however, the methodology developed and
the results obtained have played a major role in understanding the ecological succession of the plant
and animal communities on the test area. Thus, a detailed synopsis of their work is included in
this report.
1. SYNOPSIS OF BIOASSAY RESEARCH, 1969 - 1970
In the late summer of 1969, six 5-foot cores were randomly collected from an area known to
intersect spray flight paths used for missions involving the herbicide designated as Orange. The
samples were taken to the laboratory and subsampled for bioassay and analytical results. The
bioassay technique employed the use of soybean (variety Clarke 63) for detecting phenoxy-herbicide
residue. The experiments were conducted under greenhouse conditions. No standard herbicide
concentrations were included; instead, cores from treated areas were compared to control cores
and the relative differences noted. Comparisons for each depth were made against control plants
for the particular depth.
These initial bioassay studies indicated two things. First, significant concentrations of herbicides
(or phytotoxic materials) were present on the test grid; and second, these herbicides were definitely
leaching or penetrating into the soil (at least to a depth of 3 feet). Moreover, the bioassay analysis
indicated different relative concentrations of herbicides both between cores and within a given core.
As noted earlier, the area of interest was an area greater than one square mile. Obviously,
this area was too large to completely bioassay or to subject to chemical analyses. Therefore, it was
decided to find the areas of greatest herbicide concentration and follow up with detailed bioassay
and chemical analyses. To find these specific areas, it was necessary to design an experiment that
would allow inferences about herbicidal persistence for the entire test area. Consulting statisticians
assisted in designing the experiment and in analyzing the results.
In order to properly evaluate herbicidal persistence and soil leaching, a vegetation chart of the
test grid was prepared on 26 March 1970. The greatest amounts of vegetation were found near the
water sources of the grid. There were two areas that supported very dense vegetation. A terracing
effect of diminishing amounts of vegetation away from these two areas was apparent. The effects
of repeated spray could be seen along the flightpaths most frequently used in test programs. In
these strips, vegetation occurred only near the water sources and even there it was scant. By considering the flightpaths, the water sources, and the terracing effects, it was possible to divide the
test grid into 16 vegetation areas. These areas formed the base for the random selection of soil
samples. The statistical null hypotheses that were to be investigated included the following:
1. There were no herbicide concentration differences among the soils of the various
vegetative areas.
28
�2. There were no differences in herbicide content among soil depths down to 3 feet.
3. There were no interactions between the vegetative areas and the soil depths.
In order to conduct an experiment that would provide reliable evidence with respect to these
hypotheses, three random 3 foot soil cores were taken from each of the vegetative units and three
from a control area, an area 0.2 mile northwest of the square mile grid. Figure 11-1 shows the sites
for the random sampling of these soil cores. These cores provided the replication for the experiment. Because of the time involved in taking the soil cores and the possible effects of the soil
drying out if left unplanted for several days, it was necessary to apply the technique of blocking
over the days of soil core removal and planting. The experiment was initiated 1 April 1970. Again
the bioassay organism was soybean (five seeds per cup and one cup per 6 inch increment of soil
core), and the experiment was conducted in a greenhouse.
A series of standards for herbicide Orange was included in this experiment (range of standards
was 0.25 to 4.00 ppm Orange). All standards were prepared in soil taken from the top 6 inch
increment of control soil. The results indicated that therewereherbicidal persistence and leaching;
of the 48 treatment cores collected and bioassayed, 27 cores were significantly different from control
cores (95% probability level). The results indicated that soil leaching or penetration was much more
prevalent along the dissemination flightpaths than in other areas of the test grid. Moreover, there
were differences among the soils of the various vegetative areas within a given flightpath. Likewise,
differences were found in herbicide content among the increments of many of the soil cores. This
was probably due to both the elapsed time since herbicide application and to such factors as
rainfall frequency and organic matter content of the soil. It is interesting to note that there were
no statistical evidences of differences between wet and dry soils that received approximately the
same amounts of herbicide. Efforts to quantitate the bioassay were confined to only the top 6
inch increment because of within-core variations. By considering that all phytotoxic effects were
from Orange, the approximate concentration was 2.82 ppm herbicide. This was an average value
for the top 6 inches of soil core for the eight cores showing greatest herbicide concentration.
In reference to the statistical null hypothesis, all three were rejected: (1) there were differences
in herbicide concentration between cores; (2) there were differences in herbicide content within cores;
and, (3) there were interactions between the sampling areas and the soil depths (this indicated nonuniformity in soil strata).
Sixteen of the soil cores (one from each vegetation type) were subsampled for arsenic concentration (hence, a measure of Blue). The arsenic was extracted by a cold-acid extraction technique and analyzed by atomic absorption spectrophotometry. Four of the 16 locations contained
arsenic levels above 1.0 ppm in the top 6 inches of soil. A further analysis for arsenic in the
soil profile indicated that arsenic readily (and almost uniformly) leached throughout the soil profile.
In areas receiving repetitive applications of Blue, the top 6 inches of soil contained arsenic levels
of 1.4 ppm, and the additional 6 inch increments down to 5 feet contained from 0.70 to 1.2 ppm
arsenic.
From the bioassay study, it was evident that some areas of the test grid contained high levels
of phytohormonal herbicide residue (i.e., residue showing plant responses similar to those caused
by 2,4-D; 2,4,5-T; and picloram). Thus, 5 foot cores were collected from two areas (dry soils)
exhibiting highest herbicide residue. Each core was divided into 6 inch increments, placed in
amber bottles, and immediately shipped to the United States Department of Agriculture, Pesticide
Degradation Laboratory, Beltsville, Maryland, for analysis of 2,3,7,8-tetrachloro-dibenzo-p-dioxin
(TCDD). No TCDD was found in either soil core (the Pesticide .Degradation Laboratory reported
a detection limit capability of 0.0005 ppm TCDD).
29
�f
B
F
G
H
J
K
M
N
1
2
3
8
4
9
10
11
12
Figure 11-1. Collection Sites for the Random Sampling of 3 Foot Soil Cores
For Residue Analyses
30
13
14
�2. SYNOPSIS OF BIOASSAY RESEARCH, 1970 - 1971
a. Introduction
A follow-up bioassay experiment of six of the field locations studied in the previous bioassay
experiments was initiated in December 1970. Three of the samples were selected because they
showed leaching to a depth of 36 inches, two because of leaching to 30 inches, and the remaining
sample because of leaching to 18 inches. In addition, two samples were obtained from grid 1
(the 1962 - 1964 grid). These samples had not been previously bioassayed, but because of prior
history, it was expected that data on persistence could be obtained from both a bioassay and a
chemical analysis.
Since the preliminary work indicated that although equal amounts of Orange were introduced
into soil cores, the varying organic composition of the soil at different depths influenced the amount
of Orange available to the plants. This investigation attempted to determine if differences in amounts
of herbicides and in soil composition do affect plant growth and, if so, the magnitude of this effect.
This information was then used to estimate the concentration of Orange in the selected sites.
b. Method and Materials
In order to calculate the effects of herbicide concentration upon plant growth and to
study the effects of soil depth on herbicide activity, a soil core was taken from a control site 0.2
mile northwest of the one square mile test area. This core was collected in 6 inch depth segments
down to 3 feet. After being dried, sieved, and weighed, each depth-segment unit was divided into
seven parts and treated so that soil samples from each unit contained the following concentrations
of Orange: 0.028 part per million (ppm), 0.057 ppm, 0.113 ppm, 0.226 ppm, 0.454 ppm, and
0.908 ppm; one soil unit was not treated and so had 0.0 ppm concentration of Orange. These
soil samples were then used as standards.
Each of these samples was thoroughly mixed and distributed among six cups. Five soybean
seeds were planted in each of three of the cups and five cucumber seeds were planted in each of
the remaining three cups for each concentration. All bioassays were conducted in an ISCO E-3
environmental chamber maintained at a diurnal temperature regime of 90° to 70°F, a diurnal
humidity regime of 65% to 85%, and a 14-hour daylength. The length of the cucumber plants from
the root tip to the end of the epicotyl was measured after 6 days. The soybeans were harvested
10 days after planting, and the root length of each plant was recorded.
Samples of soil were also collected from six selected sites on the test grid. These locations
were coded using the coordinate of the grid marker and the direction with respect to that marker
in which the cores were taken. These six locations were B-14 SW, C-9 SW, J-3 NE, M-8 SW,
N-12 NW, and 0-7 NE. A composite of three soil cores, 2-1/2 feet apart, was collected from each
site at a distance 50 feet from the designated grid marker and on an imaginary line perpendicular
to the specified direction for sampling. These cores were collected in 6-inch segments down to
3 feet, and the soil from the corresponding depth segments for each of the three cores collected
from a specified site were throughly mixed. A control soil sample was collected in a similar manner
from the same location that the soil for the standards was taken. The soil from each site/depth
segment-unit was distributed among six cups and a bioassay was conducted in the same manner as
that described above for the Orange concentration standards. Again both cucumber and soybeans
were used as the test organisms.
This same procedure was used to collect and bioassay soil samples from sites 50 yards
south of grid markers O-5 and 0-8 which are on the southern border of the present test area (and
in the old grid 1 area). Control soil was collected for this bioassay also from the same site as the
other controls and the standards, and soybeans and cucumbers were used as the test organisms.
31
�In addition, soil samples from many locations on the test grid were collected and analyzed for
organic matter content. Samples were analyzed by the use of a muffle furnace (total combustion
of organic matter).
c. Statistical Methods
General. Except as noted, statistical analyses were conducted to test for significant
differences at the 0.95 probability level. If a significant difference was indicated at this level,
further testing was conducted at the 0.99 probability level.
Wide variations .occurred among the measurements of the plants within the
individual cups. The seeds actually belonged to two populations: (1) those seeds that would
germinate under proper conditions and (2) those seeds that would not germinate. It was impossible
to determine which population an individual seed belong to in all cases, and the extreme values
(zero length when a seed did not germinate) would have biased the results had the arithmetic mean
been used as a representative cup value. Therefore, the median measurement of the plants within
a cup was used as the cup value, and the cup became the experimental unit.
Calibration of Standards. An analysis of variance (ANOVA) technique was employed to
study the effects upon the plants grown in the soils treated with the standard concentrations of
the defoliant Orange. This was done to determine those concentrations which affected plant
growth in a significantly different manner. Also, it was hypothesized that because of soil composition variations with depth, a different percentage of the applied defoliant would be bound to
the soil or in other ways unavailable to the plants. If this were the case, different standard curves
would have to be developed for each depth group.
A test for homoscedasticity indicated unacceptable differences in variances. The
transformation:
x = Iog10 (x' + 1)
Where :
x = the transformed data
x' = the original cup value
provided homogeneity of variance.
Both the concentration levels and the depth increments were arbitrarily selected
and thus are parametric factors. Since each corresponding site/depth-segment was treated alike,
the experiment has a cross-classified design, and the statistical model can be expressed:
Yijk = a + c, + dj + (cd)jj + e jjk
Where:
a = the overall effect
Cj = the effect of the itn concentration (i = 1,2,...,m)
dj = the effect of the jtn depth-segment (j = 1,2,...,n)
32
�Gjjk = the error factor for the ktn replicate of the itn concentration and the jtn
depth-segment
yp = the cup value for the ktn replication of the itn concentration and the jtn
depth-segment
The ANOVA technique employed was based on this model. In each instance that a significant
difference was indicated between the levels of a factor or when a significant interaction was
indicated, Duncan's new multiple range test was used to separate the levels into homogenous groups.
A mathematical expression of the form
y = a + bx
which approximated the relationship between the defoliant concentration and the cup value was
determined for each homogenous group by the method of least squares. To find such a relationship a correlation study was undertaken which compared the standard data and square root and
logarithm transformations of both the concentration and cup values. Once the proper form of the
data was selected, regression analysis was used to study the mathematical expressions. This
included tests of the following hypotheses:
(1) The data does not fit the curve (lack of fit test).
(2) One regression line can be used for all the depth groups.
(3) The regression coefficients for the different depth groups are equal.
(4) If all the regression coefficients are equal, the elevations (Y-intercepts) are equal.
Analysis of the Grid Samples. The concentration of Orange present in the soil from each
site/depth-segment taken from the testing area was estimated by using the calibration curves
developed for the standard concentrations. The bioassay of the standard Orange concentrations
and the bioassay of the grid soil samples were done at different times; therefore, an adjustment of
the data was necessary to eliminate the bias and confounding introduced by this procedure. Since
control plants were grown with each group, the grid soil bioassay data was weighted according to
the ratio of the average of the controls for the test area data to the average of the zero standard
concentration data. (A paired-observations t-test of these groups indicated they were significantly
different at the 0.95 probability level.)
3. RESULTS AND DISCUSSION
a. Calibration of Standard Curves
The results of the ANOVA was the same for both soybeans and cJcumbers. The interaction
effect between concentration and depth-segments was non-significant; therefore, this effect was
pooled with the residual term. The effects of both concentration and depth were highly significant
(at a probability level greater than 0.99). These ANOVA tables are presented in Table 11-1 along
with the means and the results of Duncan's new multiple range tests.
The multiple range tests indicated that for both soybeans and cucumbers each concentration
level was significantly different from every other concentration level, and the range of the standard
curve could include all the concentration levels tested, i.e., from 0.0 ppm to 0.908 ppm. The
33
�TABLE 11-1. ANALYSIS OF VARIANCE.- ORANGE STANDARDS
Concentration
6
5.3013
0.8836
152.343
3.0419
0.5070
144.869
Depth
5
0.6875
0.1375
23.71a
0.7185
0.1437
41.069
30
0.1195
0.0040
0.1620
0.0054
1.93
Residual
84
0.5389
0.0064
0.2314
0.0028
Adj Error
114
0.6584
0.0058
0.3934
0.0035
Cone, x Depth
---
Indicates significance at the 0.99 probability level.
DUNCAN'S NEW MULTIPLE RANGE TEST
Soybean Data Results Cone. Mean Values:
1.06
0.97 0.92 0.80 0.73 0.59 0.43
Depth Mean Values:
0.85 0.78 0.74 0.71
0.91
0.70
Cucumber Data Results Cone. Mean Values:
1.17
1.04 0.99 0.93 0.83 0.75
Depth Mean Values:
0.93 0.91 0.87 0.85
1.07
0.69
0.85
Note: Common underscoring indicates homogenous groups at 0.95 probability level.
depth-segment groupings for soybeans were somewhat different that those for cucumbers. At the
0.95 probability level, three distinct depth groups were indicated from the cucumber data set.
The groupings indicated by the soybean data set were not as clearcut, and the 18 to 24 inch
depth-segment could be placed into two different groups. Since the cucumber data set indicated
that this depth-segment should be placed in the last (deepest) depth group, a similar decision was
made in the case of the soybean data. These depth groupings are as follows:
Depth, inches
Group
Cucumber
Soybean
I
0 to 6
0 to 6
II
6 to 18
6 to 12
III
18 to 36
12 to 18
IV
---
18 to 36
In the correlation analysis, the necessity for transformation of both the Orange concentration
values and cup values were studied. In addition to the untransformed data, square root and
logarithmic transformations were included. The correlation matrices for both the soybean and the
cucumber data sets are presented in Table II-2. In both cases, the best correlation (soybeans:
-0.8896; cucumbers: -0.8335) was
logiQ(cup value + 1) x
vconcen1:ration (PPm)
34
�TABLE 11-2. CORRELATION MATRICES
CUP VALUES
CONCENTRATION (ppm)
NO TRANS
LOGin(x+y)
SQUARE ROOT
No Trans:
-0.7423
-0.7761
-0.9353
Log10(x+y)
-0.8405
-0.8637
-0.8896
Square Root
-0.8085
-0.8363
-0.8758
No Trans:
-0.6547
-0.6908
-0.7703
Log10(x+y)
-0.7399
-0.7728
-0.8335
Square Root
-0.7049
-0.7385
-0.8094
SOYBEAN DATA
CUCUMBER DATA
The method of least squares was used to determine the best fitting linear expression of
the relationship between these two transformations for each of the four depth groups identified
for the soybean standards and the three depth groups identified for the cucumber standards.
These preliminary mathematical equations along with the square root of the percent of deviations
from the mean explained by the regression equation (correlation coefficient) are presented in
Table II-3.
TABLE II-3. PRELIMINARY MATHEMATICAL RELATIONSHIPS FOR
STANDARD CONCENTRATIONS
CORR: COEFF.
DEPTH, in.
REGRESSION EQUATION
I
0 to 6
Y = 1.15- 0.59X
0.86
II
6 to 12
Y = 1.11 - 0.64X
0.86
III
12 to 18
Y = 1.06 - 0.69X
0.98
IV
18 to 36
Y = 1.01 - 0.72X
0.98
GROUP
SOYBEAN DATA
CUCUMBER DATA
I
0 to 6
Y = 1.27 - 0.49X
0.86
II
6 to 18
Y = 1.13- 0.52X
0.87
III
18 to 36
Y = 1.06 - 0.50X
0.92
Where:
Y = lo 3^rj(cup value + 1)
x-
2
\concentration
35
�F-tests were employed to further analyze these results as follows:
Hypothesis Tested
Soy Bean Data
(1) The data does not fit the curve:
Depth Group I
Depth Group II
Depth Group III
Depth Group IV
F-Value
Cucumber Data
a
55.49
353.92
a
420.24
a
1,184.46
(2) One regression equation can represent
all depth groups
a
58.14
271.84
a
320.00
a
a
11.26
(3) All the regression coefficients are equal
14.00
0.98
a
(4) The elevations are equal
a
28.39
0.04
a
36.82
Indicates significant at the 0.99 probability level; hypothesis rejected.
Except for the hypothesis that all the regression coefficients are equal (which was not rejected),
these hypotheses were rejected at the 0.99 probability level for both the soybean and cucumber
data sets. Thus within each data set, the slope of the regression equations for the different
depth groups is equal. However, rejection of the last hypothesis indicates that the intercept for
each depth group is different. A common regression coefficient was computed for each data
set, and the final equations are as follows: (These equations are plotted in Figures II-2 and II-3).
Depth Group
Regression Equation for Root Lengths
Soybeans
Cucumbers
I
Y = 1.18467 - 0.68076-X
Y = 1.27936 - 0.50374-X
II
Y = 1.12705 - 0.68076-X
Y = 1.12775 - 0.50374-X
III
Y = 1.05610 - 0.68076-X
Y = 1.06402 - 0.50374-X
IV
Y = 0.99721 - 0.68076-X
Where:
Y = log-|Q(cup value + 1)
2
X = >/ concentration Tppm)
and
0.0 <X < VO908
b. Analysis of Grid Samples
Using the relationships expressed in the previous paragraph, estimates were made of the
concentration of herbicide Orange in the soil samples taken from the defoliant testing area. These
estimates along with the limits of the 95% confidence intervals are presented in Table II-4.
Analysis for organic matter content are presented in Table II-5. A comparison of organic
matter content within selected cases is presented in Table II-6.
36
�DEPTH
GROUP 1
O)
o
(0
c
(Q
E
o
z
UJ
ORANGE
(ppm)
Trans.:
Figure II-2. Concentration Calibration Curves for Soybean Bioassay [see text for
description of depth groups]
37
�DEPTH
GROUP 1
O)
o
O.9
(0
c
CO
0.7
E
u
*
0.5
O
z
UJ
0.3
0.
0.8
ORANGE
(ppm)
Trans. =
Figure II-3. Concentration Calibration Curves for Cucumber Bioassay [see text for
description of depth groups]
38
�TABLE 11-4. CONCENTRATION ESTIMATES OF ORANGE AND 95%
CONFIDENCE INTERVAL LIMITS VIA BIOASSAY ANALYSES
Cucumber Data
Soybean Data
Site
Depth
Segment
Lower
Limit
Concentration
Estimate (ppm)
Unper
Limit
Lower
Limit
B-14
1
0.0000
.0113
.1638
0.0000
.0032
.1526
B-14
2
0.0000
.0730
.3413
0.0000
0.0000
.0358
B-14
3
0.0000
.0138
.0593
0.0000
0.0000
.0363
B-14
4
.0003
.0130
.0450
0.0000
0.0000
.0344
B-14
5
.0012
.0175
.0528
0.0000
0.0000
.0341
B-14
6
.0148
.0475
.0987
0.0000
.0000
.0341
C-9
1
.0693
.3034
.7030
.0087
.1652
.5183
C-9
2
.0535
.2975
.7389
0.0000
.0161
.0932
C-9
3
.0765
.1579
.2684
0.0000
.0079
.0723
C-9
4
.0344
.0791
.1420
0.0000
0.0000
.0333
C-9
5
.0344
.0791
.1420
0.0000
0.0000
.0326
C-9
6
.0293
.0712
.1315
0.0000
.0003
.0389
,1-3
1
.0814
.3297
.7447
.0136
.1851
.5532
.1-3
2
.0214
.2094
.5912
0.0000
.0050
.0632
J-3
3
.0263
.0805
.1645
0.0000
.0025
.0540
.1-3
4
.0057
.0297
.0725
0.0000
0.0000
.0391
J-3
5
0.0000
.0017
.0196
0.0000
0.0000
.0387
J-3
6
0.0000
0.0000
.0105
0.0000
0.0000
.0393
M-8
1
.0814
.3297
.7447
.0017
.1260
.4473
M-8
2
.0222
.2120
.5957
0.0000
.0032
.0567
M-8
3
.0700
.1485
.2562
0.0000
..0098
.0778
M-8
4
.0367
.0824
.1464
0.0000
0.0000
.0331
39
Concentration Upper
Estimate (ppm) Limit
�TABLE 11-4. CONCLUDED
Cucumber Data
Soybean Data
Site
Depth
Segment
M- 8
5
Lower
Limit
.47
07
M- 8
6
.0426
.0911
N-12
1
•0814
.3297
.7447
N-12
2
•0183
.1993
5738
0.0000
.0044
. 6 3
0 1
N-12
3
•°567
-1289
.2304
0.0000
.0039
.0594
N-12
4
•0691
.1282
.2054
0.0000
.0005
.0406
N-12
5
.0985
.1672
.2540
0.0000
0.0000
.0339
N-12
6
•0593
.1147
.1883
0.0000
0.0000
.0326
0- 7
1
•°169
-1718
.4885
0033
.1377
.4689
0- 7
2
•°183
-19"
.5738
0.0000
.0111
.0812
0- 7
3
.0441
.1097
.2046
0.0000
.0262
.1151
0- 7
4
•0344
. 7 1
0 9
.1420
0.0000
.0022
.0507
0- 7
5
.0247
.0640
A217
0.0000
.0007
.0423
0- 7
6
•0293
.0712
<1315
0.0000
0.0000
.0326
0- 5
1
0.0000
.0321
.0184
.2020
.5826
0- 5
2
0.0000
.Oi96
0.0000
.0209
. 0 0
1 4
0- 5
3
0.0000
.ooio
.0259
.0025
.0508
. 6 5
1 0
0- 5
4
0.0000
. 0 8
0 1
.0202
000
.00
.06
02
.56
02
0- 5
5
o.oooo
.0102
0.0000
.0116
.0806
0- 5
6
0.0000
.0012
.0180
0.0000
.0252
.1110
0- 8
1
0.0000
.0249
.2040
0.0000
.0047
.1611
0- 8
2
0.0000
.0029
.1489
0.0000
0.0000
.0385
0- 8
3
o.oooo
0.0ooo
.0178
0.0000
0.0000
.0347
0- 8
4
000
.00
o.oooo
. 1 3
0 0
0.0000
0.0000
.0369
0- 8
5
o.oooo
o.oooo
,0103
0.0000
0.0000
.0370
0- 8
6
0.0000
.0007
. 1 0
0 6
0.0000
0.0000
.9354
Concentration
Upper
Estimate (ppm) Limit
.95
08
<1675
157g
.2225
>2142
o.oooo
40
Lower
Limit
Concentration
Upper
Estimate (ppm) Limit
000
.00
000
.00
.33
04
0.0000
0.0000
-0330
.0005
.1136
.4243
�TABLE 11-5. PERCENT ORGANIC MATTER OF SOIL FROM TEST AREA C-52A
[Samples Collected between December 1970 and June 1971]
SAMPLE
A-11
B-8
B-14
C-11
D-7
E-3
E-6
F-12
J-1
L-10
N-5
N-8
N-12
0-2
CONTROL (0.2 mile NW of grid)
C-9
C-9
C-9
C-9
C-9
C-9
G-11
G-11
G-11
G-11
G-11
0-7
0-7
0-7
0-7
0-7
0-7
CONTROL (0.2 mile NW of grid)
a
DEPTH, Inches
0-6
0-6
0-6
0-6
0-6
0-6
0-6
0-6
0-6
0-6
0-6
0-6
0-6
0-6
0-6
0-6
6-12
12-18
18-24
24-30
30-36
0-6
6-12
12-18
18-24
24-30
0-6
6-12
12-18
18-24
24-30
30-36
0-6
6-12
12-18
18-24
24-30
30-36
ORGANIC MATTER'
0.68°
1.05a
1.13a
0.55a
0.87a
0.73b
0.37b
1.31a
0.85a
0.68b
0.76a
0.41b
0.72a
0.45b
1.25b 1.99
0.96
0.71
0.72
0.67
0.87
0.41
1.65b 1.99
1.04
1.61
1.49
1.06
0.57
0.52
0.56
0.62
0.54
0.59
2.03a
1.35a
0.86a
0.73a
0.83a
0.71a
Average of three replicates.
b
Determined by the Wakley-Black wet digestion method; all others analyzed by weight
loss after 30 minute heating in tared crucible.
c
Samples designated by the closest permanent sampler station. Samples taken 50 feet
from sampler.
41
�TABLE 11-6. PERCENT ORGANIC MATTER WITHIN TREATMENT AND
CONTROL CORES TAKEN FROM TEST AREA C-52A
DEPTH, inches
CONTROL
ORGANIC MATTER, %
G-11
C-9
0-7
Oto 6
2.03
0.96
1.99
0.57
6 to 12
1.35
0.71
1.04
0.52
12 to 18
0.86
0.72
1.61
0.56
18 to 24
0.73
0.67
1.49
0.62
24 to 30
0.83
0.87
1.06
0.54
30 to 36
0.71
0.41
0.96
0.59
4. CONCLUSIONS
The varying effects of different concentrations of herbicide Orange and the changes in soil
composition associated with different depths are clearly indicated by the ANOVA and multiple
range tests on the bioassay of the standard concentrations. Thus, it should be expected that
the same concentration of Orange in different types of soils will be reflected by different plant
growth patterns.
An obvious disparity exists between the soybean data and cucumber data estimates of Orange
concentration at various test area sites. Confounding occurred because parts of this experiment
were conducted at different times without statistical balancing. The attempt to adjust for those
differences by weighting the data to reflect the differences in the control plants was not successful.
Evidently the differences in the environments could not be explained by such a simple adjustment.
5. CHEMICAL ANALYSES OF SOIL CORES
As a result of the bioassay analyses previously discussed, those soil samples collected in
November 1969 and in April and December 1970, which caused the greatest growth inhibition,
were analyzed chemically for 2,4-D; 2,4,5-T; picloram; arsenic; and the contaminant TCDD.
a. Methods and Materials
A 25 to 50 gram soil sample was weighed, acidified, and extracted with 1:1 hexane:
acetone (see Figure II-4). The hexane:acetone was made basic and the aqueous phase saved for
extraction by ether after acidification, butylation via boron trichloride, and the subsequent
determination of 2,4-D and 2,4,5-T. The hexane phase was gently shaken repeatedly with sulfuric
acid until the sulfuric acid was clear. The hexane phase was then condensed and the extract
representing 50 - 100 mg of soil was injected on a 5% OV-225 gas chromatographic (GC) column.
The GC was equipped with a Ni"^ electron capture detector. If a peak was found within.+. 10%
of the retention time of TCDD, the sample was irradiated with ultraviolet light for 16 hours.
Column chromatography was also employed.
A gas chromatograph trace of the TCDD samples is shown in Figure II-5. This figure
shows an unaltered and a spiked soil sample before and after ultraviolet light treatment for
three different soil samples. In no case was any TCDD detected. Notice also that the added
TCDD was completely destroyed by UV irradiation.
42
�CONDENSE
5 ml
EXTRACT
50 g SOIL
HEXANE ACETONE
1
GO
EXTRACT
WATER PHASE
KOH, H20
HCI
ETHER
EXTRACT
IRRADIATE
TCDD DESTROYED
ETHER
n - BuOH
BCI3
INJECT 10,\a= 100 mg
LLDb = 0.001 ppm
DETERMINE
BUTYL ESTERS
a
b
c
Lambda = A
LLD = Lower Limit of Detection
p value = Partition Value
Figure ii-4.
p - VALUE 0
0.51 ±0.06
HEXANE:
ACETONITRSLE
Analysis Flow Chart for the Extraction of 2,4-D; 2,4,5-T; and TCDD from Lakeland Sand
�50 mgSOIL INJECTED
-UNALTERED SOIL
5 ppb TCDD ADDED
I
N
160 POUNDS 2,4,5-T/A APPLIED
5 ppb TCDD ADDED
I UNALTERED SOIL
I
UV
UV
\
584 POUNDS 2,4,5-T/A APPLIED
\
\ 5 ppb TCDD ADDED
UNALTERED SOIL
i
UV
1
2
UV
<
3
4
5
6 CONTROL SOIL
Figure II-5. Gas Chromatograph Traces of TCDD Samples. (The Traces
Represent 50 mg of Extracted Soils from Grids 2 and 4.
See Table I-7)
44
�The soils were analyzed for arsenic using 6 mis of 1:1 h^SC^/HCK^ per 10 g, followed
by reductive distillation and development of a molybdenum blue color. Nine soil cores (to the
36-inch depth) were analyzed for picloram by Dow Chemical U.S.A. The minimum detection
limit for picloram was 5 ppb.
Additional soil samples were collected in June and October 1973 from near sampler
sites C-9, F-6, and 0-7 and from the center of Grid 1 located approximately 1000 feet south of
sampler station 0-7 (see Figure I-5). These soil samples were analyzed for TCDD by the
Interpretive Analytical Services, Dow Chemical,. U.S.A., Midland, Michigan. The method of
analysis reported by the Interpretive Analytical Services is as follows:
10 gms of soil were extracted with 1:1 acetone-hexane, and the hexane
recovered from the extract by the addition of water. (J. Assoc. Offic. Anal.
Chemists 56. 728 (1973). (Initially, the soil extracts were subjected to
separation procedures involving only silica gel column chromatography, but
too many interferences were found for best sensitivity. Hence, all samples
were treated by a modification of the techniques developed by Baughman
and Meselson, "An Analytical Method for Detecting Dioxin", National
Institute of Environmental Health Sciences Conference on Dibenzo-dioxins
and Dibenzo furans, Research Triangle Park, NC, April 1973, published in
Evnironmental Health Perspectives, No. 5, August 1973). The modified
procedure is as follows:
Hexane extracts from above washed with successive 10 ml portions of
concentrated H2S04 until H2SC>4 is colorless (4 - 5 washings).
Hexane evaporated to 0.5 ml, and passed through a silica gel column.
Dioxins eluted from the column and 1:5 benzene-hexane. Eluate evaporated
to a small volume, and taken up in 0.5 ml hexane. (This step is in addition
to the Baughman-Meselson procedure, and was found necessary to achieve
best sensitivity.)
Hexane solution from above placed on an Al 20o column. PCB's eluted
with 1:4 CC^-hexane. Dioxin eluted with 1:4 CH2Cl2-hexane. Eluate
evaporated to small volume and injected directly into an LKB-9000 gas
chromatography-mass spectrometer combination.
Column Conditions: 6 ft x 1/8 inch stainless steel packed with 3%
OV-3 on 80/100 mesh Gaschrom. Z, isothermal at 230°C. Retention
time ~ 6.5 min.
Detector: mass spectrometer set to monitor m/e = 320 and 322
simultaneously.
b. Results and Discussions
Table II-7 shows the results of all analyses for soils collected during the period 1969 through
1971. Notice the persistence of 2,4-D and 2,4,5-T in soil core J-3NE from April to December 1970.
However, it should be emphasized that if no herbicide degradation had occurred, a concentration
of approximately 80 ppm 2,4,5-T might be expected within the top 6 inches (see Table II-7,
45
�assuming the weight of a one acre 6-inch increment weighs 2 million pounds). Notice that
cores M-8SW, N-12SW, and 0-5S show leaching of 2,4-D, and 2,4,5-T. This particular region
of the grid received 1,168 pounds per acre of Orange from 1964 to 1966. Moreover, 0-5S may
have received heavy concentrations of herbicides when Grid 1 was in use (1962 to 1964). Table
II-8 compares chemical and bioassay data for the same core (M-8S), collected in December 1970
and subsampled for analyses. These data suggest that chemical analysis for 2.4-D and 2,4,5-T
alone may not account for all the biologically active phytotoxic components (e.g., degradation
products and/or fuel oil residue). Note that the trend is reasonably similar between methods
of analysis.
No TCDD residues were found by the Pesticide Degradation Laboratory in any of the
soil samples at a minimum detection limit of less than 1 ppb. Recent analyses of drums of
Orange in storage suggest that the average concentration of TCDD in Orange may be 2 ppm .
If it is assumed that all the 2,4,5-T sprayed on TA C-52A was contaminated with 2 ppm TCDD,
then approximately 0.5 pound of TCDD was disseminated in this test area. However, the
analyses of TCDD in the part per trillion (ppt) range would be required for detection of
potential residue. The results of soil samples collected in June and October 1973 and analyzed by
Interpretive Analytical Services, in the parts per trillion range, did in fact indicate the presence
of TCDD or a TCDD-like chemical compound. These data are shown in Table 11-10. The
greatest concentration of TCDD was found in the soil core from the center of Grid 1. This grid
received 0:1 the average 947 pounds 2,4,5-T per acre in the period 1962-1964. The levels
detected in the 6 to 12 and 12 to 18 inch depths were probably due to contamination at
the time of sample collection. These data suggest that TCDD or a TCDD-like compound may
persist for an extended period of time. Moreover, it would appear that the Orange (Purple)
disseminated on this test grid was significantly contaminated with this compound.
Significant levels of picloram were found in November 1969 near Sampler K-9. Notice
that at this date the residue was confined to the top 12 inches. However, by May 1970 picloram
may have moved to the lower increments within the soil profile.
Table II-7 also shows the levels of arsenic found in selected soil cores. From the data
in this table, it is evident that there is no appreciable build-up of arsenic in the soil. Perhaps
this is due to leaching or possibly to the reduction and volatilization of dimethylarsine from the
cacodylic acid. These observations are further verified by data on arsenic levels from sites
J-3NE, C-9SW, K-9N, and 0-8S collected and analyzed in June 1973. Table II-9 compares the
arsenic levels from these sites collected in 1970 and again in 1973.
c. Conclusions
Small amounts (in parts per billion) of 2,4-D, 2,4,5-T, and picloram were found persisting
on the test area in June 1971. The last application of Orange was December 1969, while the last
application of White was May 1970. The last application of Blue was in September 1970; nevertheless, no significant build-up of arsenic has been noted. However, leaching of the arsenical from
the soils may have occurred. Significant TCDD residue (or a TCDD-like compound) has been
detected in the parts per trillion range from Grid 1.
o
^Personal communication with Dr. Walter Melvin, February 1973, Air Force Environmental
Health Laboratory, Kelly AFB, Texas.
46
�TABLE 11-7. RESULTS OF CHEMICAL ANALYSES FOR PICLORAM; 2,4-D;
2,4,5-T; 2,3,7,8-TCDD; AND ARSENIC IN SOIL SAMPLES FROM
EGLIN AFB RESERVATION TEST AREA C-52A
SOIL
SAMPLE3
DEPTHb
TCDDd,
ppb
ARSEN!Cd,
ppm
PICLORAMC,
ppb
2,4-D,
ppb
1e
34,21
1.2
2.8
<1.0
2.24
2
21, 11
7.0
2.0
<1.0
0.86
3
<10, 6
0.1
0.8
<1.0
0.90
4
<10, 5
0.1
0.6
<1.0
0.52
5
<10, <5
0.1
0.9
<1.0
0.62
6
<10,< 5
0.1
0.3
<1.0
0.54
1
ND
1.7
1.2
<1.0
0.55
2
ND
1.7
1.0
0.34
3
ND
0.1
1.0
<1.0
<1.0
4
ND
0.1
1.0
<1.0
0.41
5
ND
ND
ND
<1.0
ND
6
ND
0.1
0.7
<1.0
0.52
2,4,5-T,
ppb
NOVEMBER 1969
K-9N
6 APRIL 11
370
T3RE"
"
0.41
10 DECEMBER 1970
1
<10
<0.1
2.4
<0.1
4.70
2
<10
<0.1
1.8
<0.1
1.30
3
<10
<0.1
1.1
<0.2
0.90
4
<10
<0.1
0.7
<0.2
0.55
5
J3NE
<10
<0.1
1.0
<0.2
1.13
<0.1
0.3
<0.2
0.90
ND
1.6
5.9
<1.0
3.21
2
ND
1.1
0.1
<1.0
0.48
3
ND
0.1
0.7
<1.0
0.20
4
ND
0.1
0.4
<1.0
0.27
5
ND
0.1
0.3
<1.0
0.27
6
ND
0.1
0.4
<1.0
0.20
6
<10
1
6 APRIL 1970
J-9SE
47
�TABLE 11-7. CONTINUED
SOIL
SAMPLE3
b
DEPTH
PICLORAMC,
ppb
2,4-D,
ppb
2,4,5-T,
ppb
TCDDd,
ppb
ARSENICd,
ppm
10 DECEMBER 1970
1
<10
<0.1
0.6
<0.1
0.55
2
<10
2.4
0.4
< 0.1
0.55
3
<10
0.6
0.4
<0.1
0.55
4
<10
<0.1
0.2
<Q.2
0.58
5
<10
<0.1
<0.1
<0.3
0.41
6
<10
<0.1
<0.1
<0.1
0.48
1
<10
<0.1
1.8
<0.4
1.64
2
<10
<0.1
1.2
<0.3
0.88
3
<10
<0.1
0.3
<0.2
0.48
4
<10
<0.1
0.3
<0.1
0.48
5
<10
<0.1
<0.1
<0.2
0.55
6
<10
<0.1
0.4
<0.4
0.52
1
<10
5.6
7.0
<0.2
0.90
2
<10
5.8
1.4
<0.2
0.48
3
<10
7.6
2.8
<0.2
0.34
4
<10
15.0
5.6
<0.1
0.41
5
<10
5.0
2.8
<0.5
0.34
6
<10
13.2
6.8
<0.2
0.55
1
<10
7.6
2.2
<0.2
1.86
2
<10
10.0
1.0
<0.2
1.05
3
<10
11.8
1.2
<0.2
0.76
4
<10
4.8
1.4
<0.3
0.69
5
<10
6.0
2.6
<0.2
0.69
6
B-14SW
<10
7.0
3.0
<0.2
0.76
10 DECEMBER 1970
C-9SW
10 DECEMBER 1970
M-8SW
10 DECEMBER 1970
N-12SW
10 DECEMBER 1970
0-5S
1
ND
0.8
1.2
<0.1
0.90
2
ND
0.6
0.6
<0.1
0.80
3
ND
0.6
1.2
<0.2
0.76
4
ND
0.6
0.6
<0.2
0.41
5
ND
<0.1
8.4
<0.7
0.69
6
ND
0.6
1.4
<0.1
0.55
48
�TABLE 11-7.
SOIL
SAMPLE3
DEPTH
b
PICLORAMC,
ppb
CONTINUED
2,4-D,
ppb
2,4,5-T,
ppb
TCDDd,
ppb
ARSENICd,
ppm
10 DECEMBER 1970
0-7NE
1
<10
ND
6.6
<0.2
2
<10
2.8
0.2
<0.3
3
<10
3.6
0.4
<0.2
4
<10
0.8
2.6
<0.2
5
<10
5.6
2.6
< 0.2
6
<10
1.2
0.2
<0.6
1.52
0.76
0.76
0.62
0.62
0.62
10 DECEMBER 1970
1
1.2
<0.1
ND
<0.1
2.6
<0.1
ND
<0.1
0.8
<0.1
4
ND
<0.1
0.6
<0.1
5
ND
<0.1
1.2
<0.1
2.70
0.58
0.62
0.20
0.41
6
ND
<0.1
0.6
< 0.2
0.07
1e
ND
0.1
8.7
<1.0
1
ND
0.1
3.2
<1.0
2
17,7
ND
ND
ND
3
<10, 5
ND
ND
ND
4
11, <5
0.1
0.1
<1.0
4
ND
0.1
ND
<1.0
5
<10,<5
10, 5
ND
ND
ND
6
0.1
0.9
1.0
6
13 MAY 1971
G-9N
<0.1
3
13 MAY 1970
K-9N
ND
2
0-8S
ND
0.1
1.0
1.0
3.94
4.25
ND
ND
0.41
0.41
ND
0.41
0.48
2
92, 160
ND
ND
ND
ND
10 DECEMBER 1970
CONTROL
1
<10
<0.1
<0.1
<0.2
0.55
2
<10
<0.1
<0.1
<0.3
3
<10
<0.1
<0.1
<0.2
4
<10
<0.1
<0.1
<0.4
5
<10
<0.1
<0.1
< 0.4
6
<10
<0.1
<0.1
< 0.5
0.41
0.55
0.24
0.41
0.48
r
°
f
8 APRIL 1971f
49'
�TABLE 11-7. CONCLUDED
a
Samples designated by the nearest permanent air sampler station on the one square mile
test grid. All samples were taken 50 feet from a certain air sampler, except control site
was 0.4 mile from the one square mile grid.
b
Samples taken with a core borer in 6 inch increments. Depth 1 = 0 to 6 inches; 2 = 6 to
12 inches; 3 = 12 to 18 inches; 4 = 18 to 24 inches; 5 = 24 to 30 inches and 6 = 30 to
36 inches. Each increment was uniformily mixed prior to sampling for chemical analysis.
G
Picloram analysis was performed by International Research and Development Corporation
and/or The Dow Chemical Company; Dow Chemical Method ACR 69.10, modified.
^Analysis performed by E. A. Woolson, Pesticide Degradation Laboratory, United States
Department of Agriculture, Beltsville, Maryland.
e
Two samples from same depth were taken 10 feet apart.
f,Control soil for picloram analysis taken 8 April 1971, and other analyses performed
after 10 December 1970 sampling.
TABLE II-8. A COMPARISON OF CHEMICAL AND BIOASSAY DATA FOR SOIL
CORE M-8a COLLECTED DECEMBER 1970
DEPTH,
Inches
CHEMICAL ANALYSIS,
ppbb
BIOASSAY ANALYSIS0
LOWER LIMIT,
UPPER LIMIT,
ppb
ppb
80
745
0-6
12.6
6-12
7.2
22
596
12-18
10.4
70
256
18-24
20.6
37
146
24-30
7.8
48
168
30-36
20.0
43
158
a
Sample collected 50 feet southwest of air sampler station M-8.
b
Total concentration of 2,4-D and 2,4,5-T.
c
Data from soybean bioassay (see Table II-4)
50
�TABLE 1 -9. A COMPARISON OF ARSENIC LEVELS IN SOIL CORES COLLECTED
IN 1970 AND 1973 FROM TA C-52Aa
LOCATION
nCDTU
Utr I n,
J-3NE
C-9SW
b
1970
1973
1970^
1973
ON!
1970
1973
0-6
4.70
0.85
1.64
1.68
3.94
0.62
2.70
1.46
6-12
1.30
0.47
0.88
0.56
4.25
0.54
0.58
0.42
12-18
0.90
0.59
0.48
0.60
<MD
0.41
0.62
0.45
I nches
a
Analysis performed by E. A. Woolson, Pesticide Degradation
Department of Agriculture, Beltsville, Maryland.
0-8S
1970
1973
Laboratory, United States
"Samples collected 50 feet in the designated direction (e.g., NE) from the permanent air
sampler station.
C
ND = not determined.
TABLE 11-10. LEVELS (PARTS PER TRILLION) OF 2,3,7,8 TETRACHLORODIBENZOp-DIOXIN (TCDD) IN SOIL FROM TA C-52A COLLECTED IN JUNE OR
OCTOBER 1973a
DEPTH,
Inches
0-6
6-12
12-18
18-24
24-30
30-36
LOCATION
C-9
<10b
ND
ND
ND
ND
ND
F-7
11
ND
ND
ND
ND
ND
0-7
GRID 1
30
<10
<10
<10
<10
<10
710
140
72
<10
<10
<10
a
Method described in text.
'-'Lower limit of detection in parts per trillion TCDD.
c
Probable interference from excessive organic matter.
51
CONTROL
<20C
<10
<10
<10
<10
<10
�SECTION III
STUDIES OF THE VEGETATION OF TEST AREA C-52A
The first studies of Test Area C-52A were those concerned with vegetation. Testing of
aerial spray equipment began in June 1962, and following heavy applications of materials in
1963 and 1964, vegetation surrounding the test site showed changes suggestive of herbicidal
damage. In the fall of 1966, concern about the extent of this damage led to the establishment
of a contract with the University of Florida, Gainesville, Florida. The purpose of the contract
was to conduct a taxonomic study that would quantitatively measure changes in density of
vascular plants in the area adjacent to the test grid (References 111-1, III-2, and III-3).
Observations of tree growth rings in those reports prompted studies (Reference III-4)
concerned with assessment of spray drift upon the forest trees adjacent to the test area. A
third study (Reference IM-5) was concerned with the histological examination of a plant
species growing in the flight lines on the test grid. Synopses of Reference 111-1 to IM-5 are
included in this section. The last report, and the one most concerned with the current research
effort (Reference III-6), will be summarized and referred to in this report within the section
on current studies.
References:
111-1. Ward, D. B.: Ecological Records on Eglin AFB Reservation - - the First Year.
AFATL-TR-67-157, Air Force Armament Laboratory, Eglin Air Force Base, Florida, 1967.
Unclassified.
III-2. Ward, D. B.: Ecological Records on Eglin AFB Reservation - - the Second Year.
AFATL-TR-68-147, Air Force Armament Laboratory, Eglin Air Force Base, Florida, 1968.
Unclassified.
III-3. Ward, D. B.: Ecological Records on Eglin AFB Reservation - - Conclusions.
AFATL-TR-70-55, Air Force Armament Laboratory, Eglin Air Force Base, Florida, 1970.
Unclassified.
III-4. Hunter, H. H. and B. M. Agerton: Annual Diameter Growth of Conifers Adjacent to
Eglin Reservation Test Area C-52A as Related to the Testing of Defoliant Spray Equipment.
AFATL-TR-71-52, Air Force Armament Laboratory, Eglin Air Force Base, Florida, 1971.
Unclassified.
III-5. Sturrock, T. T. and A. L. Young: A Histological Study of Yucca filamentosa L. from
Test Area C-52A, Eglin Reservation, Florida. AFATL-TR-70-125, Air Force Armament
Laboratory, Eglin Air Force Base, Florida. 1970. Unclassified.
III-6. Hunter, J. H. and A. L. Young: Vegetative Succession Studies on a Defoliant-Equipment
Test Area, Eglin AFB Reservation, Florida. AFATL-TR-72-31, Air Force Armament Laboratory,
Eglin Air Force Base, Florida. 1970. Unclassified.
52
�1. SYNOPSIS OF TAXONOMIC STUDIES, 1966 - 1969
a. General Observations
In the fall of 1966, turkey oak, Quercus laevis. adjacent to the test clearing was severely
affected, apparently by herbicide driftage; and the large proportion of the trees of this species
gave the entire forest an abnormal aspect. Upper branches of all trees had apparently been
completely defoliated, and many or even most of the twigs were killed. On the lower trunks a
proliferation of small branchlets had appeared; in all cases, these branchlets began growing in
the spring of 1965, as determined by the number of bud scale scars present.
Blue-jack oak, Quercus incana. and sand live oak. Quercus germinata. were also heavily
damaged near the test clearing but appeared undamaged as little as 1.1 miles from the clearing
in an area where turkey oak still exhibited signs of damage.
Longleaf pine, Pinus palustris. and sand pine, Pinus clausa. adjacent to the test clearing
appeared unaffected. Needle length and internode length were normal, as compared with
similar plants away from the test area.
A sampling was made of the growth rates of four tree species as indicated by width of annual
growth rings. Blue-jack oak, turkey oak, and long-leaf pine produced growth rings that appeared
to vary independently of spray applications to the adjacent TA C-52A. Sand pine seemingly
showed a positive correlation with a marked increase in growth in the years immediately after
the 1963 - 1964 period of heavy spray application.
Extensive observation of the vegetation in all directions from TA C-52A indicated a rapid
disappearance of damage attributable to spray driftage. The maximum distance that damage
was definitely detected was 5 miles, seen on trees at the upper end of Range 52, north of the
test area.
Observations made later in this project failed to disclose damage at any distance from the
test area that was not attributable to the 1963 - 1964 period of activity. Following a testing
period in 1969, particular attention was given to the oaks, pines, and herbaceous plants in
various directions from TA C-52A. A few sand pines along the south edge of the test area had
visible abnormalities in their early spring growth, but this had largely disappeared by early
August. Other vegetation appeared normal, suggesting that herbicide driftage, if any, from the
1969 series of tests was significantly less than in earlier years.
b. Quantitative Sampling
In the fall of 1966, a program was devised to permit the quantitative measurement of
changes in density of stand of vascular plants in the area adjacent to TA C-52A. Since changes
in the herbaceous plants might be more subtle and more difficult to detect than those in the
larger woody plants, an experimental design was developed that would disclose differences of
slight magnitude but of statistical significance.
Five stations were selected in apparently homogeneous woodland east of the test area, and
at each station four parallel transects of 50 meters were laid out at right angles to an imaginary
53
�radius from the center of TA C-52A. The first of these sets of transects was immediately
adjacent to the test clearing, and the fifth was at a distance of 2.0 miles. All plants intercepted
by the transects were counted and listed. The resulting data were interpreted by a conventional
analysis of variance and F-test.
The 2157 plants of 54 species intercepted by the 1000 meters of transect were found (with
a few exceptions) not to differ significantly in their frequency with distance from the test area.
This was taken to mean that the supposedly higher spray driftage near the test area had not had
a significant effect on the viability of individuals of most species.
A few species were found to differ significantly with distance from the test area. Eleven
species fluctuated significantly in number of individuals at varying distances from the test area,
but upon examination, these differences were found to result from natural heterogeneities in
the supposedly homogeneous woodland. They could not be attributed to spray effects.
Three species were found to be absent near the test area and to increase significantly away
from this area. These species were the small, upright legume, I^h_rQais..nQoJiriL the persimmon,
Djospyros virgmiana. and the weeping haw, Crataegus lacrimata. Again, since the legume is a
perennial with a deeply buried rootstock and the other two are trees which would have left
evidence in the form of dead trunks, it is probable that these species were not exterminated
by spray driftage near the test area, but rather reflect an original and natural heterogeneity in
their distribution.
Only in the case of four species was there clear evidence of influence by proximity to the
test area. The number of individuals of four herbs - hjyp.gricym gentianoides, Solidago odora.
Warea sessilifolia, and Rhynchosia cytisoides - decreased significantly away from TA C-52A.
More meaningfully, the number of individuals of these species increased significantly adjacent to
the test site. These four species are noted for their ability to rapidly colonize cleared land. The
observed variation in number of individuals is best explained by these species utilizing the opening
in the canopy resulting from the spray-induced loss of foliage by the oaks.
By early August 1969 the oaks in the area of the five transect stations again had normal
foliage. At that date, it was not possible to find individuals of the Hypericum. the Warea. or
the Rhynchosia. and the Solidago was very reduced in number. The presumption is that the
spray-induced damage of 1963 - 1964 to the forest surrounding the test site had largely
disappeared and that by 1969 the vegetation of the area was again essentially normal.
2. SYNOPSIS OF GROWTH OF SAND PINE, 1969 - 1970
a. General Comments
One of the observations noted in Reference 111-1 was that the growth of sand pine,
Pin'us cjausa, was seemingly related (positive correlation) to the periods of heaviest testing
of spray equipment. This observation prompted an investigation, conducted between March
1969 and June 1970, into the growth of tree rings.
The species of trees selected for sampling were sand pine, longleaf pine, P. palustrjs. and
turkey oak, Quercus Jaeyjs. A total of 18 sand pines were cut along with two longleaf pines
and two turkey oaks. Sand pines were cut at ground level, and all others were cut 2 to 3 feet
above ground level. A cross section was cut from the end of each trunk and was sanded so
that the annual growth rings could be measured - to the nearest 0.1 mm.
54
�An examination of the relative amount of annual herbicide delivery on TA C-52A revealed
that the greatest amount of defoliant drift probably occurred in the following increasing order
of years: 1967, 1966, 1962, 1965, 1969, 1968, 1964, and 1963. This order is based primarily
on the amount, type, and formulation of materials sprayed per year. The amount of drift and
defoliant damage that occurred would also have depended upon climatic and flight conditions.
For example, probably very little drift damage occurred in 1967 because relatively little testing
was done and all testing occurred during winter months (the time of a reduced level of plant
growth). Likewise, damage would have been expected in 1964, not only because of the many
Orange missions, but also because all testing occurred from May through July and some of the
missions were flown at altitudes greater than the usual 150 to 200 feet.
b. Results
An initial examination of the annual diameter growth data indicated that possibly the
growth of some trees was directly or indirectly stimulated by spray drift from defoliant testing.
However, an analysis of the data did not substantiate this hypothesis. Growth obtained by
trees during individual years of testing was often no greater than growth obtained in some
previous year before defoliant spraying started. When the total annual diameter growth for
individual pines during years of defoliant testing was compared with the same number of years
before testing, no significant differences were apparent. Five of nine treatment trees (those
close to TA C-52A) and three of six control trees made less total growth during the years of
testing. For longleaf pine, one sample showed a decrease and the other an increase between
1962 and 1968.
Several of the pines located close to TA C-52A made less annual growth in 1963 - 1964
(period of expected greatest damage) when compared to the annual diameter growth of other
years of defoliant testing. However, the reduced amount of growth did not seem to be related
to defoliant spraying because three control trees also grew less in 1963 than any other year
between 1962 and 1969. In addition, the amount of diameter growth in 1963 for trees close
to TA C-52A was often no less than the diameter growth for some year previous to defoliant
testing.
Difficulties were encountered in measuring annual diameter growth in turkey oak. The
older increments could be easily differentiated, but the last three to five increments were not
discernable. Gross observations of the diameter growth of the turkey oak sampled close to
TA C-52A indicated the tree had grown less during the years of defoliant testing. As discussed
in Reference III-3, the annual diameter growth of two turkey oaks that had grown within a few
hundred yards of TA C-52A was measured, but without a clear indication that annual diameter
growth was inhibited by defoliant testing. The greatest amount of tree defoliation around
TA C-52A had been noticed on turkey oak, and a reduction in annual diameter growth was
expected to be most evident in individuals of this species. However, the small amount of
sampling showed no indication of a general reduction of annual diameter growth during the
years of testing.
An attempt was made to relate annual diameter growth to rainfall and temperature. An
analysis of average, maximum, and minimum monthly temperatures recorded since 1949 at
IMiceville, Florida, revealed a high degree of uniformity for the same months from year to
year. Rainfall for each month, however, varied greatly over the years; and many attempts
55
�were made to discover what combinations of monthly rainfall data correlated with annual
growth. While the combination of April and May rainfalls yielded the highest correlation
of any two other months, only one sample showed a significant probability (95 percent
confidence level) of this rainfall being related to annual diameter growth. Therefore, the
rainfall data available could not be used to explain the annual growth patterns of the trees
observed.
3.
SYNOPSIS OF HISTOLOGICAL STUDY OF YUCCA, 1970
a. General Comments
The military herbicides Orange (2,4-D and 2,4,5-T) and White (2,4-D and picloram)
function as growth regulators in their herbicidal behavior. A study was undertaken to
determine whether structural (histological) changes were evident in a plant species (Yucca
filamentosa) found in a high herbicide residue area of TA C-52A.
Observations have confirmed that the largest bulk of the various chemicals used in the
testing of aerial defoliation spray equipment was released and fell within the instrumented test
area (TA C-52A). As a result of these repetitive applications, many plant species (i.e., the
dicotyledonous plants) were selectively eliminated. The vast majority of the remaining plant
life was monocotyledonous with the only distinct plant association being broomsedge
(Andropogon virginicus). switchgrass (Panicum virgatum). and yucca (Yucca filamentosa).
Field observations indicated that yucca was the most persistent species occuring in the
flight-line areas of the test grid. Observations on gross morphology indicated no differences
between plants occurring on and off the test grid; however, crownal areas (the plant part at the
soil surface) appeared to be different.
Specimens of yucca were selected from areas of high herbicide residue and from an
area sufficiently distant from the treated area to preclude contact with the herbicides and/or
herbicide residues. Tissue samples obtained from the crown area of these plants were prepared for microscopic observation.
b. Results
Both cross and radial sections of treated and control plants were examined. The control
plants were used to establish the normal development of this species. Yucca is different from
most monocotyledonous plants in that it has some secondary growth and develops a peridermlike structure. In addition, repeated divisions of parenchyma cells and the suberization of
their products produces tangential bands of cork progressing inward and including some of
the fibrovascular bundles which have an uncharacteristic forked habit of growth. All of these
structures were quite evident in both the control and the treated samples.
Based on these studies, there is no apparent difference in the formation of structures
in Yucca filamentosa specimens obtained from an area subjected to repetitive applications
of military herbicides and specimens from an area not receiving the herbicides. Both samples
followed the normal structure for this species, as described in the scientific literature.
While these observations were conducted on a very small sample of the plants which did
persist in the heavily treated area, no evidence of malformations was found. A larger sample and
many more observations of different tissues of the plants might detect abnormalities in this
56
�species under these conditions, and it is also possible that a larger sample of untreated plants
would similarly produce individuals with malformations - - such anomalous structures are
often found in many species of plants grown under different environmental conditions.
4. CURRENT VEGETATIVE SUCCESSION STUDIES
a. Introduction
The first complete survey of the vegetation existing on the herbicide test grids was
initiated in 1971 (Reference III-6). The 1971 survey established a base line from which
future observations or surveys could proceed to determine the rate and type (plant species
involved) of plant succession on the test grids.
The June 1973 studies of vegetation are a continuation of the 1971 survey and provide
precise data and photographs to illustrate changes that have occurred during a 2-year period.
b. Materials and Methods
In May 1971, the one square mile grid (Figure I-4) was divided into 169 sections (each
400 by 400 feet). The percentage pla.nt cover in each 160,000 ft^ section was visually estimated,
and a vegetative coverage map resulted. In June 1973, the same technique was used to construct
another vegetative coverage map. Coverage was ranged into five classes as follows: Class O = 0
to 5% cover, Class I = 5 to 20% cover, Class II = 20 to 40% cover. Class III = 40 to 60% cover.
Class IV = 60 to 80% cover, and Class V = 80 to 100% cover.
In June 1971, three 400 by 400 foot sections from each coverage class were randomly
selected for a detailed collection of dicotyledonous (broadleaf) plant species. A diagonal transect starting 20 feet within the northwest corner of each section was walked to the southeastern
boundary. Plants were collected along the transect, and the results were tabulated for the number
of dicotyledonous plants occurring in each section. A control area 0.2 mile northwest of the
one square mile grid and an area in the center of the plot formerly occupied by Grid 1 were
also surveyed. In June 1973, each of these areas was again surveyed by the same method. A
square-foot analysis was performed on (1) 15 additional 400 by 400 feet sections, (2) the
control area used in 1971, (3) a new control area west of the one square mile grid, and (4) a
160,000 ft^ section in the center of area occupied by Grid 1. The additional 15 sections were
randomly selected, and within each section, nine areas, each measuring one square foot, were
analyzed (Figure 111-1). The square foot sampling sites were selected by dividing the 400 by
400 foot sections into three strips, each 133 feet wide. A line was drawn in center of each
strip and three one-square-foot areas were selected by generating d-j, ^ anc' ^3 as distances
to be walked. The distances were generated by a random number generator which included
constraints that assured one sampling area from each one-third of the transverse with the
sampling area being random within the one-third area. After each distance was walked-off,
the metal square-foot measuring device was placed, and the percent coverage for each plant
species was visually estimated.
d. Results and Discussion
The 1971 and 1973 vegetative coverage maps are shown in Figures III-2 and III-3,
respectively. Table 111-1 shows the percent coverage that each vegetative class occupied in
June 1971 and in June 1973.
57
�-Figure 111-1. Square-Foot Measuring Device in Use During Vegetation Survey - June 1973
TABLE 111-1. PERCENT OF VEGETATIVE COVER OCCUPIED BY VEGETATIVE
CLASS FOR THE 1 SQUARE MILE GRID
VEGETATIVE CLASS
JUNE 1971
JUNE 1973
0 (0 to 5%)
4%
0%
I (5 to 20%)
14%
4%
II (20 to 40%)
29%
12%
III (40 to 60%)
25%
18%
IV (60 to 80%)
21%
42%
V (80 to 100%)
4%
23%
58
�80 to 100%
40 to 60%
5 to 20%
60 to 80%
20 to 40%
0 to 5%
8
A
9
10
11
12
13
14
B
C
D
E
F
G
H
J
M
N
O
Figure III-2. Vegetative Coverage of the One Square Mile Grid on Test Area C-52A,
May 1971
59
�80 to 100%
40 to 60%
5 to 20%
60 to 80%
20 to 40%
0 to 5%
12
13
14
Figure III-3. Vegetative Coverage of the One Square Mile Grid on Test Area C-52A,
June 1973
60
�After a 2 year period, no vegetative class O areas were judged to remain on the one square
mile grid. All class O areas had developed into class I or II areas. The greatest change in number
of individual areas occurred from class II to IV (14% of total) and class III to IV (17% of total).
For those areas with less cover than class V, 19 class IV areas, two class III areas, four class II
areas and four class I areas did not change in percent cover during the 2 year interval.
Examples of vegetative cover changes are illustrated in Figures III-4 to 111-13 by comparing the 1971 and 1973 photographs of identical areas. All of these photographs represent
changes from one coverage class to another, except for area IM-5 (Figures III-6 and III-7).
Although an increase in vegetative coverage can be seen for N-5, this increase was not enough
to place the area in Class II. Figure 111-14 and Figure 111-15 illustrate an increase in number
of shrubs for a Class IV area.
In 1971, data on number of dicotyledonous or broadleaf species were assembled, and
the same 400 by 400 feet areas were again surveyed in 1973. Table III-2 shows the increase
in numbers of broadleaf plants after 2 years. The numbers of broadleaf plants are still
significantly increasing in all areas, including Control Area 1. As is expected, the greatest percent change occurs in those areas with the smallest amount of vegetation because these areas
have open sections where seeds can germinate free of competition from other plant species.
However, these areas are relatively dry, windblown sites, and vegetative succession will continue
to be relatively slow as compared to areas on the grid that have more poorly drained soils,
and therefore, more available soil moisture. An indication of relative rate of succession for
different areas of the one square mile grid is illustrated by observing the speed with which class
0, I, II, and III areas change to other classes. For example, all 1971 class 0 areas on the
northern section of the grid are now in class II, but 1971 class O areas in the southern portion
of the grid only changed to class I in the 2 year interval.
From June to September 1971, 74 dicotyledonous species were collected on the one
square mile grid, and 33 additional species were found during the June 1973 survey. Table
III-3 contains a complete list of all species that have been found on the grid. The relative
frequency of occurrance of all new species collected in 1973 was rare or infrequent except for
Euphorbia maculata and Polygonella gracillis. Plants that were found in Control Area 2 but not
found on the grid were rosinweed (Silphium ovatifolium). hairy bedstraw (Galium pilosum).
sun flower (Helianthus sp.), and flax (Linum floridanum).
Because the square-foot analysis technique is a more accurate method of determining
vegetative cover, the results of the two methods are compared in Table III-4. This shows that
visual estimations of 400 by 400 foot areas were 8% to 30% higher than the more accurate
square-foot technique. However, class rankings for the two methods are the same except for
areas found to have 40% to 60% vegetative cover by the square-foot analysis. The most
significant comparison of the two methods is that which shows Control Site 2 and Grid 1 area
to be in class III instead of class IV.
As a result of the square-foot analysis, the most important plants on the grid in terms
of coverage are the grasses, switchgrass (Panicum virgatumHFigure 111-16), and, woolly panicum
(£. lanuginosum) (Figure 111-17). These two grasses were found to comprise from 44% to 64%
of the existing coverage for all vegetative classes. The most important dicotyledonous plants
are rough buttonweed (Diodia teres) (Figure 111-18), poverty weed (Hypericum gentianoides)
(Figure 111-19), and common polypremum (Polypremum procumbens). These three dfcots
occupy from 3% to 17% of the existing cover in all classes on the grid.
61
�*&%'•••'• ****$*£ * ~Zff' .'•*^i,"*: 4,%'T"^'W;*'i ^ j>«*r-*,'**'L,}^^T~^?fc'^V'&2.> *-. ..*'. 2r
•&&*"*•%' '-»--'-„-.-•:.. ~ * ,*-*•.'• * ,
-'^w" -v r •»Awi«>'A*i:<ii«r^-**
i
.;.=, ••"j^, -^' v"„-.-..^.. 4 i.v /•-,
^ *»*» ^ ^,.v ? .-»•*
v
:
v
:
•"4,:-^ / . i-^^'^S-'^ijatt.-,
. c: ^>ti-ir ^L^**
. • > -. .." * - . " ' • : :.'-f -- -^' ' /'-4^ -"**-*- «
r-. - Apfc's-tu:'»" *.*u.i .T ~ .. jal:<^ . ^-,AA^«.. •
;::-.*»•
•
Figure IM-4. Area N-8, June 1971, Looking SE from Samp,er N-;
8
; '\ , '*? • i •,:; :^ -^
^*
"*
\
-^ <• *
-
.^ -y^
i-t #
Figure II.-5. Area N-8, June 1973, Same View as Figure IM-4 After 2 Years
62
»«^
�Figure IH-6. Area N-5, June 1971, Looking SE from Sampler N-5
Figure 111-7. Area N-5, June 1973, Same View as Figure HI-6 After 2 Years
63
�Figure 111-8. Area L-10, June 1971, Looking SE from Sampler L-10
Figure III-9. Area L-10, June 1973, Same View as III-8 After 2 Years
64
�Figure 111-10. September 1971 View of North-South Flightpath on One Square Mile
Grid from Sampler A-9
Figure 111-11. June 1973 View from Same Position as Figure 111-10 After 2 Years
65
�.*,,!«Vi v;;v '•£
<*. ,t>*' Hs^-r
Figure 111-12. April 1969 Looking South Near Sampler G-5
Figure 111-13. July 1973, Same View as Figure III-12 After 4 Years
66
�Figure 111-14. Area D-7, June 1971, Looking SE From Sampler D-7
Figure 111-15. Area D-7, July 1973, Same View as Figure 111-14 After 2 Years
(Notice increase in number .-of shrubs after 2 years)
67
�Figure 111-16. Switchgrass (Panicum virgatuml
Figure 111-17. Woolly panicum (Panicum lanuginosum)
68
�Figure 111-18. Poorjoe or Rough Buttonweed (Diodia teres)
Figure 111-19. Poverty Weed (Hypericum gentianoidesl
69
�TABLE II 1-2. VEGETATIVE COVER CHANGES AND DICOTYLEDONOUS
PLANT SPECIES CHANGES BETWEEN JUNE 1971 AND
JUNE 1973
400 BY 400 FT
AREAS SURVEYED
CLASS RANKING
1971
1973
NUMBER OF
DICOTYLEDONS
COLLECTED
1971
1973
PERCENT
INCREASE
1971 TO
1973
B-8, M-7, N-8
0
I, II
%
a
10
100
L-10, N-5, M-2
I
I, II, III
a
6
a
13
116
II
IV
a
13
a
23
76
D-9, K-13, J-1
III
IV
a
a27
59
D-7, C-6, E-3
IV
V
a
19
a
37
94
E-6, F-12, H-11
V
V
a24
a
37
54
Grid I Area
IV
IV
17
27
59
Control Area 1
V
V
28
39
39
Control Area 2
ND
IV
ND
44
ND
D-12, A-11, C-11
17
a
Average of the three 400 by 400 ft areas
70
�TABLE 111-3. SPECIES OF DICOTYLEDONOUS SHRUBS AND HERBS COLLECTED
ON TA C-52A ONE SQUARE MILE GRID IN SUMMER 1971 AND 1973
SPECIES
COMMON NAME
VEGETATIVE CLASS AND
FREQUENCY OF
OCCURENCE
SHRUBS
*Baptisia ellipitica
*Baptisia hirsuta
Callicarpa americana
Diospyros virqiniana
Ilex qlabra
Ilex opaca
Lespedeza sp.
Pinus clausa
Pinus palustris
Quercus laevis
Quercus sp.
Quercus sp.
Quercus sp.
Quercus sp.
wild indigo
wild indigo
American beautyberry
common persimmon
gal I berry
American holly
sand pine
longleaf pine
turkey oak
V; rare
V; rare
IV; rare
IV; infrequent
V; infrequent
IV; infrequent
III; rare
IV; rare
IV; rare
III, IV, V; frequent
V; infrequent
IV; infrequent
III, IV; infrequent
IV, V; infrequent
HERBS
Acanthospermum australe
Achillea millefolium
Aqaloma discoidalis
* AgaJims djyar icata.
Ambrosia artemisiifolia
*Arenaria caroliniana
Asclepia humistrata
*Asclepias tuberosa
*Asvrum hvpericoides
*Baccharis halimifolia
*Balduina anqustifolia
Biqelowis nudata
Cassia fasciculata
Centella asiatica
*Chenopodium sp.
Chrysobalanus oblonqifolius
*Chrysoma pauciflosculosa
*Chrysopsis aspera
Chrvsopsis graminifolia
Chrvsoosis mixta
*Clitoria fragrans
Cnidoscolus stimulosus
Crotalaria maritima
Crotalaria sagittalis
paraquay bur
common yarrow
foxclove
common ragweed
Carolina sandwort
common milkweed
butterfly weed
St Andrews cross
groundsel baccharis
partridgepea senna
goosefoot
gopher apple
golden-aster
grassleaf golden-aster
golden-aster
pigeonwings
risky treadsoftly
rattlebox
arrow Crotalaria
*Collected only in June 1973
71
III; frequent
III; infrequent
II, III; frequent
IV, V; infrequent
II, III, V; frequent
II, IV, V; rare
IV; rare
IV; rare
IV; rare
IV, V; rare
V; infrequent
0,l,ll,lll; frequent
V; rare
V; rare
III, V; frequent
V; rare
II; infrequent
II; infrequent
V; rare
III, IV; infrequent
III, IV, V; infrequent
V; rare
�TABLE 111-3. CONTINUED
SPECIES
COMMON NAME
VEGETATIVE CLASS AND
FREQUENCY OF
OCCURENCE
HERBS Continued
*Croton arqvranthemus
Croton qlandulosus
*Cuphea so.
Diodia teres
Erechtites hieracifolia
*Eriqeron annuus
Erioqonum tomentosum
Eupatorium capilifolium
* Euphorbia maculata
Euphorbia supina Raf.
Froelichia floridana
Galactia microphylla
Gnaphalium falcatum
Gnaphalium obtusifolium
Gnaphalium purpurem
Hedyotis procumbens
Hedvotis uniflora
*Heterotheca subaxillaris
Hypericum qentianoides
*Hypericum myrtifolium
*Kalmia harsuta
*Kraqia virqinica
Lechea patula
*l_echea villosa
*Liatris secunda
*Liatrisqracilis
Lithospermum caroliniense
Lobelia brevifolia
Lugwigia virgata
Lupinus diffusus
Lupinus nuttallii
Molluqo verticillata
Oxalis stricta
Paronychia patula
Petalostemon caroliniense
Phlox flotidana
*Physalis heterophylla
Pluchea rosea
Polyqala nana
Polyqala polyqama
Polygala sp.
*Pnl\/nnnellq gracilis
tropic croton
cuphea
rough buttonweed
fireweed
annual fleabane
wild buckwheat
dogfennel
spotted spurge
prostrate spurge
Florida snakecotton
milkpea
cudweed
fragrant cudweed
purple cudweed
camphor telegraph plant
poverty weed
St Johns-wort
sandhill kalmia
pinweed
hairy pinweed
pinkscale gayfeather
slender gayfeather
Carolina gromwell
lobelia
false loosestrife
sandhills lupine
carpetweed
yellow woodsorrel
nail wort
prarie-clover
Florida phlox
clammy groundcherry
bachelor button
bitter polygala
polygala
jointweed
*Collected only in June 1973
72
V; rare
III; rare
IV; rare
all classes; common
V; infrequent
IV,V; frequent
II, IV; infrequent
II, III, IV; frequent
1, 1 1, 1 V,V; frequent
I; infrequent
I; infrequent
1 1, 1 1 1; infrequent
IV; infrequent
IV,V; frequent
1 1 1, IV; infrequent
V; rare
V; rare
IV; rare
II, III, IV; frequent
V; infrequent
V; rare
IV; rare
1 1 1,IV; frequent
IV; rare
V; infrequent
V; infrequent
l,lll; infrequent
V; frequent
V; rare
0,l,lll; infrequent
I; rare
I; rare
III; rare
1, 1 1, 1 1 1; frequent
I; infrequent
II; infrequent
V; rare
V; rare
IV,V; infrequent
II, III, IV,V; frequent
III; infrequent
1. 1 I.I V; frequent
�TABLE 111-3. CONCLUDED
SPECIES
COMMON NAME
VEGETATIVE CLASS AND
FREQUENCY OF
OCCURENCE
common polypremum
IV; infrequent
V; rare
IV; frequent
V; frequent
V; rare
V; rare
V; rare
1, 1 1, IV; frequent
V; rare
III; infrequent
IV,V; rare
1 1, 1 1 1, IV; frequent
V; rare
IV,V; infrequent
1 1, 1 V,V; frequent
I V,V; frequent
0,l; rare
III; rare
III; rare
all classes; common
IV; rare
V; rare
V; rare
V; rare
IV; infrequent
1 1 1, IV; infrequent
1 1 1, IV; infrequent
HERBS Concluded
Polypremum procumbens
*Pterocaulon undalatum
Rhexia alifanus
*Rhexia lutea
* Rhexia mariana
* Rhexia salicifolius
* Rhexia virginiana
Rhvnchosia aalactioides
Rhynchosia reniformis
Rubussp.
*Rudbechia hirta
Rumex acetosella
*Sabatiaangularis
Schrankia microphylla
*Smilax sp.
Sophronanthe hispida
Stylisma villosa
Stylosanthes biflora
Tephrosia so.
Tithymalus soaerospermus
Tragia linearifolia
Tragia smallii
*Traqia sp.
* Verbena carnea
Vernonia angustifolia
Wahlenberaia merginata
Wareasessilifolia
meadowbeauty
yellow meadowbeauty
Maryland meadowbeauty
common meadowbeauty
pinebarrenpea
dollarleaf rhynchosia
blackberry
blackeyed coneflower
red sorrel
rosegentian
littleleaf sensitive brier
greenbrier
twin pencilflower
common euphorbia
noseburn
noseburn
noseburn
verbena
ironweed
rockbell
*Collected only in June 1973
73
�TABLE 111-4. DATA COMPARISON OF PERCENT VEGETATIVE COVER BY
VISUAL OBSERVATION OF OVERALL PLOT VERSUS THE
SQUARE-FOOT TRANSECT METHOD, 1973 DATA
VEGETATIVE
CLASS/SITE
VEGETATIVE CLASS
CRITERIA
VISUAL
ESTIMATE9
SQUARE-FOOT
TRANSECTb
Class I
5 to 20%
19
11
Class II
20 to 40%
29
19
Class III
40 to 60%
60
41
Class IV
60 to 80%
76
67
Class V
80 to 100%
89
80
Control Site 2C
75
45
Grid 1 d
75
47
a
Average of 12 estimates
b
c
Average of 27 transects
Located 0.1 mile west of Sampler E-1
d
Center section of Grid 1 located 1000 feet south of Sampler 0-7
74
�e.
Conclusions
A comparison of vegetative coverage and occurrence of plant species on the one
square mile grid between June 1971 and June 1973 has shown that areas with 0 to 60%
vegetative cover in 1971 have a coverage of 15% to 85% in 1973. Those areas having 0 to 5%
coverage in 1971 (areas adjacent to or under flightpaths used during herbicide equipment
testing) now have 15% to 54% coverage. The rate of change in the coverage seems to depend
on soil type, soil moisture, and wind; there is no evidence to indicate that existing vegetative
coverage is in any way related to herbicide residue in the soil. Dicotyledonous or broadleaf
plants that are normally susceptible to damage from herbicide residues presently occur throughout the entire one square mile grid.
75
�SECTION IV
STUDIES OF THE ANIMALS OF TEST AREA C-52A
In May 1970, a survey was initiated to determine the animal species composition of the sprayequipment testing grid on TA C-52A and within the adjacent 11 square mile area. The purpose
of this survey was to determine the extent of faunal ecological alteration that occurred in the
test area due to repetitive applications of military herbicides.
It was expected that application of military herbicides would temporarily alter the faunal
ecology of an area, primarily due to the changes in the vegetation. It had been postulated that
the animals living in a sprayed area would either be killed outright by herbicides or would receive
doses via water or food that would affect their reproductive processes. Laboratory studies dealing
with the teratogenic and embryotoxic effects of TCDD, a contaminant found in 2,4,5-T, have
been reported (Reference IV-1). It had also been suggested that animals would totally avoid a
sprayed area either due to the lack of food, the offensive appearance or taste of the vegetation,
or odors produced by the herbicides or their degradation products.
The objectives of this animal survey were to determine species variation, distribution patterns,
migration, and relative population sizes as found on the test grid or immediately adjacent to it.
Methods of study included early morning, midday, and night field trips for identification and
collection of mammals, birds, reptiles, and amphibians. Many species collected were brought into
the laboratory where they were photographed and either preserved or mounted, and these now serve
as a reference collection to facilitate identification for subsequent studies.
The results of the 1970 animal survey were reported in Reference IV-2. A synopsis of the
1972 report and comments concerning its correlation to the 1973 studies are included in this report.
1. SYNOPSIS OF QUALITATIVE ANIMAL SURVEYS, 1970 - 1973
A total of 18 mammal species were observed off the test grid with 12 of these species also being
found on the grid. All of the animals sighted on the grid used the area for foraging or as a source
of drinking water except the beach mouse and the hispid cotton rat, which were using the area as
their habitat. The hispid cotton rat was first seen on the grid during the 1973 study. Table IV-1
lists the mammals observed both on and off the grid. The most important economic population in
the area was the deer herd. Night field trips yielded average counts of from 24 to 36 deer on the
grid and within the immediate area. Close inspection of aquatic areas on the grid during early morning field trips revealed extensive activity the previous nights. In addition to the deer herd a sizable
herd of feral hogs earlier crossed with Russian Boars, also inhabited the area. The hogs frequented
the marshy areas, drinking and rooting for food.
During the spring of 1970, a red fox was frequently observed close to the grid and its den was
found approximately 100 yards from the edge of the grid. Five kits were found in the den and based
upon gross observations, they appeared healthy and normal.
The most common rodents found off the grid in 1970 along the streams that drain the area
were the cotton mouse and the hispid cotton rat. In the fields surrounding the grid, the eastern
References:
IV-1. Report of the Advisory Committee on 2,4,5-T to the Administrator of the Environmental
Protection Agency, 7 May 1971
IV-2. Pate, B. D., R. C. Voigt, P. J. Lehn, and J. H. Hunter: Animal Survey Studies of Test Area
C-52A, Eglin AFB Reservation, Florida. AFATL-TR-72-72, Air Force Armament Laboratory,
Eglin AFB, Florida, April 1972. Unclassified.
76
�TABLE IV-1. MAMMALS FOUND ON THE 1 SQUARE MILE GRID AND .WITHIN THE
ADJACENT 11 SQUARE MILE AREA
SPECIES
AREA WHERE OBSERVED
COMMON NAME
ON GRID
Canis familiaris
wild dog
Dasypus novemcinctus
armadillo
Didelphis marsupialis
opossum
Geomvs pinetis
southeastern pocket gopher
Lynx rufus
bobcat
Mephitis rnephitis
striped skunk
Odocoileus
virginianus
whitetail deer
Oryzomys paulustris
rice rat
Peromyscus gossypinus
cotton mouse
Peromvscus polipnotus
beach mouse
Reithrodontomys
humulis
eastern harvest mouse
Procyon jotqr
racoon
Sciurus carolinensis
eastern gray squirrel
Sciurus niger
eastern fox squirrel
Sigmodon hispidus
Sus scrofa
hispid cotton rat
Sylvilagus floridanus
eastern cottontail rabbit
Vulpes fulva
red fox
OFF GRID
b,c
b,c
b,c
b,c
wild pig
a
Species found on or off grid for first time, 1973 data
b
Dominant species; sighted during 80% of the field trips, 1973 data
c
Dominant species; sighted during 80% of the field trips, 1970 data
77
�harvest mouse was common. Eight pairs of the eastern harvest mouse were taken into the
laboratory and allowed to breed. Six of the eight pairs had litters totalling 24 offspring which
were normal in size and free from any apparent birth defects.
During the 1973 study, only two cotton mice and two eastern harvest mice were found.
The cotton mice were caught near a stream draining the grid, and the eastern harvest mice were
captured on the grid. There were eight beach mice captured off the grid in areas along streams
and in open fields.
The most common rodent species on the grid was the beach mouse. Trapping studies during
the summer of 1970 showed that this species was widely distributed throughout the grid, except
in areas with less than 5% vegetative cover. In the 1973 study, the beach mouse was found
predominantly in the areas of 5% to 60% vegetative cover.
At least 25 species of birds were observed in the area immediately adjacent to the grid or
feeding within its boundaries. Many more species than those listed in Table IV-2 are found
in the more densely forested areas near the outer limits of the 2 mile radius.
In 1970, seven species of water birds and waders were sighted repeatedly in the aquatic
areas on or off the grid. The most common birds on the grid were the meadow lark and
the mourning dove. It seems significant that all birds sighted, with the single exception
of a grasshopper sparrow (caught in a live animal trap) were medium to large species.
In I973, the first sightings of red-wing blackbirds and little blue heron occurred on the grid.
In 1970, the meadow lark was the predominant species of bird found, while in 1973, frequent
and repeated sightings of night hawks, bobwhite quail, Mississippi kites, mourning doves and
meadow larks were reported.
Eighteen species of reptiles were collected or observed, with 10 species recorded on the
grid and 12 species from the surrounding area (Table IV-3). Differences in faunal species
composition on and off the grid due to vegetation differences can best be illustrated with the
reptiles. Those species that are adaptable and occupy a variety of niches were found both on
and off the grid in large numbers. The dominant species on the grid was the six-lined racerunner,
and it was also one of the dominant species in the wooded area surrounding the grid. Those
species whose habitat is characterized by definite vegetative type cannot adapt to the open
habitat of the grid. The green anole and southern fence lizard are two of these. There are
also species which occur in the forest areas but are more plentiful in the open areas, such as
the eastern coachwhip. In 1973, the first softshelled turtle was seen on the grid.
Twelve species of amphibians were collected (Table IV-4). The amphibian population on
the grid centered mainly around the aquatic areas with the exception of the two toad species,
which were also found in the dry areas. There were breeding populations throughout most of the
year in the aquatic areas on the grid: the southern cricket frog, the southern toad, the oak toad,
the barking tree frog, the southern leopard frog, and the squirrel tree frog. The slimy salamander
is one of the dominant species in the surrounding forest but does not occur on the grid, presumably
because of its need for sufficient moist ground cover. The squirrel tree frog and the hog-nosed
waterdog were first reported on the grid in the 1973 study.
2. CURRENT STUDIES ON ANIMALS
In the 1970 animal survey, 73 species of vertebrates were observed on and off the test grid.
The most frequently observed species on the grid was the beach mouse Peromyscus polionotus
78
�TABLE IV-2. BIRDS FOUND ON THE 1 SQUARE MILE GRID AND WITHIN THE
ADJACENT 11 SQUARE MILE GRID
SPECIES
COMMON NAME
AREA WHERE OBSERVED
ON GRID
Accipiter striatus
velox
Aqelaius phoeniceus
OFF GRID
sharp-shinned hawk
red-wing blackbird
a
+
+
Ammodramus savannarum grasshopper sparrow
Bubulcis ibis
cattle egret
Botaurus lentiginosus
American bittern
Buteo jamaicensis
red -tailed hawk
Buteo liniatus
red-shouldered hawk
eastern green heron
Butorides virescens
virescens
Caprjmulgus vociferus
eastern whippoorwill
Casmerodius acbus
egretta
American egret
Cathartes aura
turkey vulture
Chordeiles minor
night hawk
b+
b+
Co!jn us. virginlanus
bobwhite quail
b+
b+
Coragyps atratus
black vulture
Con/us brachyrhynchos
American crow
Florida caerulea
little blue heron
Elanoides forficatus
forficatus
swallowtail kite
Falco sparverius
sparrow hawk
Ictinia misisipoiensis
Mississippi kite
Sturnella maqna
meadow lark
b,c +
b+
Turdus migratorius
robin
Zenaidura macroura
Unidentified Duck
mourning dove
b+
b+
Unidentified Goose
Unidentified Grebe
a
Species found on grid for the first time, 1973 data
boominant species; sighted during 80% of the field trips, 1973 data
c
Dominant species; sighted during 80% of the field trips, 1970 data
79
�TABLE IV-3. REPTILES FOUND ON THE 1 SQUARE MILE GRID AND WITHIN THE
ADJACENT 11 SQUARE MILE AREA
SPECIES
COMMON NAME
AREA WHERE OBSERVED
ON GRID
Agkistrodon piscivorus
eastern cottonmouth
Alligator
mississippiensis
American alligator
Anolis carolinensis
carolinensis
green anole
Cnemidophorus
sexlineatus
six-lined racerunner
Coluber constrictor
priapus
southern black racer
Crotalus adamanteus
eastern diamondback rattlesnake
Elphae guttata guttata
corn snake
Ferox sp.
soft-shelled turtle
Heterodon platyrhinos
eastern hognose
Lampropeltis doliata
doliata
scarlet kingsnake
Lygosoma laterale
ground skink
Masticophis flagellum
flagellum
eastern coachwhip
Matrix sipedon
pictiventris
Florida water snake
Pituophis melanoleucus
mugitus
Florida pine snake
Pseudemys scripta
scripta
yellow-bellied turtle
Sceloporus undulatus
undulatus
southern fence lizard
Sistrurus miliarius
barbouri
dusky pigmy rattlesnake
Sternotherus minor
minor
loggerhead musk turtle
OFF GRID
a
+
b,c
a
Species found on grid for the first time, 1973 data
^Dominant species; sighted during 80% of the field trips, 1970 data
c
Dominant species; sighted during 80% of the field trips, 1973 data
80
b,c
�TABLE IV-4. AMPHIBIANS FOUND ON THE 1 SQUARE MILE GRID AND WITHIN THE
ADJACENT 11 SQUARE MILE AREA
SPECIES
COMMON NAME
AREA WHERE OBSERVED
ON GRID
Acris sryllus gryllus
southern cricket frog
Bufo quercicus
oak toad
Bufo terrestris
southern toad
Eurycea bislineata
cirrigera
southern two-lined salamander
Gastrophryne
caroljnensis
eastern narrow-mouthed toad
Hermidactylium
sccutatum
four-toed salamander
Hyla qratiosa
barking tree frog
Hyla squirella
squirrel tree frog
Necturus beyeri
hog-nosed waterdog
Plethodon glutinosus
glutinosus
slimy salamander
Rana clamitans
clamitans
bronze frog
Rana pipiens/
sphenocephala
southern leopard frog
b+
a,b+
a
Species found on grid for first time, 1973 data
bA breeding population
81
OFF GRID
b+
�and the six-lined racerunner Cnemidophorus sexlineatus. These two species were suggested as
candidates for future studies of population distribution. During the months of February, March,
and May 1971 a trapping study was performed on the test area for three, 4-day periods in each
month (Reference IV-3). A total of 38 beach mice were captured during the three trapping
periods. Thirty beach mice were captured during the February-March periods, and of these,
six from the test grid and three from a control area were examined for gross deformaties.
Sections of liver, kidney, and gonads were free of abnormalities, and no cleft palates were
observed.
The primary purpose of the present study was two fold. First (Test Program I), animals
were to be obtained for examination of gross and microscopic lesions, since it has been
reported (Reference IV-1) that TCDD produces teratogenic and embryotoxic effects under certain
experimental conditions. Second (Test Program II), the trapping survey discussed in the previous
paragraph was to be expanded in an attempt to correlate habitat preference for the most prevalent
mammal observed on the grid in order to determine if the population distribution is related to
vegetative cover.
3. MATERIALS AND METHODS
Traps used for this study were Havahart traps (Havahart Traps, Department 1, P.O. Box 551,
Ossining, N.Y. 10562) numbers 0 and 1 for small mammals. Traps were baited with peanut
butter and oatmeal.
In June 1973, Test Program I was initiated by placement of traps on the square mile grid
in two patterns. At first, one trap was placed in every other plot (400 by 400 foot areas) in every
other row. For example, Row A had one trap each in plots 1, 3, 5, 7, 9, 11, and 13. Row C
had one trap each in plots 2, 4, 6, 8, 10, and 12. Four to eight traps were placed in these areas.
A total of 90 traps were emplaced. Traps were checked daily and the trapping duration was one
week. A second portion of Test Program I utilized four sampling plots with distinct physical
characteristics and involved the placement within each plot of 25 traps in five rows of five traps
each, 20 paces apart, in each plot. Historically, these areas were exposed to low or high concentrations of herbicide . Traps were checked daily, and the trapping was carried out for 7 days. In
October 1973, a third portion of Test Program I was conducted on Grid 1 exclusively (Figure I-5).
Grid 1 was divided into equal quadrants North-South and East-West, and was numbered upper left
(Area 1), lower left (Area 2), lower right (Area 3), and upper right (Area 4). Twenty-five traps
were placed in each area in two rows of 10 traps per row and one row of five traps with 15 paces
between traps. The rows were located at 250, 500, and 750 feet from the center of the grid on
the ordinate. Traps were checked daily for 7 days.
Mice, rats, and reptiles were taken to the laboratory for gross examination and prepared for
histologic examination. The majority of the animals were alive on arrival but some had succumbed
to the intense heat and confinement in the trap.
Live animals were subjected to a euthanasic procedure using ether. All animals were photographed, weighed, measured, and examined for develqpmental defects such as cleft palate, cleft
lip, polydactyly, and micro-ophthalmia. All internal organs were examined for gross lesions, and
individual organ weights were recorded. Representative sections of each tissue were placed in
^Personal .communication with Donald King, Department of Zoology, University of Minnesota,
Minneapolis, Minnesota.
82
�neutral 10% buffered formalin and processed for microscopic study by the Veterinary Pathology,
Washington, D.C. 20305. All remaining control and grid rat liver tissue and mouse fat and liver
tissues were collected, placed in clean glass jars, frozen, and sent to the Interpretive Analytical
Services Laboratory, Dow Chemical U.S.A., for TCDD analysis. The method of analysis was as
described in Section II with the following exceptions: Ten grams of tissue were added to 10 ml
ethanol and 20 ml 40% aqueous KOH and refluxed 2 hours. The resulting mixture was extracted
with four 10 ml portions of hexane. The hexane extracts were combined, subjected to h^SC^
extraction and the same subsequent steps as in analysis of the soil samples.
Recovery studies using blank fish, beef liver, and soil averaged 70+% at the 10 to 25 part
per trillion level.
In Test Program II, eight mouse traps were placed by computer randomization in areas
which were classified according to vegetative coverage. Five vegetative areas were classified
as follows: 5% to 20% coverage; 20% to 40% coverage; 40% to 60% coverage; 60% to 80%
coverage; 80% to 100% coverage (see Section III, Figure III-3). Three of the 400 by 400 foot
plots for each of Classes 1 to 5 were chosen at random. Eight pairs of coordinates were generated
using the library random number generator for the Wang 720C programmable calculator. Each
trap was placed in accordance with these coordinates. A total of 120 traps were utilized. Animals
thus trapped were ear tagged with size 1, sequentially numbered, fingerling tags (National Band
and Tag Company, Newport, Kentucky, 41071) and species, sex, and trap location was recorded.
They were examined for external abnormalities and released. Traps were checked daily during
the 8 days this study was conducted, and records were kept of original capture and the recapture
of individual animals.
4. RESULTS AND DISCUSSION
During Test Program I, several different species of animals were caught, both on and off the
test grid (Table IV-5). The sex distribution of the trapped animals was 23 male and 14 female
beach mice, eight male and eight female cotton rats, two female eastern harvest mice, one male
and one female cotton mice, ten male and seven female six-lined racerunners, one male eastern
cotton mouth, and one male toad.
TABLE IV-5. TOTAL NUMBER AND LOCATION OF ANIMALS COLLECTED DURING
1973 TEST PROGRAM I
CLASS
COMMON NAME
OFF GRID
ON GRID
Mammalia
beach mouse
cotton rat
eastern harvest mouse
cotton mouse
8
10
0
2
42
6
2
0
six-lined racerunners
eastern cottonmouth
4
1
13
0
toad
1
0
Reptilia
Amphibia
83
�The age of the rodents was determined by histological examination of the gonads based on
the presence or absence of sperm or ova (gametes) in the gonads. Animals with gonads showing
gametogenesis were classified as adults and those with gonads showing no gametogenesis were
classified as immature. The age of the animals varied, but adults predominated in the sample,
55 adults, 33 immature. Nine pregnant mice and five pregnant rats were found in the adult
female animals. The stage of gestation varied considerably from early pregnancy to near term.
Fifty-four embryos and fetuses were examined grossly and microscopically. No developmental
defects or other lesions were seen.
Gross necropsy lesions were relatively infrequent in the test population and consisted primarily of lung congestion in those animals that died prior to being brought to the laboratory.
No developmental defects were seen in any of the adult animals.
Histologically, the tissues of 13 of the 26 control animals and 40 of the 63 animals from
the test grid were considered normal. Microscopic lesions were noted in some animals from
both groups. For the most part, these were minor changes of a type that would be expected in
any animal population. One of the most common findings was parasites. A total of 11 controls
and 9 grid animals were affected with one or more classes of parasites. These are summarized
in Table IV-6.
Parasites may be observed in any species, and those in this population were for the most part
incidental findings that were apparently not harmful to the animal. There were exceptions
however. Protozoan organisms had produced focal myositis in one rat and were also responsible
for hypertrophy of the bile duct epithelium in a six-lined racerunner.
Moderate to severe pulmonary congestion and edema were seen in several rats and mice. All
of these animals were found dead in the traps before reaching the laboratory, and the lung lesions
were probably the result of heat stroke. The remainder of the lesions in both groups consisted
principally of inflammatory cell infiltrates of various organs and tissues. They were usually mild
in extent, and although the etiology was not readily apparent, the cause was not interpreted as
toxic.
It was highly improbable that any of the mice trapped during this study were alive during the
final phase of herbicide dissemination (September 1970), although the life span of the beach
mouse has been reported to be 5 years in captivity (Reference IV-3). A portion of the grid
population was certainly made up of offspring of these animals present in 1970. Emigration from,
or immigration to, the test grid could occur, especially on the fringe areas, since it has been
reported that the area traveled by an individual beach mouse during its daily activities may extend
to 5 acres (Reference IV-4).
An analysis of the ratios of organ weight to body weight, and organ weight to body length
for mice captured off the grid versus mice captured on the grid was conducted within the severe
constraints of limited data (June 1973 data). Female mice were not considered due to the fact all
References:
IV-3. Benton, A.H. and W. E. Werner, Jr. Field Biology and Ecology. McGraw Hill, New
York, 1966.
IV-4. Andrewartha, H.G. Introduction to the Study of Animal Populations. University of
Chicago Press, 1961.
84
�control females were pregnant and showed large individual body weight and organ weight
variations. Only two of 11 female mice from the grid were pregnant. There were five control
males (three mature and two immature) and 18 males (ten mature and eight immature) captured
on the grid. Complete organ data were available only for 13 of the 18 grid males (nine
mature and 4 immature).
It is recognized that the mature and immature mice will likely show different characteristics;
however, combination of these two groups was necessary to produce any reasonable sample size.
The t test for unpaired samples was used on 16 different factors (Table IV-7). These factors
are as designated below:
FACTOR
DESCRIPTION
A
=
Total organ weight/body length
B
=
Total organ weight/body length
C
=
Sum of lung, heart, kidney, and brain/body weight
D
E
=
=
Sum of lung, heart, kidney, and brain/body weight
Lung weight/body weight
F
=
Heart weight/body weight
G
=
Spleen weight/body weight
H
=
Liver weight/body weight
I
=
Kidney weight/body weight
J
=
Brain weight/body weight
K
=
Lung weight/body length
L
=
Heart weight/body length
M
=
Spleen weight/body length
N
=
Liver weight/body length
0
=
Kidney weight/body length
P
=
Brain weight/body length
Formula for the procedure used:
sx 2
~N~2
r
r
I
9
iA
sx.,^
1
sx.,
ITf
(2X1)2+
Ml
w.2
~X2
-2
Where
IS!-) + N 2 ¥ 2
85
<SX2>"1
N2
rN 1 + N 2 i
.
N
1N2 J
�TABLE IV-6. PARASITES FOUND IN RODENTS COLLECTED FROM CONTROL
AND TEST AREA SITES, JUNE 1973
LOCATION
Control
Test Area
a
NUMBER OF
ANIMALS
EXAMINED
NUMBER OF
PARASITES
ANIMALS
EFFECTED
NEMATODES CESTODES PROTOZOAN?
20
3
11
9
1
5
50
g
4
0
7
Animals trapped on Grids 2, 3, and 4
TABLE IV-7. SUMMARY OF RESULTS OF ORGAN WEIGHT TO BODY WEIGHT,
AND ORGAN WEIGHT TO BODY LENGTH FOR MICE OFF THE
GRID VERSUS MICE ON THE GRID (HEOn-Grid and Off-Grid
Samples are from the Same Population)
v = 16
FACTOR
t
P (exceeding t. Given H)
A
0.1863
0.43
B
0.8859
0.19
C
0.9750
0.17
D
0.1025
0.45
a
b
E
1.6618
F
0.2750
0.38
G
1.1025
0.14
H
0.7077
0.06
(0.05)
0.25
a
b
I
2.2228
J
0.2363
0.41
K
0.6500
0.27
L
0.5659
0.29
M
0.4979
1.0214
0.32
1.1034
0.14
1.1647
0.13
N
0
P
0.02
(0.10)
0.16
Significant at p < 0.05
"Value when control animal with lung and kidney lesions is removed from sample
86
�When the ratios of average body weight to average organ weight of various visceral organs
were compared between the male mice captured on the grid and the male mice captured off the
grid it was found that on the average, the control animals had lung and kidney weights that
varied significantly at the 95% confidence level. The lung variation just being significant. When
this information was compared to the pathological work-up, it was found that one male control
animal had multifocal subacute pneumonitis and multifocal subacute nephritis. When this animal
was removed from the sample, the ratio of kidney weight/body weight between the control and
grid animals no longer varied significantly. The lung weight/body weight variation became slightly
more significant. It is felt this variance is due to the difference in ratio of mature to immature
animals between the two groups, i.e., controls 3:2 compared to 9:4 for the grid animals.
The analyses for TCDD from rodents collected in June and October 1973 are shown in Table
IV-8. An initial interpretation would be that TCDD does in fact accumulate in liver and fat
of tissue from rodents living on the test grid. Data from soil analysis (Table 11-10, Section II)
confirm the presence of TCDD in soils of the test area. Discrepancy of levels of TCDD between
soils and tissues suggest the potential for bio-magnification of this compound. These data do not
correlate with previously published research (Reference IV-5). Such levels encounted in the
animals reported herein would be suspect of teratogenic or pathologic abnormalities. Such
abnormalities, however, were not encountered in this study. It would appear that analytically,
via mass spectrometry, the chemical detected is of a very similar nature to TCDD, but biologically
does not behave in the manner characterized for TCDD (Reference IV-5).
TABLE IV-8. CONCENTRATION (PARTS PER TRILLION) OF 2,3,7,8-TETRACHLORODIBENZO-p-DIOXIN (TCDD) IN LIVER AND FAT SAMPLES FROM
RODENTS COLLECTED FROM CONTROL AND TEST SITES ON
TA C-52A, JUNE OR OCTOBER 1973a
RODENT
TISSUES
CONTROL
LOCATION
GRIDS 2, 3,4
Rats
Liver, Fat"
<20
210
Mice
Liver, Fatb
<20
300
GRID 1
No Sample0
540d
a
Analysis for TCDD was performed by the Interpretive Analytical Services, Dow
Chemical U.S.A., Midland, Michigan
"Tissues represent a composite from all animals collected at the respective location
c
Rats do not frequent dry areas.
d
Sample collected in October 1973.
Reference:
IV-5. Conference on Dibenzodioxins and Dibenzofurans, Environmental Health Perspectives,
Experimental Issue Number Five, September 1973, National Institute of Environmental
Health Science, Research Triangle Park, North Carolina.
87
�The beach mouse was reported in Reference IV-2 as the most common rodent species
on the grid in 1970. Observations in the field indicate that the beach mouse remains the most
common rodent on the grid.
The 1970 study (Reference IV-2) also indicated that the beach mouse was widely distributed throughout the grid except in areas of less than 5% cover. In an attempt to correlate
distribution of the beach mouse with vegetative cover, a second test program (Test Program II)
was initiated with a total of 83 animals being trapped during an 8 day period, 28 June to
3 July 1973. The majority of animals (63) were found in areas with 5% to 60% vegetative
cover; within this range, the greatest number of animals trapped (28) was from an area with
40% to 60% cover (Figure IV-1). A similar habitat preference has been observed along the
beaches of the Gulf Coast (Reference IV-5). In this study, it appears that the beach mouse
utilizes the seeds of switchgrass, (Panicim virgatum) and woolly panicum (Panicum lanuginosum)
for a food source, and these are two of the most dominant plants on the grid (see photographs
in Section III). Seed husks of these plants have been observed in areas of mouse activity. It
is possible that another prominant plant, broomsedge bluestem (Andropogon virginicus).
also provides food for the beach mouse.
In an attempt to compare the trapping data from 1971 with those data obtained in the
1973 study and, hence, to determine whether an increase in the population of beach mice
has occurred, the following assumptions were made:
a. It was assumed that the traps, the bait, and the methods employed for setting
and placing the traps were equally as effective and similar in the 1971 and 1973 studies.
b. It was assumed that the density of trap placement was equally as effective and
similar in the 1971 and 1973 studies.
c. It was assumed that traps should be no further apart that approximately 1-1/2
times the mean random travel distance of the animal being trapped. For beach mice, this
distance is approximately 300 feet (Reference IV-5).
d. On the other extreme, it was assumed that the traps should not be so dense as
to impede animal movement nor disrupt animal habits.
All trapping experiments involved in this study were conducted within these extremes.
In order to produce an estimate of the population density of the beach mouse in the
herbicide treated area, it was necessary to determine what portion of that area was effectively
surveyed. It was also necessary to normalize the areas sampled for comparison based on the
mean random travel of the beach mouse from the 1973 recapture data. A tabulation was
made of the distances between the trap where initial capture occurred and the trap location
of the recapture farthest from the initial capture point. These distances represent the
distances that the mice from the sample were known to have traveled and were assumed to be
random samples from the population of habitat radii. The longest radius observed was 3,200
feet, the next longest was 285 feet, and the shortest was 45 feet. The 3,200-foot distance
was disregarded as a freak occurence because such a number appeared only once out of a sample
88
�30
S 20
<D
I 15
01
5-
20
40
60
100
Vegetative Cover, %
Figure IV-1. Relationship of Animals Trapped to Vegetative Cover
of 18 and it is more than 11 times as large as the next largest distance which is, itself, only
6.3 times as large as the smallest distance observed. The mean distance, 194 feet, of the
remaining 17 distances was used as the average habitat radius. Circles with 194-foot radii were
drawn using the traps of 12 randomly selected 400 by 400 foot plots as centers. The envelope
area around the traps was estimated using a triangle, rectangle, or circle according to the fit
which, by inspection, appeared to be the best. The average of the 12 areas measured was 8.3
acres with a standard deviation of 1.69, a maximum of 10.45, and a minimum of 5.17. The
estimate, 8.3 acres, was used as the effective survey area for each group of eight traps.
a. Variation of the Lincoln Index
The Lincoln Index may be stated mathematically as:
Pi =
- R)
Where
PI = first population estimate
89
�N-| = pre-census sample
N2 = total census sample
R = number of recaptures
Using the catch of 26 June and considering only the tagged animals, NI = 13. Using the
catch of 27 June, N2 = 18 and R = 1. According to this information, the first estimate is
PI = 222. Enough uncertainty is introduced, however, such as how a dead animal should be
counted in the pre-census sample, that an alternative method of estimation was desirable.
The following equation was used to calculate the second estimate of the population.
8
RJ + 1
'max " '
Where
N.|i = the catch from the ith day
N2 + 1 = the catch from the (i + 1)th day
RJ + 1 = the recaptures from the (i + 1)th day which were captured on the (ith)day also
The values for RJ + 1 were corrected for the influence of mice no. 18, recaptured six times;
no. 27. recaptured four times; no. 28, recaptured four times; no. 41, recaptured four times;
no. 45 recaptured three times; and no. 50, recaptured three times. These mice were considered to be trap addicts. From the data available, P2 = 152.
A third method was used for calculating P% in which the first catch was considered to be
the pre-census and the second catch the census. A computer program to simulate the
trapping of mice was developed with inputs of average sample size, Sa, and true population
size, Pt. Twenty-five runs were made at specific values of Sa and Pt, and the estimated
population was calculated with the Lincoln Index and averaged over the 25 trials. The average
recapture number, Ra was also calculated. Pt was changed until Ra was equal to the observed
recapture rate and Sa was equal to the observed sample size. Pt at these values is considered
to be the best estimate of the population, i.e., Pt is the number most likely to produce the
results which were observed in the real case. P% by this method was 191. This is not grossly
different from the 222 and 152 estimated from P-| and Po. The average of P l f P2, and Po
is probably the best overall estimate of the population. This average is approximately 189
total population - approximately 1.64 mice per acre.
90
�5. CONCLUSIONS
Based on the pathologic findings of the Test Program I study, it was concluded that there
was no evidence that the herbicide contaminant in question (TCDD) had produced any developmental defects or other specific lesions in the animals sampled or in the progeny of those that
were pregnant. The lesions found were interpreted to be of a naturally occurring type and were
not considered related to any specific chemical toxicity. The organ to body weight and organ
to body length comparisons for the grid versus the control animals did not vary significantly when
age and pathological lesions were considered. Chemical analysis of composite rodent liver and
fat tissue indicated that there was an accumulation of TCDD-like chemical in tissue. If these data
are valid (an assumption that may be challenged), what is the source of the TCDD? Seeds of
switchgrass (Panicum virgatum) were found in abundance in the stomachs of beach mice. Samples
of such seed collected from the test area were analyzed for TCDD. Results indicated no residue
of TCDD at a minimum detection limit of less than 10 parts per trillion.
Based on information provided by the Test Program II study, it was concluded that the
beach mouse forms a natural, integral part of the ecosystem of the Lakeland Sand Complex
utilizing the dominant plants on the grid for food. The beach mouse continues to inhabit
areas of 5% to 60% cover, with a preference for areas of 40% to 60% vegetative cover. This
is indeed similar to the habitat preference of the beach mouse in other locations.
The statistical evidence derived from the Test Program II study shows that the 1.64 beach
mice per acre population (based on the Lincoln Index for 1973) is slightly higher than the
0.8 and 1.4 mice per acre found on Santa Rosa Island (Reference IV-6). It was also concluded
that the population of beach mice was higher in 1973 than in 1971 in the area of the test grid.
Even though the first trial of the 1971 data reflected a higher count of mice per acre trapped,
the low capture count on the second trial in 1971 indicates a lower actual population based on
the Lincoln Index assumptions than the 1973 data. The apparent increase in beach mouse
population on the grid in 1973 over 1971 was probably due to the natural recovery phenomenon
of a previously disturbed area. Some areas of the test grid have already exceeded the preferred
percentage of vegetative coverage of the beach mouse habitat, and other areas are either ideal
or fast developing into an ideal habitat. If the test grid remains undisturbed and continues
toward the climax species, a decline in the number of beach mice will probably occur simply
due to his habitat preference.
Reference:
IV-6. Blair, W. F., Population Structure, Social Behavior, and Environmental Relations in
Natural Populations of the Beach Mouse (Peromyscus polionotus leucephalus). Contribution
from the Laboratory of Vertebrate Biological, University of Michigan, Number 48:1-47, June 1951.
91
�SECTION V
INSECT DENSITY AND DIVERSITY STUDIES
ON TEST AREA C-52A
During 1970 and 1971, an initial survey of the arthropod populations of Test Area C-52A,
Eglin Air Force Base, Florida, was accomplished, and the results were published in Reference V-1.
1. SYNOPSIS OF PREVIOUS RESEARCH, MAY - JUNE 1971 (Reference V-1)
A sweep net survey of the insects on a 1 mile linear transect of Test Area C-52A resulted in
the collection of more than 1,800 specimens belonging to 74 insect families and two non-insect
arthropod orders. Eighteen of the taxa collected accounted for 97 percent of the collection, and
of these, six taxa accounted for 72 percent of the collection: order Araneida (spiders), insect
families Cicadellidae (leafhoppers), Elaterjdae (click beetles), Asilidae (robber flies), Hygaeidae
(lygaeid plant bugs), and Pentatomidae (stink bugs). Spiders and robber flies are carnivores,
stink bugs are carnivores or herbivores, and the other families are herbivores.
As plants were eliminated by the herbicides, those insects which fed specifically upon those
plants disappeared; however, no direct effects of residue on the insects were observed.
The objective of the present study was to duplicate the techniques of the 1971 study as closely
as possible in order to evaluate populations along the same grid line 2 years later. Qualitative and
quantitative comparisons were drawn to indicate the changes in variety and number of arthropods
(especially insects) that had become established on the grid since the aerial dispersal tests were
terminated in 1970.
2. MATERIALS AND METHODS
The techniques used in the study discussed in this report were the same as those outlined in
Reference V-1 except as discussed in the following paragraphs.
Time and manpower limitations precluded general, non-systematic sampling of the grid, therefore
the bulk of this comparative study was based on sweep net surveys along sampler row 8 of the
test area. This allowed a quantitative comparison of results while non-systematic net sampling of
grid areas did not lend itself to such analysis. A total of five paired sweep net surveys were performed on the mornings of June 14, 16, and 18; these dates being approximately 2 years and 2
weeks after the study discussed in Reference V-1. A given "paired sweep" (200 sweeps made by
2 individuals using 15-inch diameter nets) was taken across the grid and then back to the starting
point. The simultaneous sweeps were 20 feet apart. At the end of each 400 foot transect, rather
than using killing jars, the net contents were emptied into a paper bag into which a vial of ethyl
acetate had been placed. These bags were then tightly folded and placed in a large sack that was
carried out to the same taxonomic level as in the 1971 study. Exceptions to this classification
scheme included the listing of Acalypterate muscoid flies as a group and the listing of certain
Reference:
V-1. Valder, S. M.: Insect Density and Diversity Studies on Test Area C-52A, Eglin AFB
Reservation Florida. AFATL-TN-72-4, Air Force Armament Laboratory, Eglin AFB, Florida.
January 1972. Unclassified.
92
�undetermined insects only to order. Table V-1 represents a full listing of the arthropods found
in the sweep net survey. The undetermined insects (112 specimens) for the most part were
either immatures or only partial specimens. The identifications were based on information in
Reference V-2.
Finally, due to time limitations, only one full set of sweep net survey samples had been
identified at the time of this report. Therefore, while the 1971 report discussed the results of
five 2-mile sweeps of sampler row 8 (essentially 10 replicates), the present study considers data
only from one 2-mile sweep of the same sampler row (essentially two replicates of each 400 foot
transect of the row). Representative specimens of the identified samples are in the reference
collection of the Biological Studies Branch, USAF Environmental Health Laboratory, Kelly AFB,
Texas.
3. RESULTS AND DISCUSSION
Those taxa or arthropods that were collected in numbers exceeding one percent of the total
number of specimens collected are listed in Table V-2. This table was formatted for comparison
with Table V-3 (from Reference V-1). (The various taxa are treated as families for simplicity.)
Such a comparison indicated that even though the 1973 data are based on only one sweep of the
grid, the total number of identified arthropods equaled 1,614 as compared to a total of 1,803
specimens from five sweeps in 1971. These data would then indicate that if the one 1973 sweep
were representative of all five sweeps taken during this second study, the total number of insects
caught would likely be greater than four times the number taken during the 1971 study. Further
analysis of the data indicates that the 1973 survey found great numbers of very small insects as
compared to the 1971 study. The majority of the Chrvsomelid beetles were very small insects,
and the Qcalvptrate muscoids, Psocoptera, Thysamoptera, Sminthuridae, Ocarine, and Chalcidoidea
also fall into this small to minute category. Table V-1 represents a listing of all arthropods collected
during the 1973 survey, and is compared to Table V-4 (from Reference V-1). Reference V-1,
however, lists not only those arthropods collected in 1971, but also those groups only observed
in 1970 and 1971. Therefore, the tables are not fully comparable either in taxa listed or in the
number of specimens reported. Comparison of this second set of tables again shows a relatively
large number of small insects found in the 1973 study. This discrepancy may simply represent a
difference in sampling/separation techniques or it may indicate an influx of populations of these
smaller arthropods as the vegetation and other environmental characteristics of the transects have
developed since the spray program was terminated.
Figures V-1 and V-2 represent arthropod/vegetation comparisons on Test Area C-52A for both
the 1971 and 1973 surveys. There exists a similarly vegetative distribution, and a slightly greater
plant coverage is indicated in 1973. The extreme differences in the numbers of arthropods found
on the transects during the 1971 study are shown as being reduced in 1973, and further replication
as well as time would likely reduce these differences more. Comparisons of the arthropod populations have to take into consideration the fact that Figure V-1 is based on the total observed and
collected specimens from Table V-4, while Figure V-2 is derived from only the identified specimens
of a single sweep of the 1973 study. Therefore, although the graphs representing the number of
arthropod "families" in both figures are relatively similar, and there is a tendency toward reduction
of extreme differences in the 1973 transect data, further discussion and comparison might be spurious.
Similar comments pertain to comparisons of the arthropod diversity graphs, even though basic
Reference:
V-2. Pate, B. D., P. J, Lehn, R. C. Voigt, and J. H. Hunter: Animal Survey Studies on Test Area
C-52A, Eglin AFB Reservation, Florida. AFATL-TR-72-72, Air Force Armament Laboratory,
Eglin AFB, Florida. April 1972. Unclassified.
93
�TABLE V-1. ANTHROPODS COLLECTED ON TEST AREA C-52A, EGLIN AFB
RESERVATION, FLORIDA, JUNE 1973
TAXON
COMMON NAME
CLASS: ARACHNIDA
ORDER: Araneida (Spiders)
ORDER: Acarine (Mites)
TOTAL
SPECIMENS
144
46
NUMBER OF SPECIMENS COLLECTED ON TRANSECT
AB BC CD DE EF FG GH HJ JK KL LM MN NO
4
9
9
2
16
2
18
3
36
27
18
7
1
1
7
6
6
2
8
3
2
1
1
4
1
3
CLASS: INSECTA
ORDER: Coleoptera (Beetles) 275 Specimens collected
Anthicidae
Antlike Flower Beetles
3
1
Carabidae
Ground Beetles
Chrysomelidae
Leaf Beetles
219
Cicindellidae
Tiger Beetles
7
Coccinellidae
Lady Beetles
1
Curculionidae
Snout Beetles
5
1
Elateridae
Click Beetles
Blister Beetles
Mycetaeid Fungus Beetles
Shining Flower Beetles
12
1
1
Meloidae
Mycetaeidae
Phalacridae
Tenebrionidae
Darkling Beetles
7
Undetermined larvae
and adults
6
1
1
1
1
84
35
2
1
1
5
69
18
1
1
1
1
1
2
2
1
1
1
2
53
1
1
1
1
1
12
1
11
2
1
1
2
1
1
2
3
14
12
1
ORDER: Collembola (Springtails) 53 Specimens collected
Sminthuridae
2
7
3
7
9
1
�TABLE V-1. ARTHROPODS COLLECTED ON TEST AREA C-52A, EGLIN AFB
RESERVATION, FLORIDA, JUNE 1973 (Continued)
NUMBER OF SPECIMENS COLLECTED ON TRANSECT
TOTAL
SPECIMENS AB BC CD DE EF FG GH HJ JK KL LM MN NO
ORDER: Diptera (Flies) 165 Specimens collected
TAXON
COMMON NAME
Acalyptrate
Asilidae
Muscoids
Robber Flies
Bombiliidae
Bee Flies
1
Cecidomyiidae
Gall Midges
3
1
1
14
2
Ceratopogonidae Biting Midges
2
2
6
6 21
14
7
3
7
1
8
3
3
1
1
1
1
1
2
Muscid Flies
2
1
1
Pipunculidae
Bigheaded Flies
3
1
1
Sarcophagidae
Flesh Flies
4
Syrphidae
Flower Flies
2
Tachinidae
Tachina Flies
10
Tipulidae
Crane Flies
Midges
Culicidae
en
9
5
1
Chironomidae
CO
86
Mosquitoes
Muscidae
Undetermined Adults
1
2
1
5
4
1
1
1
1
1
Burrowing Mayflies
33
2
2
4
4
6
1
1
1
5
1
ORDER: Hemiptera (True Bugs) 183 Specimens collected
Corimelaenidae
Corizidae
Corimelaenid Bugs
Grass Bugs
6
3
1
1
ORDER: Ephemeroptera (Mayflies) 1 Specimen Collected
Epnemeridae
1
1
1
2
1
1
1
1
2
2
4
4
2
�TABLE V-1.
TAXON
ARTHROPODS COLLECTED ON TEST AREA C-52A, EGLIN AFB
RESERVATION, FLORIDA, JUNE 1973 (Continued)
COMMON NAME
TOTAL
SPECIMENS
NUMBER OF SPECIMENS COLLECTED ON TRANSECT
AB BC CD DE EF FG GH HJ JK KL LM MN NO
ORDER: Hemiptera (True Bugs) Continued
Lygaeidae
Lygaeid Bugs
Miridae
Plant Bugs
6
1
33
2
Nabidae
Damsel Bugs
33
Neididae
Neidid Bugs
1
Pentatomidae
Stink Bugs
1
2
7
1
3
1 13
3
5
1
3
2
5
1
7
2
4
3
1
1
2
3
1
1
12
6
11
1
Assassom Bugs
19
Scutellerid Bugs
13
2
Usidetermined
Nymphs
68
2
2
1
2
3
1
10
3
3
6
1
1
10
2
4
3
Homoptera (True Bugs) 454 Specimens collected
Aleyrodidae
Whiteflies
1
Aphidae
Plantlice
5
Cercopidae
Spittlebugs
Cicadellidae
Leafhoppers
Scale Insects
Membracidae
6
1
Scutelleridae
Coccoidea
Fulgoridae
1
1
Reduviidae
ORDER:
4
Fulgorid Planthoppers
Treehoppers
1
1
43
1
400
1
21
3
1
27
3
81
2
1
25
41
3
1
32
1
4
28
27
1
1
36
1
4
28
31
3
22
1
8
18
�TABLE V-1. ARTHROPODS COLLECTED ON TEST AREA C-52A, EGLIN AFB
RESERVATION, FLORIDA, JUNE 1973 (Continued)
TAXON
COMMON NAME
TOTAL
SPECIMENS
NUMBER OF SPECIMENS COLLECTED ON TRANSECT
AB BC
CD DE EF
FG JGH HJ
JK
KL LM MN NO
ORDER: Hymenoptera (Bees, Wasps, Ants) 167 Specimens collected
Andrenidae
2
Bethylidae
Bethylids
2
Braconidae
Braconid Wasps
2
Chalcidoidea
Cynipoidea
Chalcids
Dryinidae
CO
Mining Bees
Dryinids
Formicidae
Ants
Halictidae
Ichneumonidae
Sweat Bees
Ichneumon Wasps
9
1
Mutillidae
Pompilidae
Velvet Ants
Spider Wasps
3
2
Undetermined Adults
5
Gall Wasps
40
1
1
1
1
1
2
3
7
1
3
1
99
1
3
1
9
6
3
1
2
1
28
8
10
9
4
15
4
2
1
1
3
4
2
4
10
1
1
1
1
12
1
1
2
1
1
1
1
4
2
1
1
1
1
2
1
ORDER: Neuroptera (Nerve Winged Insects) 1 Specimen collected
Myrmeleonidae
Antlions
1
1
1
ORDER: Lepidoptera (Butterflies and Moths) 13 Specimens collected
Microlepidoptera Several Families
Noctuidae
Owl Moths
2
1
�TABLE V-1. ARTHROPODS COLLECTED ON TEST AREA C-52A, EGLIN AFB
RESERVATION, FLORIDA, JUNE 1973 (Concluded
TAXON
COMMON NAME
TOTAL
SPECIMENS
NUMBER OF SPECIMENS COLLECTED ON TRANSECT
AB BC
CD DE EF
FG GH HJ
JK
KL LM MN NO
ORDER: Odonata (Dragonflies and Damselflies) 12 Specimens collected
Coenagrionidae
Damselflies
12
2
3
7
5
1
13
3
1
6
7
3
11
3
3
2
3
7
1
7
1
5
2
3
1
ORDER: Psocoptera (Psocids) 66 Specimens collected
Family not determined
66
2
7
10
15
6
3
1
2
2
1
ORDER: Orthoptera (Grasshoppers and Crickets) 92 Specimens collected
Acrid idae
Gryllidae
Grasshoppers
36
Crickets
34
Mantidae
Mantids
Phasmidae
Walkingsticks
14
1
Tettigoniidae
Katykids
2
1
1
2
6
1
1
7
1
1
5
ORDER: Thysanoptera (Thrips) 54 Specimens collected
Family not determined
TOTAL ARTHROPODS
TOTAL IDENTIFIED ARTHROPODS
54
1
1726
57
1614
55
9
6
2
19
9
1
81 253 190 128 357 184 104 92
70 248 185 123 339 172 98 77
1
4
92 118
2
37
33
81 103 33
30
�TABLE V-2. TAXA COLLECTED IN NUMBERS EXCEEDING ONE
PERCENT OF THE TOTAL SPECIMENS COLLECTED3,
JUNE 1973
FAMILY
COMMON NAME
Cicadellidae
Leafhoppers
Chrysomelidae
Leaf Beetles
219
13.6
38.4
Araneida
Spiders
144
8.9
47.3
Formicidae
Ants
99
6.1
53.4
Acalyptrate Muscoid
Flies
86
5.3
58.7
Psocoptera
Psocids
66
4.1
62.8
Thysanoptera
Thrips
54
3.3
69.4
Sminthuraidae
Springtails
53
3.3
72.3
Acarina
Mites
46
2.9
72.3
Cercopidae
Spittlebugs
43
2.7
75.0
Chalcidoidea
Chalcid Wasps
40
2.5
77.5
Acrid idae
Grasshoppers
36
2.2
79.7
Gryllidae
Crickets
34
2.1
81.8
Miridae
Plant Bugs
33
2.0
83.8
Nab idae
Damsel Bugs
33
2.0
85.8
Reduviidae
Assassin Bugs
19
1.2
87.0
a
Total equals 1,614 identified specimens:
NUMBER
PERCENT CUMULATIVE
COLLECTED OF TOTAL PERCENT OF
TOT A Ic
24.8
400
24.8
1 percent of the total equals 16 specimens
"As discussed in the text, several of the taxa represent ordinal or super family levels of
classification rather than family.
c
Cumulated percent of total is derived by the progressive summation of the figures in the
percent of total column.
99
�TABLE V-3.
TAXA COLLECTED IN NUMBERS EXCEEDING ONE PERCENT
OP THE TOTAL SPECIMENS COLLECTED3, JUNE 1971
PERCENT OF
TOTAL
FAMILY-COMMON NAME
CUMULATIVE PERCENT
OF TOTALb
Cicadelliclae - leaf hoppers
31.7
31.7
Araneida - spiders '(order)
18.6
50.3
Lygaeidae - lygaeid bugs
7.7
58.0
Elateridae - click beetles
Pentatomidae - stink bugs
4.7
62.7
4.5
67.2
Asilidae - robber flies
4.2
71.4
Nabidae - damsel bugs
3.9
75.3
Acrididae - grasshoppers
3.2
78.5
Reduviidae - assassin bugs
2.7
81.2
Sphecidae - sand wasps
2.6
83.8
Tenebrionidae - darkling beetles
2.4
86.2
Chrysomelidac - leaf beetles
2.2
88.4
Scutelleridae - scutellerid bugs
2.1
90.5
Coenagrionidae - dragonflies
1.4
91.9
Halictidae - sweat bees
1.4
93.3
Mydaidae - mydas flies
Tettigoniidae - katydids
1.3
94.6
1.3
95.9
Myc e t oph i 1 i dae - mycetophilid flies
1.0
96.9
Total equals 1803 specimens: 1 percent of the total equals 18
.specimens
Cumulated percent of total is derived by the progressive summation of
the figures in the percent of total column
100
�TABLE V-4.
INSECTS AND ARACHNIDS COLLECTED OR OBSERVED ON TEST AREA C-52A, EGLIN AFB
RESERVATION, FLORIDA, JUNE 1971
ARACHNIDS
ORDER
Araneida
Phalagida
NUMBER OF SPECIMENS COLLECTED ON TRANSECT
COMMON NAME
Spiders
Harvestmen
TOTAL
SPECIMENS
355
1
AB
BC
CD
4
3
25
DE
EF
FG
GH
HJ
JK
KL
LM
MN
NO
8 30 188
26
28
7
4
8
2
2
NUMBER OF SPECIMENS COLLECTED ON TRANSECT
FAMILY
COMMON NAME
TOTAL
SPECIMENS
AB
BC
CD
DE
EF 1 FG
GH
HJ
JK
KL
LM
MNJ NO
ORDER: COLEOPTERA (BEETLES) 206 Specimens Collected
Anthicidae
1
Buprestidae
Ant like Flower Beetles
Seed Beetles
Metallic Wood Borers
Carabidae
Ground Beetles
Cerambycidae
Long Horned Beetles
4
1
Chrysomelidae
Leaf Beetles
Cicindellidae
Tiger Beetles
Coccinellidae
Curculionidae
j-j
Lady Beetles
Bruchidae
Snout Beetles
1
1
43
2
1
2
4
4
1
1
1
1
1
8
6
Click Beetles
Gyrinidae"
Blister Beetles
Tumbling Flower Beetles
6
Passalidae
Passalid Beetles
4
4
2
4
2
4
2
10
3
Mordellidae
6
Whirligig Beetles
Meloidae
5
1
Predacious Diving Beetles
Elateridae
1
1
10
Dytiscidae"
1
Sighted but not collected in 1971
'sighted or collected in 1970
84
12
10
15
5
13
10
2
5
2
1
2
4
1
1
7
3
�TABLE V-4. CONTINUED
NUMBER OF SPECIMENS COLLECTED ON TRANSECT
FAMILY
ORDER:
TOTAL
SPECIMENS
COMMON NAME
Scarabaeidae
Scarab Beetles
Staphylinidae
Rove Beetles
Tenebrionidae
Darkling Beetles
ORDER:
BC
CD
DE
EF
FG
GH
HJ
KL
LM
MN
NO
7
3
6
9
3
2
6
JK
1
2
1
43
1
1
2
1
1
1
1
2
2
10
3
3
4
9
2
1
14
2
1
DERMAPTERA (EARWIGS) 1 Specimen Collected
Forficulidae
ORDER:
1
Forficulid Earwigs
DIPTERA (FLIES) 211 Specimens Collected
Anthomyiidae
Anthomyiidid Flies
14
Asilidae
o
ro
AB
COLEOPTERA (Continued)
Robber Flies
76
1
4
4
8 11
10
4
2
8
3
2
Midges
7
1
• 4
Blow Flies
1
Bibionidae
March Flies
Bombiliidaea>b
Bee Flies
Calliphoridae
Chironomidae
Chloropidae"
Culicidaea'u
Mosquitoes
Dolichopodidae
Long-Footed Flies
Drosophilidae
Mycaidae
Vinegar Flies
Fungus Gnats
Mydas Flies
Muscidae
Muscid Flies
Pipunculidae
Bigheaded Flies
Mycetophilidae
4
4
Chloropid Flies
3
16
2
2
3
1
18
23
:
17
3
1
4
1
3
2
1
1
16
1
2
2
2
2
9
1
1
3
2
1
4
|..
_
1
�TABLE V-4. CONTINUED
!NUMBER
COMMON NAME
FAMILY
ORDER:
TOTAL
SPECIMENS
AB
BC
OF SPECIMENS COLLECTED ON TRANSECT
CD
Tabanidae
Sepsid Flies
Flower Flies
Horse Flies, Deer Flies
Tachinidae
Tachina Flies
Tipulidae
Crane Flies
1
1
Tripetidae
Trypetid Flies
4
Syrphidae
ORDER:
11
3
9
1
GH HJ
JK
KL
LM
MN
NO
5
1
2
9
7
1
1
1
)
1 |
3
I
1
HEMIPTERA (TRUE BUGS) 390 Specimens Collected
Belastomatidae
CO
FG
DIPTERA (FLIES) (Continued)
Sepsidae
o
EF
DE
Giant Water Bugs
Coreidae
Coreid Bugs
3
2
Corimelaenidae
Corimelaenid Bugs
5
5
Cydnidae
Cydnid Bugs
2
Gerridae*
Water Striders
Lygaeidae
Lygaeid Bugs
Miridae
Nabidae
Plant Bugs
Xeididae
Neidid Bugs
Nepidae
N'otonectidae
Water Scorpions
Backswimmers
Pentatomidae
1
138
2
4 38
10
19
40
6 19
1
1
8 15
3
,3
9 14
2
7
5
4 18
1 |
71
1
2
Stink Bugs
82
2
Reduviidae
Assassin Bugs
49
1
Scutelleridae
Scutellerid Bugs
37
Damsel Bugs
7
1
2
4
1
7 22
1 11
2
3
13
14
1
12
ft
1 13
6
2
4
1
1
7
2
1
�TABLE V-4. CONTINUED
NUMBER OF SPECIMENS
TOTAL
SPECIMENS AB BC CD DE EF
FAMILY
COMMON NAME
ORDER: HOMOPTERA (TRUE BUGS) 360 Specimens Collected
1
4
Aphidae
Plantlice
1 2 1
Cercopidae
Spittlebugs
9
Cicadellidae
10 30 46 54 41
Leafhoppers
343
a b
Coccidae '
Scale Insects
Fulgoridae
1
Fu Igor id Planthoppers
Membracidae
3
Treehoppers
ORDER: HYMENOPTERA (BEES, WASPS, ANTS) 125 Specimens Collected
Apidae
1
Apid Bees
Bombidae"
Bumble Bees
1 1 1 2
Braconidae
Braconid Wasps
11
Chalcididae
2
Chalcids
Chrysididae
1
Cuckoo Wasps
Cynipidae
Gall Wasps
2
Formicidae
1 2
12
Ants
Halictidae
2 1
Sweat Bees
3 1
25
Ichneumonidae
Ichneumon Wasps
3
Megachilidae
Leafcutting Bees
2
1
Mutillidae
Velvet Ants
4
3
Pamphiliidae
1
1
Webspinning Sawflies
5
Pompilidae
Spider Wasps
6
COLLECTED ON TRANSECT
FG
GH HJ
JK
KL
1
1 1
1 1 3
80 21 29 10 10
2
LM MN
NO
2
2
10
1
1
1
1
1
1
3
1
2
2
6
12
2
5
1
1
1
2
1
1
1
2
1
1
1
2.
1
�TABLE V-4. CONTINUED
NUMBER OF SPECIMENS COLLECTED ON TRANSECT
TOTAL
AB BC CD DE EF FG GH HJ JK KL LM MN NO
COMMON NAME
SPECIMENS
FAMILY
ORDER: HYMENOPTERA (BEES, WASPS, ANTS) (Continued)
1
1
Scoliidae
Scoliid Wasps
1 2 4 6 2
2 2
1
Sphecidae
Sand Wasps
46
6 20
4
Tiphiid Wasps
4
Tiphiidae
Carpenter Bees
Xylocopidae
ORDER: ISOPTERA (TERMITES) Observed Only
Rhinotermitidae Subterranean Termites
ORDER: LEPIDOPTERA (BUTTERFLIES AND MOTHS) 38 Sp-cimens Collected
Danaidae
Milkweed Butterflies
Geometridae '
Geometrid Maths
a D
Lycaenidae '
Blues and Coppers
Hesperiidae '
Skippers
Microlepidopter* Several Families
23
5 3
Noctuidae
1
1
Owl Moths
a b
Nyrophalidae '
Brushfooted Butterflies
Papilionidae ' Swallowtail Butterflies
Pieridae*'11
Sulfurs
*
~
Psychidae
Bagworm Moths
Pyralidae
Pyralid Moths
14
3 1 2 1
i
'Several families in this group, but identified no further
�TABLE V-4. CONCLUDED
NUMBER OF SPECIMENS COLLECTED ON TRANSECT
THTiT
FAMILY
ORDER:
Green Lacewings
Brown Lacewings
Ant lions
CD
DE
EF
FG
GH
HJ
JK
KL
LM
1
1
MN
5
NO
1
8
Dragonflies
Damselflies
Dragonflies
Damselflies
Dragonflies
1
25
2 21
15
1
1
1
1
14
ORTHOPTERA (GRASSHOPPERS AND CRICKETS) 74 Specimens Collected
Acrididae
Grasshoppers
Gryllidae
Crickets
Gryllotalpidae* '"Mole Crickets
Mantidae
Mantids
Tettigoniidae
Katykids
Trydactylidae
Pygmy Mole Crickets
ORDER:
BC
ODONATA CDRAGONFLIES AND DAMSELFLIES) 40 Specimens Collected
Aeshnidae
Coenagrionidae
Corduliidae0
Lestidaeb
Libel lulidae
ORDER:
AB
NEUROPTERA (NERVE WINGED INSECTS) 9 Specimens Collected
Chrysopidae
Hemerobaeidae
Myrmeleonidae
ORDER:
SPECIMENS
COMMON NAME
TRICHOPTERA (CADDISFLIES)
Family not determined
58
Observed Only
1
6
1
6
8 16
1
3
6
3
6
4
2
4
23
7
1
4
7
7
1
4
1
5
1
1
1
1
1
�s?
o
< 100.
cc
90
—
t-
40
-
£
20.
2
>
0
70
ZP- ?P-i
nnni1ft
40
Ti n
30
AB BC
CD
DE
EF
500.
450.
Q 400 .
FG
GH HJ
JK
40
KL
LM
MN NO
52
i
| l
§ 350.
K 300.
I
£ 250.
< 200 .
u. 150
O
. 100 .
o<trt
A
50.' 50
0
"n
i
90
!0
> 80.
R
u 60-
AB
r
J£
\
BC
n
96
Ifl
V
147
CD
DE
1fi|
FiFiflrin
EF
FG
GH
jJ4_
HJ
JK
KL
LM
MN
NO
48
U)
%
50.
I
£
Q
O
O
40-
fE
CC
20.
u.
O
10.
31
M.
22.
-18
2i
AB
BC
^1
nnnf
5
113
n
17
CD
DE
EF
FG
GH HJ
JK
17 ,
KL
LM
MN
NO
9.
U
8.
t
7
6.9
•*__
-
(A
5.9
Q
4.4
0
cc
z
KCC
4.6
5-
4
4.2
—
„„ «
'
•JL
-
3.8
iZ
4.1
f"
3.
P
i
0
2 1 -
0
AB
BC
CD
DE
EF
FG
GH
HJ JK
KL
LM
MN
NO
400 FOOT GRID TRANSECTS ON SAMPLER ROW 8
Figure V-1. Arthropod/Vegetation Comparisons on TA C-52A, 1971 Study
107
�Ul
0
K
Ul
10Q.
>
0
ui
90
80
6Q
3D
60_
UL
Bj
§' ff °
I1V13D3A
^
70
OS,
SO
p
i
40 40
JK
KL
LM
98
77
81
J23.
HJ
JK
KL
LM
40
AH
BC
CD
DE
EF
FG
GH HJ
nnnn*
MN
NO
MN
NO
CO
O 400.
2
339
§300.
X
N
248
< 200.
21
LL
0
n ft
d ioo- ' 55
z
o
AB
BC
CD
DE
n
EF
172.
FG
GH
to
Ul
i
£ 40.
0
2
0
cc
36
29
fl
30 -
X
I- 20 .
K
nL
Ul
>
_
27 ^
27
BC
CD
DE
EF
FG
76-
__
5.6
5.1
§
££J
KL
LM
MN
NO
5.6
!^
4.4
3-
cc
JK
pa
4.2
Q
4-
MM
GH HJ
6.8
•—
5_
Q
21
121
19
AB
>
H
tt
28
31
m
.
n
"~
4.6
^^
f*1
A
r^
2.9
~*
I 2 .
1 1.
AB
BC
CD
DE
EF
FG
GH HJ
JK
KL
LM
2.4
MN
NO
Hn
400 FOOT GRID TRANSECTS ON SAMPLER ROW 8
Figure V-2. Arthropod/Vegetation Comparisons on TA C-52A, 1973 Study
108
�similarities exist. The diversity index used was that of Margalef:
In N
Where
d = diversity
S = number of Taxa
N = number of specimens
In = natural log
This formula has been used in previous diversity studies on Test Area C-52A (References V-3
and V-4), and it is used elsewhere in the present report. The greatest diversity of Arthropods as
indicated by this formula was in transect GH in both surveys, even though the adjacent transect
FG showed equal or greater amounts of vegetation (due to the presence of standing water in this
area). The greater diversity in GH is due to a large number of taxa relative to the total number of
Arthropods present. This large number of different organisms is likely due to the existence of a
wider variety of available niches in transect GH, which includes influences of the adjacent aquatic
area, dry sandy areas, and areas more disturbed by man. (The central sampling tower of the test
area is located in this transect.)
Other factors would be of interest in comparisons of the 1971 and 1973 data, such as the relationship of Arthropod population biomass to vegetative cover. While this biomass-vegetation comparison would ideally show a close correlation, two factors make it impractical. First, the influence
of randomly caught large insects (especially the grasshoppers) on biomass data would be quite
confounding until a great deal of replication had produced a representative sampling of these
animals. Second, the 1971 insect survey considered factors other than biomass, so there is no
direct basis for comparisons. Many of the other topics that were discussed in the 1971 study
hold equally true at this time. Experimental biases of the sweep net technique factors affecting
plant distribution, and plant-insect relationships are discussed in Reference V-1.
4. SUMMARY AND CONCLUSIONS
A sweep net survey of the Arthropods of Test Area C-52A on the Eglin AFB Reservation
resulted in the collection of over 1,700 specimens belonging to 66 insect families and Arachnid
orders. These totals represent only one of five paired sweeps taken over a one-mile section of the
test grid. A similar study performed in 1971 produced 1,803 specimens and 74 families from
five paired sweeps of the same area using the same basic sampling techniques. A much greater
number of small to minute insects were taken in the 1973 survey. Vegetative coverage of the test
area had increased since 1971. The two studies showed similarities in distribution pattern of
vegetative Arthropod numbers, number of Arthropod \ varieties, and Arthropod diversity. Generally,
the present study showed a reduction of the extremes found in the above parameters in the 1971
study. This result is expected to continue as the test area stabilizes and develops further plant
cover, thus allowing a succession of animal populations to invade the recovering habitat.
References:
V-3. Boror, D. J. and D. M. DeLong: An Introduction to the Study of Insects. New York,
Rinehart. 1952.
V-4. Lehn, P. J., A. L. Young, N. A. Hamme, and B. C. Wolverton: Studies to Determine the
| Presence of Artificially Induced Arsenic Levels in Three Freshwater Streams and its Effects of
I Fish Species Diversity. AFATL-TR-70-81, Air Force Armament Laboratory, Eglin AFB, Florida.
August 1970. Unclassified.
109
�SECTION VI
AQUATIC STUDIES OF TEST AREA C-52A
One of the major parameters involved in the process of herbicide movement and/or
persistence in soils is the adsorptive capacity of the soil. The adsorptive capacity, or
the cation exchange -capacity (i.e., the ability of a cation to be displaced or exchanged from the
soil by another cation), is closely associated with the inorganic colloids (e.g., clay particles)
and organic colloids (e.g., organic matter) of the soil. A soil with a large cation exchange
capacity could bind within its colloidal system a large concentration of herbicide. Soils with
a low cation exchange capacity do not retain cationic herbicides (e.g., cacodylic acid or sodium
cacodylate), and thus, soil leaching of these herbicides would be expected. From June 1969
to October 1970, 4,395 gallons of military herbicide Blue were disseminated on TA C-52A
(Table I-7). Approximately 13,624 pounds of cacodylic acid and sodium cacodylate were
sprayed onto an area of less than one square mile. The soil of the test area has a low cation
exchange capacity of approximately 0.8 mg exchangeable cation per 100 g of soil (Table I-4),
while the annual precipitation of the area is high (Table 1-1). Data from the analyses of soil
cores for arsenic (Table II-9) confirm the movement and/or disappearance of arsenic from
the test grid. Moreover, Table II-7 suggests that picloram, a component of the herbicide
White, has moved within the soil profile and is apparently rather residual in nature.
Test Area C-52A is drained by five streams: Mullet, Trout, Basin, Grassy, and Pucker
Creeks (Figure VI-1). The combined annual flow from these streams exceeds 24 billion
gallons of water. However, only Mullet, Trout, and Basic Creeks are closely associated with
the test grid. The mean daily flow rate for these three streams is shown in Table VI-1. As
previously noted, studies on the movement of arsenicals and picloram indicated the possibility of herbicides contaminating the three freshwater stream communities draining the test
grid. Since arsenical residues may concentrate in the tissue of fish, and particularly in the
tissue of oysters, studies were conducted in 1969 and 1970 to determine (1) whether arsenic
residues were entering the streams from the test grid and (2), if so, whether these residues
were having adverse effects on the fish populations in the streams or were accumulating in
oysters found at the mouth of streams adjoining Choctawhatcheee Bay. Synopses of these
studies (Reference VI-1) are included in this report.
1. SYNOPSIS OF PREVIOUS RESEARCH, 1969
a. Fish Study
To assess the effects of possible arsenic residues, a diversity index study of the fish
populations of Mullet, Trout, and Basin Creeks was initiated 3 months prior to the aerial
spraying of Blue and continued for approximately 4 months after spraying.
Of the three streams under investigation, Trout Creek seemed the most likely to receive
herbicide residues from the grid area. The headwaters of the stream are at the bottom of steepReference:
VI-1. Lehn, P. Jeffery, A.
the Presence of Artifically
on Fish Species Diversity.
Force Base, Florida, 1970.
L. Young, N. A. Hamme, and B. C. Wolverton: Studies to Determine
Induced Arsenic Levels in Three Freshwater Streams and its Effects
AFATL-TR-70-81, Air Force Armament Laboratory, Eglin Air
Unclassified.
110
�1 MILE
LITTLE
BASIN
CREEK
\
)
BASIN
SPRAY FLIGHT PATH
|BAS IN
BAYOU
EAGLE
CRtEK
CHOCTAWHATCHEE BAY
Figure VI-1. Map of Test Area Showing Streams in Relation to Test Grid and Location
of Sampling Stations Used in Arsenic Monitoring Study
111
�TABLE VI-1. CHARACTERISTICS OF SAMPLING SITES ON
STREAMS DRAINING TEST AREA C-52A
NAME
Temperature,
Range, °C
Mean
PH
Width,
Feet
Depth,
Feet
Bottom
Material
Mean Flow Rate,
gal/day
Basin Creek
16-23.5
5.8
to 12
to 4
Sand
39,073,000
Mullet Creek
14-23.0
6.0
to 10
to 2
Sand
3,648,000
Trout Creek
13-23.5
6.1
to 15
to 2
Sand
5,870,000
Little Basin
Creek3
(Control Stream)
15-22.5
6.0
to 8
to 3.5
Sand
3,450,000
a
Does NOT drain TA C-52A
sided bayheads adjacent to the edge of the grid and directly in line with the lower extremities
of the repeatedly used spray flightpath (Figure VI-1). From its headwaters, the stream flows
approximately 2 miles directly south into Choctawhatchee Bay. As the stream nears the bay,
it deepens to several feet and has a heavy deposit of leaves and other organic matter on the
bottom.
Mullet Creek has portions of its headwaters originating in steep-sided bayheads within
0.5 mile of the west boundary of the spray grid and flows south for approximately 2.5 miles
into Choctawhatchee Bay, deepening near its mouth with a heavy deposit of leaves and other
organic matter on the bottom (Figure VI-1).
The headwaters of Basin Creek originate several miles to the north of the spray grid.
The stream flows southeast within 0.25 mile of the northeast corner of the grid and joins
with a small tributary originating at the north margin of the grid, continues east for approximately 3.5 miles, and turns south for 2.25 miles emptying into Basin Bayou and Choctawhatchee
Bay (Figure VI-1).
Six sampling stations were established on the three streams: One on Mullet Creek, two
on Basin Creek, and three on Trout Creek (Figure VI-1). The selection of sampling station
locations was determined mainly by their accessibility, variation of habitat within the station,
and apparent fish populations. Because of the number of stations and time involved, they were
not all sampled on the same day.
On each sampling date, observations were made in an effort to detect any gross changes
in the population levels of the following selected benthic organisms: crayfish (Orconectes sp.).
dragonfly naiad (Gomphus sp.), freshwater snail (Neritian sp.), and an unidentified immature
freshwater clam. Observations were also made to detect any morphological effects that may
have occurred to eelgrass (Vallisneria americana). the only species of vascular aquatic plant common
to all stations.
112
�Fish were collected with a variety of seines ranging in length from 4 to 15 feet and in
mesh size from 1/8 to 1/4 inch. All represented habitats within each station were sampled
randomly, and the time of day that the samples were taken was also varied. For the first
several weeks of the survey, the fish were returned to the stream after the total catch was made
and counted; however, for the remainder, and majority, of the survey, the fish were preserved in
10% formalin and counted in the laboratory. In conjunction with the stream sampling, two
ponds on the test grid were sampled using dip nets.
b. Residue Sampling
Samples were routinely collected at 11 stations on the streams and in Choctawhatchee
Bay after each rainfall following herbicide missions, or, if no missions had been flown, samples
were collected monthly. Water from these streams was sent to the Regional Environmental
Health Laboratory, Kelly AFB, Texas, where it was analyzed for arsenic. Detritus (bottom)
samples were taken monthly with an Eckman dredge at three randomly selected water sampling
locations. After appropriate pretreatment, these were assayed in the same manner as the water
samples.
In addition to water and detritus sampling, oysters were used to monitor changes in
arsenic level. Because these mollusks are filter feeders, the arsenic content of their bodies was
correlated with that of their environment.
Oyster racks were established in Choctawhatchee Bay at the mouths of Basin, Trout,
Grassy, Mullet, and Rucker Creeks. A control rack was also located in the bay at the mouth
of Eagle Creek, which does not drain the grid area (Figure VI-1). Each rack contained
approximately 2,000 oysters in the 1 to 3 inch diameter range, and these were sampled
periodically. The small size of the oysters was intended to discourage removal from the racks.
Samples obtained from the racks were frozen and taken to the laboratory for analysis. There
the sample was acidified, hydrolyzed, and neutralized before undergoing standard atomic
absorption analysis for arsenic (Reference VI-2).
Water samples were collected for picloram analysis from a small bayhead of Basin
Creek just north of sampler station A-11. The bulk of herbicide White was disseminated on
Grid 3, with the remainder being sprayed on Grid 4 (see Section I, Figure I-5 and Table I-7).
Thus, most of picloram was probably concentrated around the northern portion of the one square
mile area. Other water samples for picloram analysis were collected in the bayhead of Long
Creek, which is located approximately 3 miles northwest of the one square mile grid and which
has a water source not associated with TA C-52A.
c. Results
Twenty-one species of fishes were collected, with three species occurring within the
boundaries of the one square mile grid and 20 species from the surrounding streams (Table
VI-2). Habitat and spatial isolation seemed to be the major limiting factors on the grid.
Reference:
VI-2. Hamme, N. A., A. L. Young, J. H. Hunter: A Rapid Analysis of Soil and Water by
Atomic Absorption. AFATL-TR-70-106, Air Force Armament Laboratory, Eglin Air Force
Base, Florida, 1970. Unclassified.
113
�TABLE IV-2. FISH SPECIES FOUND IN PONDS AND DRAINAGE AREAS OF THE
ONE SQUARE MILE GRID AND IN BASIN, MULLET, AND TROUT
CREEKS
SPECIES AND COMMON NAME
AREAS WHERE COLLECTED
ON GRID
1
Amhlnplitfis rupflstris - snnthfirn rnnk hass
-
2. Anguilla rostrata - American eel
OFF GRID
+B
+BT
3. Aphredoderus sayanus - pirate perch
-
+BT
4. Elassoma okefenokee - Okefenokee pigmy sunfish
+T
5. Erimyzon sucetta - lake chubsucker
+*
6. Esox arpericanus - red-fin pickerel
-
+B
7. Esox niger - chain pickerel
-
+B
8. Etheostoma edwini - brown darter
-
+BT*
9. Fundulus nottj - starhead topminnow
-
+T
10. Gambusia affinis - mosquito fish
-
+BMT*
11. Ichthyomyzon gagei - southern brook lamprey
-
+BM
12. Ictglurus natalis - yellow bullhead
+
-
13. Lepomis punctatus - spotted sunfish
+
+BMT
14. Micropterus punctulatus - spotted bass
-
+T
15. Minytrema melanops - spotted sucker
-
+B
16. Notropis hypselopterus - sailfin shiner
-
+BMT*
17. Notropis texanus - weed shiner
-
+B
18. Noturus funebris - black madtom
-
+T
19. Noturus gyrinus - tadpole madtom
-
+T
20. Noturus leptacanthus - speckled madtom
-
+BMT*
21. Percina nigrofasciata - blackbanded darter
-
+BMT*
* Denoted large population in area.
B = found in Basin Creek
M = found in Mullet Creek
T = found in Trout Creek
114
-
�The lake chubsucker was abundant in one of the ponds on the grid but was not found in the
three streams within a 2 mile radius of the center of the grid, however, the species occurs
several miles downstream in more sluggish waters. The employment of a diversity index
(i.e., a statistical comparison of the fish populations before and after the spray missions,
representing a time period of 8 months) showed a population change in one fish species at one
of the six stations studied. This change, however, was probably due to an unidentified variable
(e.g., variation in collecting techniques) rather than to arsenic residue. The arsenic analyses for
588 water samples and 68 silt samples were negligible (less than 1 ppm and not significantly
different from control streams). A comparison of arsenic contents of 73 oyster samples taken
from sampling stations established in Choctawhatchee Bay showed no significant differences
from control samples taken elsewhere in the bay at the 95% probability level (1.32 ppm
arsenic versus 1.45 ppm).
The results of water samples collected from Basin, Trout, and Long Creeks, and
analyzed for picloram content are shown in Table VI-3. Picloram residues were still being
detected in the small bayhead north of sampler station A-11 as late as December 1971.
The last mission with herbicide White was in May 1970.
TABLE IV-3. RESULTS OF CHEMICAL ANALYSIS OF WATER SAMPLES FOR
PICLORAM, 1971 DATA
SAMPLE LOCATION
DATE COLLECTED
PICLORAM8, ppb
Basin Creek, North of Sampler
Station A-11 in NE Corner of
one square mile grid
11 Jun 1971
11
Trout Creek, South of Sampler
Station 0-11 in SE Corner of
one square mile grid
11 Jun 1971
2.4
Basin Creek, same as
June 1971 location
3 Dec 1971
11, 9.4
Trout Creek, same as
June 1971 location
3 Dec 1971
1.4
Control; Long Creek,
approximately 3 miles from
one squane mile grid
11 Jun 1971
<0.1
a
Analysis performed by the Dow Chemical Company; Method ACR 68-14
115
�2. CURRENT STUDIES OF AQUATIC ORGANISMS
The objectives of the current studies were (1) to reaccomplish the 1969 - 1970 aquatic
studies and to compare population and diversity data, (2) to accomplish an in-depth survey
of the aquatic organisms in the test grid ponds, and (3) to obtain samples of aquatic vertebrates
from streams and grid ponds for arsenic and TCDD residue analyses.
a. Methods and Materials
Sampling of the ponds on TA C-52A was accomplished using dip nets and, where aquatic
vegetation permitted, a 4 by 15 foot seine and a variable mess gill net. Sampling of the ponds
was performed twice with identical collection methods employed both times. Tadpoles (Rana
pipens subsp. sphenocephala Hyla gratiosa) and lake chubsuckers (Erimyzon sucetta) were
frozen for arsenic and TCDD residue analyses. Those aquatic organisms caught only for species
diversity and relative quantity were preserved in 10% formalin. Tadpoles were also collected
at a control pond (north of TA C-52A) and were frozen for TCDD residue analysis.
Sampling of the streams draining TA C-52A (Mullet, Trout, and Basin Creeks) and the
control stream (little Basin Creek) was accomplished also using the 4 by 15 foot seine. Approximately 100 yards of each stream was worked for 2 hours. The identical sampling technique was
employed, and each stream was sampled three times. (This technique was that described in
Reference VI-1). Species collected only for diversity and relative quantity were preserved in
10% formalin. Crayfish (Ordonectes sp.), speckled madtoms (Noturus leptacanthus). brown and
blackbanded darters (Etheostoma edwini) and (Percina nigrofasciata) and any larger fish, e.g.,
redfin pickerel (Esox americanus) and spotted sunfish (Lepomis punctatus). were frozen for
subsequent analysis of TCDD and arsenic residue. The selection for residue analyses of the crayfish and smaller fish species was based on the fact that they are bottom feeders or primary/secondary
consumers and thus likely to ingest organic matter containing TCDD and arsenic. The larger fish
were selected for residue analysis because they had been in the stream for a longer time and were
predators, filling niches at the top of the aquatic food web - hence, a greater likelihood of residue
accumulation taking place if bio-magnification was occurring. In addition to these species, oysters
were collected for arsenic analysis from the mouth of Mullet and Trout Creeks where they drain
into Choctawhatchee Bay. The samples collected for TCDD analysis were sent to the Interpretive
Analytical Services Laboratory, Dow Chemical U.S.A., while the samples collected for arsenic
analysis were sent to the Pesticide Degradation Laboratory, United States Department of Agriculture. The analysis of arsenic was by atomic absorption of arsine generated with N2BH4All of the streams that were sampled for fish were also sampled for aquatic invertebrates.
Benthic samples were taken near the stream margins and in mid-stream at each station using a
modified Surber Sampler with number 15 mesh. The margins were covered with a thin layer of
organic debris and entangled with the root systems of neighboring plants, while the center of the
stream bed was composed almost entirely of sand. The sampler was sunk about 6 inches into the
stream bottom with the net on the downstream portion; then, the sand and debris enclosed by
the sampler were placed in the net - going down about 6 inches into the stream bottom. The
netting was taken to a deep spot on the stream and washed so that sand and debris would pass
out through the netting. The remaining contents in the mesh were transferred into an enamel pan.
The debris was examined, and all invertebrate organisms were removed and placed in plastic bottles
containing water from the stream. The bottles were labled and taken to the laboratory. There,
the organisms were placed in boiling water for 5 minutes, transferred to containers with 70%
ethanol solution, classified, and counted.
116
�Ten-foot strip samples of the aquatic areas of the grid were taken by using an insect
net to make a 10 foot linear scoop along the bottom of the pond. The debris collected was
then sorted for invertebrate organisms. Figure IV-2 shows the location of the major bodies
of water at the time of survey, June 1973. It should be noted that the first 6 months of
1973 were abnormally high in rainfall, and thus, the 1973 survey showed more water on the
grid than observed in 1969 to 1971. The three aquatic invertebrate samples were taken from
the ponds located near sampler stations F-7, F-13, and G-13.
Biological specimens were forwarded to Dow Chemical U.S.A., Midland, Michigan for
determination of TCDD levels. Analysis was accomplished using a modification of the technique
of Baughman and Meselson (Reference VI-3).
b. Results and Discussion
Table VI-4 compares those fish species caught in the streams (draining TA C-52A) in
1969 (Reference VI-1) and those caught in 1973. The methods of collection and the sampling
stations were the same for both studies.
In order to compare the fish populations caught in 1969 with fiose caught in 1973, three
assumptions were made:
(1) That fish caught per sampling is proportional to the total fish population at that
site, so long as the methods employed are sufficiently similar.
(2) That the sampling methods remained sufficiently similar to justify assumption
one during all seining operations both in 1969 and 1973.
(3) That the frequency distribution of fish caught per sampling is approximately normal.
The data for fish populations per sampling for 1969 and 1973 can be shown as:
Sampling Period
Number of
Observations
Mean Number
of Fish Per
Sampling
Standard
Deviation
Before Spraying Blue
(Mar 1969)
36
84
29.6
After Spraying Blue
(Oct 1969)
16
84
49.2
1973 Sampling
13
141
60.2
As can be seen from these data, the fish caught per sampling before and immediately after
the dissemination of Blue in 1969 remained constant. Moreover, a significant increase in
fish caught per sampling occured in 1973 as compared to 1969. If the control stations
(Little Basin and Fox Creeks) are compared for population changes during this time period,
the following data are obtained.
Control Stations
Little Basin Creek
Fox Creek
1969 Means Per Sampling
81
83
1973 Means Per Sampling
94
84
Reference:
VI-3. Report Number IAS-405, Dow Chemical U.S.A., Midland, Michigan
117
�N
I
8
5
9
10
11
12
13
14
"W
B
•
G
H
r
•
•
*
'
•
*
sr
*
- •*
r^ •
•
TOWER X
• • I
——W»
V
M
N
Figure VI-2. Location of Water and Major Drainage Ditches on the One Square
Mile Grid of TA C-52A, 1973 Data
118
�TABLE VI-4. FISH SPECIES COLLECTED IN 1969 AND 1973 FROM THREE STREAMS DRAINING
TA C-52A AND A CONTROL STREAM
COMMON NAME
TROUT CREEK
MULLET CREEK
BASIN CREEK LITTLE BASIN^
1969
SPECIES
1973
1969
1969
1973
1969
1973
1973
Notropis
hvpselopterus
sailfin shiner
+°
+
+
+
+
+
+
+
Gambusia affinis
mosquito fish
+
+
+
blackbanded darter
+
+
+
Percina
niorofasciata
+
+
+
+
+
+
+
+
+
+
Etheostoma edwini
brown darter
+
+
+
spotted sunfish
speckled madtom
+
+
+
+
+
+
+
+
+
+
Lepomis punctatus
Noturus
leptacanthus
+
+
+
+
+
+
+
+
+
+
+
Ichthvomvzon
gagei
southern brook
lamprey
-c
+
+
+
+
+
+
+
Notropis texanus
weed shiner
+
+
Esox niqer
chain pickerel
+
—
Aphredoderus
savanus
pirate perch
+
+
+
+
+
+
Esox americanus
redfin pickerel
—
+
Anquilla rostrata
American eel
+
—
Minvtrema
melanops
spotted sucker
—
+
.+
+
+
+
+
—
a
Control Stream
D
Species Present (+)
Species Absent (— )
G
+
+
_u
—
—
+
+
�TABLE VI-4. CONCLUDED
SPECIES
southern rock bass
TROUT CREEK
MULLET CREEK
BASIN CREEK
1969
Ambloplites
rupestris
Muqil ceohalus
COMMON NAME
1969
1969
—
—
common mullet
Ictalurus
natalis
yellow bullhead
Micropterus
punctulatus
spotted bass
+
to
o
Control Stream
1973
1969
1973
—
+
+
+
—
1973
+
—
a
1973
LITTLE BASIN3
+
—
�There is no significant change in the fish populations at the control sites. There are insufficient
data on other variables (e.g., nutrient fluctuations), on other environmental factors, or on food
chain growth data to warrant pinpointing the direct cause of the fish population increase other
than that it appears to be associated with the general recovery phenomenon of vegetation,
animal, and insect populations as noted in other sections of this report.
The species diversity was determined by the same method employed in the 1969 study
(Reference VI-1). The mean diversity for 1969 (before and after the spraying of Blue) and
1973 for the control sites are:
Control Sites
Number of
Samplings
Mean
Diversity
Standard
Deviation
Variance
Before Blue, 1969
36
0.9779
0.3049
0.0930
After Blue, 1969
16
1.3286
0.4903
0.2404
1973 Sampling
13
1.5934
0.1952
0.0381
The 1973 sample size of 13 may be too different from that of 1969 to compare diversity
indices. The dependence of the diversity index (d) on the number of samples taken (N) may
exist in such a way as to bias d when large or small values of N are used. If the diversity
index is plotted as a function of N (using actual data) then the difference in d values before
and after spraying Blue (and hence, the 1973 data) is too greatly dependent on N to use
without either correcting for the sample size difference or re-sampling (thus using nearly the
same sample sizes) A correction technique was employed. A description of this method is
included and is in fact an analysis of the diversity of species using Monte Carlo normalized
diversity indices.
In attempting to make comparisons between d values it appeared desirable to
factor out the influences of N by making all N's the same. A small simulation was
undertaken in which the observed frequency of species was assumed to be the
expected value. A sample size of 80 was chosen as the common sample size because
it is near the mean of the actual sample taken. Then, using the observed distribution
to establish the probability of the occurrence of each species, 80 "fish" were drawn
from the population. This closely simulated the process in which fish are captured
until exactly 80 were caught in each sample and then the specimens classified and
the data tabulated. One source of error for the simulation is the fact that the number
of species, S, cannot exceed the S value for the observed case; i.e., if a species did
not appear in the original sample, then the probability of its appearance in the
"redrawn" sample is zero. This error, however, should be insignificant in cases where
the original sample size was 30 or larger.
In a further effort to make comparisons of diversity more meaningful, the
expected values of sample size, Ne, and expected number of species, Se, were
calculated assuming that the variety of fish life had not decreased; i.e., the d value
now is no worse than the d value for the time period before the herbicide was applied.
A comparison of Ne and Se were made with the respective observed values N0 and S0.
121
�The equations used are:
and
S e = d log e (N + 1 )
The d values were calculated for the redrawn samples. The only tendency, if any, was
for the diversity index to increase after spraying. Linear correlation coefficients between
d and average sample size compared to distances of the sampling stations from the
center of the spray area were very small and insignificant. The Se and Ne values for
1969 both before and after spraying were compared to those for 1973 using the two
control sites to establish the expected diversity index. In both cases S0 was 10 to 20
percent higher than Se, and Ne was grossly larger than NQ. These observations both
tend to imply that the collecting sites considered to be within the spray zone are
richer in fish life than the control sites outside the spray zone.
By using the correction technique on the mean diversity for the control sites only,
a chronologically higher diversity in fish is evidenced from before spraying Blue in 1969,
through the after spray period, to the 1973 sampling.
Control Sites
Before Blue
1969 Diversity
After Blue
1969 Diversity
1973 Diversity
Little Basin
1.324
1.806
1.770
Fox Creek
1.138
1.212
1.580
This same trend was noted for the streams draining'the test area. However since the control
sites are assumed to be either too far away from the grid area to be affected by the herbicides or are experiencing the recovery phenomenon noted for TA C-52A, no significant changes
are evident in the diversity of fish life from 1969 to 1973.
In order to compare the species proportions for the 1969 data to the 1973 data, the
following assumptions were made:
(1) That the average of the percentages of a given species found in the sample is
a reasonable estimate of the actual percentage of that species in the fish population in the
stream.
(2) That the percentages of rare species found in the samples are not valid for
comparisons because sample sizes are not large enough for a sufficiently high confidence in
the percentages.
122
�Using these assumptions, only the two most common species were compared from the 1969
and 1973 data for significant changes. The rare species, therefore, were treated as part of
the general diversity analysis.
Table VI-5 compares the 1973 mean percentages for the sailfin shiner (Notropis
hypselopterus) and the mosquito fish (Gambusia affinis) to the 1969 data of before and after
spraying of Blue and the combined mean for 1969. The significance of the differences was
tested using the t test. The sailfin shiner had a significant decrease in its proportion of the
fish population in 1973 as compared to the before spray (March 1969) fish populations, but
the difference was not significant when 1973 data were compared to after spray data
(October 1969). For the overall comparison, however, of 1973 data to 1969 data (combined)
no significant difference existed. If data for the sailfin shiner are compared only for the
control sites a significant decrease occurs in the percent of the population between the
March 1969 data and the 1973 data. However, such a significant decrease does not occur
when 1973 data is compared to October 1969 data.
Control Station
March 1969 Means
1973 Means
October 1969 Means
Little Basin
0.869
0.623
0.788
Fox Creek
0.928
0.714
0.758
As a result of these data, it is apparent that some factor (unrelated to the herbicide or
recovery phenomenon) was at work between the spring of 1969 and the fall of 1969. As
a result, it is more prudent to assume no significant proportional changes existed between
spring 1969 and 1973 for the most abundant species.
The three aquatic areas on the grid were observed to be areas of 80% to 100%
vegetative cover with the vegetation chiefly composed of grassy plants. The pond at station
F-7 is located on Rutledge Sand, and the ponds at F-12 and G-13 have Chipley Sand underlying them. The F-7 pond had a pH reading of 5.51 and was heavily congested with algae
and aquatic grasses. The two other ponds had a pH reading of 6.39 and were much less
overgrown with aquatic grasses and algae. Both of the ponds were known to be intermittent;
partially drying up once in the last 5 years. An alligator was sighted in F-7 pond and two
6-inch lake chubsuckers (Erimyzon sycetta) were taken from it. In the east grid ponds (F-12
and G-13), sightings were made of turtles, but no fish were taken from these ponds. The
results of bottom sampling these ponds for specimens of invertebrate are shown in Table VI-6.
The dominant order is Odonata. Without exception, the members of this order are predacious;
therefore, their supply in these ponds must be relatively extensive.
The Serber sampling of the streams is shown in Table VI-7. Fox Creek yielded very
few aquatic organisms, either invertebrate or vertebrate. The yields of invertebrates were so
few, in fact, that Fox Creek was considered too different from Basin, Trout, or Mullet Creeks
to effectively serve as a control stream. Perhaps the low yield in organisms in Fox Creek is
related to its depth (mean depth of 18 inches with pools reaching to five feet) and/or
swiftness. The majority of the organisms found in the other three streams were caddis fly
larvae and snails. The caddis fly larvae are omnivores, while the snails are herbivores.
Presumably, there is an extensive food web associated with these invertebrates that was not
sampled by the Serber sampler.
123
�TABLE VI-5. POPULATION CHANGES IN THE TWO MOST COMMON FISH
SPECIES (ALL SITES ARE GROUPED TOGETHER) 1969 AND
1973 DATA
SPECIES
DATE
NUMBER OF
OBSERVATIONS
MEAN
STANDARD PROBABILITY OF
DEVIATION CHOOSING SAMPLES
WITH MEANS
HAVING THIS OR
GREATER
DIFFERENCE
Notroois
hypselopterus
Mar 1969
8
0.79
0.117
0.0 1a
Oct 1969
8
0.58
0.172
0.94
16
0.69
0.179
0.91
Jun 1973
5
0.51
0.161
Mar 1969
8
0.102
0.101
0.92
Oct 1969
8
0.188
0.132
0.99
16
0.145
0.122
0.96
5
0.182
0.194
Combined
1969
Gambusia
affinis
Combined
1969
Jun 1973
a
95% level of significance
TABLE VI-6. NUMBER OF AQUATIC INVERTEBRATE SPECIMENS
COLLECTED FROM BOTTOM SAMPLING THREE PONDS
ON TEST AREA C-52A8
ORDER
LOCATION OF PONDSb
COMMON NAME
F-7
F-13
G-13
Coleoptera
scavenger beetle
0
1
0
Hemiptera
backswimmers
giant water bugs
3
0
10
1
6
0
Odonata
dragonflies/
damsel flies
10
2
8
17
1
9
Trichoptera
caddis flies
1
0
0
16
37
16
Total Specimens
a
Each sample represents three collections with a 1 -square foot Serber Sampler
"Ponds designated by the closest permanent sampler station
124
�TABLE VI-7. NUMBER OF AQUATIC INVERTEBRATE SPECIMENS
COLLECTED FROM BOTTOM SAMPLING THE STREAMS
DRAINING TEST AREA C-52A8
ORDER
COMMON NAME
CREEK
FOXb
MULLET
TROUT
BASIN
10
11
10
1
5
8
1
1
19
1
0
48
96
15
0
0
Annelida
aquatic earthworms
Coleoptera
Decopoda
beetles
crayfish
Gastropoda
snails
Odonata
dragonflies
0
0
2
2
Plecypoda
freshwater clams
0
0
9
0
Trichoptera
caddis flies
51
75
158
49
115
202
202
53
Total Specimens
a
Ten-foot strip sample from bottom of pond using a 15-inch insect net
'•'Control station
The results of residue analysis for arsenic in aquatic organisms are shown in Table
VI-8. The level of arsenic in the oysters svas considerably lower than those values reported
for oysters in 1970 - 1971 (average of 0.28 ppm arsenic versus 1.32 ppm, respectively). The
lower levels of arsenic in 1973 may be due to the employment of different analytical procedures or to the increased stream flow noted this year, and hence, to a greater purging of
the arsenic by the large volumes of freshwater entering Choctawhatchee Bay. No control
tadpoles were analyzed for arsenic content, but presumably the level of arsenic was probably
higher than it would be in control samples. This would be evident from data of the arsenic
levels in 1973 grid soils as shown in Table II-7 (Section II).
The results of residue analysis of aquatic organisms for TCDD are shown in Table VI-9.
The analysis were performed by the Interpretive Analytical Services, Dow Chemical U.S.A.,
Midland, Michigan. The duplicate samples were analyzed independently by high resolution
mass spectrometry (see Section II for methods and materials). Duplicate samples of all
biological specimens were also submitted to the Pesticide Degradation Laboratory, Agricultural
Environmental Quality Institute, Beltsville, Maryland, for an independent check on results.
However, none of the methods employed by the Degradation Laboratory could lower the limit
of detection below 0.1 - 0.2 ppb TCDD.
3. CONCLUSIONS
From examining the data, certain observations support the idea that a recovery phenomenon
is occurring in the streams draining TA C-52A. These observations are difficult to document
because of insufficient data. For example, in 1969 the southern brook lamprey (Ichthyomyzon
gagei) was never collected in Trout Creek, yet in 1973 it was taken in relatively large numbers.
It now appears that the lamprey is breeding in Trout Bayhead south of sampler station 0-11.
Moreover, all of the specimens of lamprey collected this year in Trout Creek are immature
125
�TABLE VI-8. CONCENTRATION OF ARSENIC IN BIOLOGICAL SPECIMENS
COLLECTED ON OR ADJACENT TO TA C-52A
BIOLOGICAL SPECIMEN3
(Common Name)
LOCATION COLLECTED
(June 1973)
Oyster
Mouth of Trout Creek
Oyster
Mouth of Mullet Creek
0.44
0.12
Blue Crab
Mouth of Trout Creek
0.32
Blue Crab
Mouth of Mullet Creek
0.32
b
CONCENTRATION OF
ARSENIC
( ^ g As/gram Fresh Tissue)
Crayfish
Little Basin Creek
Crayfish
Trout Creek
Black-banded Darters
Little Basin Creekb
0.29
0.30
0.75
Black-banded Darters
Trout Creek
0.15C
Speckled Madtom
Little Basin Creekb
0.30
Speckled Madtom
Trout Creek
0.38
Redfin Pickerel
Trout Creek
0.23
Tadpoles
Grid Pond (F-7)
1.47
a
Samples for analysis were either aliquots of homogenates or the entire homogenate
depending on sample size.
"Control Samples
c
Part of the tissue was lost in digestion of sample.
TABLE VI-9. CONCENTRATION OF 2,3,7,8-TETRACHLORODIBENZO-p-DIOXIN
(TCDD) IN BIOLOGICAL SPECIMENS COLLECTED ON OR ADJACENT
TO TEST AREA C-52A
BIOLOGICAL SPECIMEN9
(Common Name)
LOCATION
COLLECTED
Cub Sucker
Crayfish
Crayfish
Oyster
Rock Bass
Spotted Sunfish
Spotted Sunfish
Tadpole
Tadpole
Mouth of Trout Creek
Trout Creek
Control
Mouth of Trout Creek
Trout Creek
Trout Creek
Controlb
Grid Pond (F-7)
Control
CONCENTRATION OF TCDD
(parts per trillion)
a
<10
< 10
<10
<10
< 10
<10
<10
<10
<10
AII samples were run in duplicate and analyzed independently by high resolution mass
spectrometry.
b
Control locations are noted in text.
126
�indicating that the population was recently established (within the past two years). However,
statistical comparisons of 1969 and 1973 data confirm a chronologically higher diversity in fish
populations for even the control streams. Thus, the presence of the lamprey may or may
not reflect a change in the habitat due to recovery from herbicide exposure.
The data on picloram in waters draining from the test grid would support the need for
production studies of these streams. However, a review of toxicological data, for picloram
(Reference VI-4) suggests that concentrations of 1000 ppb do not seem to effect aquatic
organisms. Moreover, the lack of baseline data and adequate control streams would probably
make such studies futile or of doubtful value.
It is apparent from the results of samples analyzed for TCDD that representative organisms
living in streams draining Test Area C-52A or in the ponds on the test area were free from TCDD
contamination at a lower detection limit of less than 10 ppt. These data are not unexpected
knowing the low solubility of TCDD in water and its apparent lack of movement in the soil
profile (Reference IV-1).
Reference:
VI-4. Pimentel, David: Ecological Effects of Pesticides on Non-Target Species. Executive Office
of the President, Office of Science and Technology, June 1971.
127
�SECTION VII
STUDIES ON THE MICROFLORA OF TEST AREA C-52A
The soil persistence of herbicides is influenced by many environmental and biological factors.
Perhaps one of the most important of these is that of the presence or absence of microorganisms.
In an area such as Test Area C-52A, Eglin AFB Reservation, where the soils were subjected to repetitive
applications of four different herbicides (2,4-D, 2,4,5-T picloram, and cacodylic acid) over a
period of 8 years (1962 - 1970), the organisms had to either adapt to the presence of the chemicals
or be adversely affected (i.e., reduction in population). For this reason, studies were initiated to
examine population levels of various microflora found occurring on the one square mile grid.
The initial studies '° were conducted from 1967 to 1969. These studies provided data on the soil
algal populations and are included as a synopsis in this report. In June 1970, a survey was conducted®
of the soil bacterial, fungal, and Actinomycete populations found at specific sites on the grid and
in control areas. The data from this study (identified in this report as the 1970 study) have been
the basis for comparisons in the current study. In addition, the current studies also include a
preliminary examination of aquatic algae found in the ponds in the center of the one square mile
grid.
1. SYNOPSIS OF PREVIOUS RESEARCH , 1967 - 1970
In 1967, three areas were soil sampled for algal flora. Area I was Grid 1 located immediately
south of the present one square mile grid. This area received a total accumulative concentration
of 1,894 pounds of 2,4-D,and 2,4,5-T from June 1962 through July 1964. Area II was Grid 2
located in the southwest portion of the present grid. This area received a total accumulative
concentration of 1168 pounds of 2,4-D and 2,4,5-T from May 1964 through September 1966.
Area III was a control area and was located 3 miles northwest of the present grid. (See Figure I-5).
Samples were taken from two levels in the soil. The first level included the surface litter
and the first centimeter of soil. The second level samples included an amalgam of the soil between
one and 15 cm. Two methods of culture were used. In the first, sterile filter paper was placed
in sterile Petri dishes, after which approximately 10 gm of the sample soil were added. The
cultures were moistened with sterile Bristol's solution and placed under fluorescent lights with
an intensity of 300 Ht-candles. The second method of culture preparation was identical to the
first, except an additional piece of sterile filter paper was placed directly on the soil and moistened
with the nutrient solution.
The number of algae was found to be low but no significant differences could be noted
between the sprayed area and plots that had not received herbicides or only minimal amounts due
to drift (Table VI1-1). Only green and bluegreen algae were considered for identification. A
total of 38 organisms were identified (Table VII-2). At least one species of Chlamydomonas.
Chlorococcum. Chlorella. Micrococcus. Nostoc. Oscillatoria and Schizothrix was in every sample.
In the majority of cases, Chlorococcum. Nostoc. and Schizothrix were represented by two or
more species. Most of the other algae were located sporadically through the sampling period, and
few were not universally distributed in all samples. A species of Sponiococcum was the only alga
found repeatedly in a single location. The most frequently located alga was Schizothrix calcicola.
4
Arvik, J. H.: Soil Algae of the Eglin AFB Defoliant Test Range and the Response of Selected
Species to Militacy Herbicides. Air Force Armament Laboratory Unpublished Data. 1969.
Unclassified.
5Arvik, J. H. and J. H. Hunter. Soil Algae of a Herbicide Test Area, Eglin AFB, Florida, and
-the Response of Selected Species to Military Herbicides. Air Force Armament Laboratory
Unpublished data. 1971. Unclassified.
6 Hunter, J. H. Soil Microorganism Study of TA-C52A, Eglin AFB, Florida. Air Force Armament
Laboratory Unpublished Survey. 1970. Unclassified.
128
�TABLE VIM.
NUMBER OF SOIL ALGAE FOR GRAM OF SOIL FROM GRIDS 1 AND
II, TEST AREA C-52A, AND THE CONTROL AREA, 1967 DATA
SAMPLING AREA
SOIL pH
SURFACE ( 0 - 1 cm) CORE (1 - 15 cm)
Grid I (Area I)
2,360a
820a
Grid II (Area II)
5.2
2,243
567
Control
a
5.4
5.3
2,468
570
Data are averages of three samples and three replications taken 30 days apart from
September 1967 through November 1967.
TABLE VII-2. SOIL ALGAE FOUND ON OR NEAR TEST AREA C-52A, EGLIN AFB
RESERVATION
CHLOROPHYTA
Characium ambiguum Herm
Characium sp.
Chlamydomonas pyrenoidosa Deason and Bold
Chlamydomonas typica Deason and Bold
Chlorella vulgaris Beyer
Chlorella sp.
Chlorococcum ellipsoideum Deason and Bold
Chlorococcum Jiplobionticujm Hern
Closteridium sp.
Cylindrocystic brebissonii Meneg.
Euglena sp.
Homidium subtillissimum Mattox and Bold
Hormidium flaccidum Mattox and Bold
Protococcus viridis C. A. Agardh.
Spongiococcus bacillaris Naeg.
Ulothrix tenerrima Kuetz.
Zygogonium ericetorum Kuetz.
CYANOPHYTA
Anacystis marina Drouet and Daily
Arthrospira brevis (Kuetz.) Drouet
Calothrix parictina (Naeg.) Thuret.
Coccochloris aeruginesa Drouet and Daily
Coccochloris peniocystis Drouet and Daily
Fischerella ambigua (Naeg.) Gom.
Microcoleum lyngbyaceus (Kuetz.) Crouan
Microcoleus vaginatus (Vauch.) Gom.
Nodularia sp.
Nostoc commune Vauch
Nostoc ellipsosporum (Desmaz.) Raben.
Nostoc muscorum Ag.
Oscillatoria lutea Ag.
Oscillatoria submembranaceae Ard. and Straff
Porphyrosiphon Natarisii (Menegh.) Gom.
Rivularia sp.
Schizothrix arenaria (Berk.) Gom.
Schizothrix calcicola (Ag.) Gom.
Schizothrix friezii (Ag.) Gom.
T29
�2. CURRENT STUDIES ON MICROFLORA
In the June 1970 study, soil samples were selected for microbial analysis from sites which had
been separated into four general areas on the basis of a prior bioassay experiment to determine
phenoxy herbicide residues. The four areas were as follows: (a) relatively moist soil with high
residue, (b) relatively moist soil with low residue, (d) relatively dry soil with high residue, and
(d) relatively dry soil with low residue. The lowest fungal counts were obtained from Area c:
4 x 103 to 7 x 103 propagules per gram of soil. The highest fungal counts were obtained from
Area b: 4 x KT' to 1 x 1CP propagules per gram of soil. Actinomycetes and bacteria were
considerably higher on wet sites than on dry sites, but the amount of herbicide residue did not
seem to affect the count.
The objective of the present study was to analyze the microflora in the C-52A Test Grid
(population levels of bacteria, fungi, and Actinomycetes, and identification of predominant
genera) and then compare the results with a microfloral analysis of an adjacent non-treated
area (control) and with a similar C-52A Test Grid analysis carried out in the 1970 study.
3. LITERATURE REVIEW
The general role of microorganisms in the biodegradation of herbicides has been thoroughly
investigated and well documented. As part of the study, a literature review was conducted
of the items listed in Table VII-3. Most research has centered around the biodegradation of various
commercial herbicides by fungi and bacteria, both alone and in combination (Table VII-3,
items 2 to 9, 11 to 14, 16, 17, 20, 21, and 27 to 31). In many such efforts, various soils have
been used to effect the breakdown of herbicides with little attention paid to the microbial genera
involved in the process. Total numbers, rather than types of organisms, have been stressed
(Table VII-3, items 12 to 14, 16, 17, 20, 21, 27, and 30 to 32).
Pfister has investigated the role of soil organisms in biodegradation of pesticides, especially
the breakdown of halogenated hydrocarbons (Table VII-3, item 27). In that study, soil fungi,
Actinomycetes, and bacteria are implicated in the breakdown of various pesticide compounds.
Kearney has extensively studied the role of microorganisms in the soil degradation of halogenated
hydrocarbons and has likewise concluded that they do function in the breakdown of these
products. Kaufman, Kearney, Sheets, and Beall have been involved in elucidating the role of
total bacterial count and individual enzymes in the breakdown process (Table VII-3, items
20 to 23).
Bollag has researched the biochemical transformation of pesticides by soil fungi, and considers the fungi to be an important group of organisms in this transformation process (Table
VII-3, item 7). He implicates specific organisms, particularly Geotrichum candidum, in
connection with polymerization of an aniline compound to an azo-derivative.
Tyagny-Ryadno, in determining the effect of heroicides on the microflora and agrochemical
properties of the soil, concludes that some herbicides actually increased bacterial populations
(2,4-D was a notable exception). He states also that some herbicides promote the growth of
fungi, but seem to inhibit Actinomycetes. In his experiments, Simazine caused the greatest
increase in populations of Clostridium pasteurianum (Table VII-3, item 32).
In investigating the action of 2,4-D on Azotobacter spp. in sugarcane soils, Colmer concludes
that the population levels of these organisms are not affected if herbicide application rates are
within those normally recommended for sugarcane (Table VII-3, item 1). Johnson and Colmer
have included in their work the effect of 2,4-Diand 2,4,5-T on metabolic activities of various
.bacteria including specific Azotobacter organisms, Bacillus cereus and Pseudomonas fluorescens
(Table VII-3, items 11, 18, and 19). Johnson and Colmer have determined that concentrations
of 2,4-D less than 5,000 ppm have little effect on Pseudomonas fluorescens.
130
�TABLE VII-3. LITERATURE REVIEWED IN 1973 STUDY
1. Adams, A. P. and A. M. Wachinski. 1973. Microbial Assessment of Soil Samples from Desert
Soil Treated with 2,4-D/2,4,5-T herbicide. Presented to the Ad-hoc subcommittee of the U. S.
Scientific Advisory Board. 22 - 23 February 1973.
2. Alexander, M. and M. I. H. Aleem. 1961. Effect of Chemical Structure of Microbial
Decomposition of Aromatic Herbicies. Ag. and Food Chem. 9:44-47.
3. Audus, L. J. 1950. Biological Detoxification of 2,4-dicblorophenoxyacetic Acid in Soils:
Isolation of an Effective Organism. Nature 166:356.
4. Audus, L. J. and K. V. Symonds. 1955. Further Studies on the Breakdown of 2,4-dichlorophenoxyacetic Acid by a Soil Bacterium. Ann. App. Biol. 42:174.
5. Bell, G. R. 1960. Some Morphological and Biochemical Characteristics of a Soil Bacterium
Which Decomposes 2,4-D. Can. J. of Microbio. 3:821-840.
6. Bell, G. R. 1960. Studies on a Soil Achromobacter which Degrades 2,4-dichlorophenoxyacetic
Acid. Can. J. of Microbiol. 6:325-337.
7. Bollag, J. M. 1972. Biochemical Transformation of Pesticides by Soil Fungi. CRC Critical
Reviews in Microbiology. 2(1):35-37.
8. Bollag, J. M., G. G. Briggs, J. E. Dawson, and M. Alexander. 1968. Enzymatic Degradation
of Chlorocatechols. J. Agr. Food Chem. 16(5):829-833.
9. Bollag, J. M., C. S. Helling, and M. Alexander. 1968. Enzymatic Hydroxylation of
Chlorinated Phenols. J. Agr. Food Chem. 16(5):826-828.
10. Cairney, W. J. 1973. Summary of Results: Populations of Soil Microorganisms from
Desert Soil Treated with 2,4-D/2,4,5-T Herbicide. Presented to Ad-hoc subcommittee of the
U. S. Scientific Advisory Board. 22 - 23 February 1973.
11. Colmer, A. R. 1953. The Action of 2,4-D upon the Azotobacter of Some Sugarcane
Soils. Applied Microbiology 1:184-187.
12. Fletcher, W. W. 1966. Herbicides and the Bio-activity of the Soil. Invitation lecture
given at Wageningen at meeting organized by the Dutch Working Party for Weed Control.
22 March 1966.
13. Fletcher, W. W., and J. E. Smith. Herbicides and Soil Microbes. New Scientist 24:527-528,.
14. Hirsch, P. and M. Alexander. 1960. Microbial Decomposition of Halogenated Propionic
and Acetic Acids. Can. J. of Microbiol. 6:241-249.
15. Hunter, J. H. and A. L. Young. 1972. Vegetative Succession Studies on a DefoliantEquipment Test Area, Eglin AFB Reservation, Florida. AFATL-TR-72-31. Air Force
Armament Laboratory, Eglin Air Force Base, Florida. February 1972. Unclassified.
16. Jensen, H. L. 1957. Decomposition of Chloro-substituted Aliphatic Acids by Soil Bacteria.
Can. J. of Microbiol. 3:151-164.
131
�TABLE VI1-3. Concluded.
17. Jensen, H. L. 1957. Decomposition of Chloro-organic Acids by Fungi. Nature 180:1416.
18. Johnson, E. J. and A. R. Colmer. 1955. I. The Effect of 2,4-dichlorophenoxyacetic Acid
on some Phases of the Nitrogen Metabolism of Bacillus cereus. Applied Microbiology 3:123-126.
19. Johnson, E. J. and A. R. Colmer. 1955. II. The Effect of 2,4-dichlorophenoxyacetic Acid
on some Phases of the Nitrogen Metabolism of Pseudomonas fluorescens and the Microorganisms
of a Soil Suspension. Applied Microbiology 3:126-128.
20. Kaufman, D. D., P. C. Kearney, and T. J. Sheets. 1963. Simazine: Degradation by Soil
Microorganisms. Science 142:405.
21. Kaufman, D. D., P. C. Kearney, and T. J. Sheets. 1965. Microbial Degradation of
Simazine. J. Agr. Food Chem. 13:238.
22. Kearney, P. C. 1965. Purification and Properties of an Enzyme Responsible for Hydrolyzing
Phenylcarbamates. J. Agr. Food Chem. 13:561.
23. Kearney, P. C., D. D. Kaufman, and M. L. Beall. 1964. Enxymatic Dehalogenation of
2,2-dichloroproprionate. Biochem. Piophys. Research Commun. 14:29.
24. Lamartinere, C. A., L. T. Hart, and A. D. Larson. 1969. Delayed Lethal Effect of
2,4-dichlorophenoxyacetic Acid on Bacteria. Bull. Environ. Contam. Toxic. 4(2): 113-119.
25. Magee, L. A. and A. R. Colmer. 1955. III. The Effect of some Herbicides on the
Respiration of Azotobacter. Applied Microbiology 3:288-292.
26. Pate, B. D., R. C. Voigt,. P. J. Lehn, and J. H. Hunter. 1972 Animal Survey Studies of
Test Area C-52A, Eglin AFB Reservation, Florida. AFATL-TR-72-72. Air Force Armament
Laboratory, Eglin Air Force Base, Florida. April 1972. Unclassified.
27. Pfister, R. M. 1972. Interactions of Halogenated Pesticides and Microorganisms: A Review.
CRC Critical Reviews in Microbiology 2(1): 1-34.
28. Rogoff, M. H. and J. J. Reid. 1956. Bacterial Decomposition of 2,4-dichlorophenoxyacetic
Acid. J. Bacteriol. 71:303-307.
29. Smith, N. R., V. T. Dawson, and M. E. Wenzel. 1945. The Effect of Certain Herbicides
on Soil Microorganisms. Soil Sci. Soc. Amer. Proc. 10:197-201.
30. Steenson, T. A. and N. Walker. 1956. Observations on the Decomposition of Chlorophen^
oxyactic Acids by Soil Bacteria. Plant and Soil. 8:17-32.
31. Thiegs, B. J. Fall 1962. Microbial Decomposition of Herbicides. Down to Earth.
18(z):7-10.
32. Tyagny-Ryadno, M. G. 1967. Effect of Herbicides on the Microflora and Agrochemical
Properties of the Soil. Trudy Kamenetzpodolsk. sel',-khoz. Inst. 9:43-48.
132
�Two recent studies, however, have indicated that the 2,4-D/2,4,5-T herbicide combination has
a short term effect on levels of soil microorganisms, especially bacteria (Table VI1-3, items 1 and
10). Analyses of desert soil to which herbicide had been applied three months earlier have
revealed that bacteria levels are still considerably reduced from levels in control soil samples.
Fungal levels were also affected but not to the same degree as the bacteria.
4. MATERIALS AND METHOD
Samples were taken from the C-52A Test Grid on 13 June 1973. Eight sampling sites
were selected to correspond with those sampled in the 1970 study. Three samples were taken
from each of the eight 400 by 400 foot grid areas according to the pattern in Figure VII-1.
Samples were taken from depths of 0 to 6 inches and from 6 to 12 inches at each
site. Four control samples were taken from the same depths in an area 1/4 mile distant from the
C-52A site, but similar to it in soil and vegetative cover. The control area was upwind from
prevailing wind patterns, upstream from natural test grid water drainage, and never subjected
to concentrated herbicide application.
In selecting areas for sampling within the 400 by 400 foot grid squares, an attempt was
made to sample sites with varying vegetative cover. A system was devised to approximate
cover which employed a rank ordering of the sites from 0 to 5; 0 indicated a 0 to 5% vegetative
cover, 1 a vegetative cover of 5 to 20%, 2 a cover of 20 to 40%, 3 a cover of 40 to 60%, 4 a
cover of 60 to 80%, and 5 a cover of 80 - 100%.
In obtaining the samples, a shovel was used to bare a slightly more than one foot deep
vertical cross section of soil. The side of the cross section was marked at the 6 and 12 inch
points. Soil was skimmed from the side of the hole, first from the 0 to 6 inch depth, then from
the 6 to 12 inch depth. Samples were placed in plastic bags and labelled. The soil was kept
at 4°C for no more than 2 days before plating on media for microorganism analysis.
Three media were used to enumerate microorganisms. Potato dextrose agar medium plus
Tergitol NPX (100 ppm) and chlorotetracycline (40 ppm) was used for maximum development of
soil fungi. Nutrient agar plus 150 ppm Actidione was used for development of bacteria. Sodium
caseinate medium (DIFCO Actinomycete Isolation Agar) plus 50 ppm Actidione was used for
determination of Actinomycetes.
Thirty grams of each sample to be analyzed were blended with 300 ml of sterile distilled
water for one minute. Dilution series were made using subsequent sterile distilled water blanks
to achieve dilutions of 10"^, 10 , and 10" . Dilutions were dispensed in three media in sterile
petri plates with three replicates per dilution for each sample. All plated samples were
incubated at 25°C.
Potato dextrose agar plates were examined for fungi after 3 days. Nutrient agar plates were
examined for bacteria after 4 days, and the sodium caseinate agar plates were examined for
Actinomycetes after 6 days. Counts were made from each plate and predominant organisms were
isolated in pure culture for subsequent identification.
In addition to enumeration of microorganisms, 10 samples (0 to 6 inch depth) were
analyzed for water content. Samples were selected on the basis of Hunter's previous estimations
of relatively high or relatively low water content of a given area of the C-52A Grid and on the
basis of relative vegetative cover (0 to 5). Samples tested were as follows: (1) five from
relatively high moisture areas, (2) two from areas with a vegetative cover of 1, (3) one from an
area with a vegetative cover of 3, (4) two from areas with a vegetative cover of 5, (5) five
samples from relatively low moisture areas, (6) three from areas with zero vegetative cover, and
(7) two from areas with a vegetative cover of 1.
133
�A
I
I
B
J
I
C
D
I
I
1
E
123
I
1
i
1
F
3
21
1
G
32,
1
\
I
X
T
H
_ x
2
2
1
l
1
,1
12
|
3
1
K
1
I
1
L 3''
1
1
23
1
IV
1
1
M
12=1
n
1
2
3
A
E>
6
7
1
1
8
g
1C)
11
12
Figure VI1-1. Schematic of the Test Area C-52A Grid Showing Soil
Sampling Pattern (also see Figure I-5)
134
13
14
�5. RESULTS AND DISCUSSION
The average number of organisms per gram of soil are shown in Tables VI1-4 and VI1-5.
Table VI1-4 indicates the average number of bacteria, fungi, and Actinomycetes for each grid
location sampled. Table VII-6 indicates the average number of organisms per gram of soil in terms
of relative vegetative cover. Table VI1-5 is a summary of the data from the 1970 study arranged
for comparison with Table VII-4. Table VII-7 is a summary of the data from the 1970 study
arranged for comparison with Table VII-6. Tables VII-8 and VII-9 show water content and percent organic matter, respectively, for each of the samples analyzed.
There were no large differences in the numbers of Actinomycetes, bacteria, or fungi between
the sampling sites on the grid for the 0 to 6 inch depth. Comparing these data with the 1970
population levels shows an increase in the average number of Actinomycetes in the J-9 and K-2
locations and an overall increase in the number of bacteria in all sampling areas. In the K-2 area,
particularly, the number of bacteria per gram of soil shows an order of magnitude increase over
the 1970 level. This increase might be partially explained by the marked increase in overall
vegetative cover around J-9 and K-2 since 1970.
Differences in microorganism levels in 1970 correlated to an extent with vegetative cover,
the lower populations existing where cover was minimal (see Table VII-7). The 1973 data
(Table VII-6) shows a significant increase in microorganisms in poorly covered areas. The 1973
data indicates no strong correlation between vegetative cover and microorganism populations.
Control areas had population levels similar to those found for the grid.
Predominant bacteria isolated from the test grid were Bacillus sp. and Pseudomonas sp..
Predominant fungi were Penicillium spp., Aspergillus spp., and Fusarium spp.. In addition,
Nigrpspora sp., Helminthosporium sp.f Pullulariasp., and Curvularia sp. were recovered. The
predominant Actinomycetes were Strepjomyces sp. and Nocardia sp.
Although number of organisms from the 6 to 12 inch depth were not tabulated for this report,
the numbers of fungi were approximately 40 to 50% reduced from the corresponding 0 -to 6 inch depth averages. The average numbers of Actinomycetes and bacteria were about the same as those
from the corresponding 0 to 6 inch depth.
Water content varied very little in the 10 samples tested; the range being 0.35% to 1.22%.
The average for all samples was 0.54%. There was no correlation between microorganism population levels and the slight differences in water content.
Organic matter variation was also minimal . Percent organic matter variations did not
correlate with differences in microorganism populations.
6. CURRENT STUDIES ON SURVEY OF AQUATIC ALGAE
The role of phytoplankton in the productivity of both soil and aquatic ecosystems is well
documented. Algae have been identified (Reference VI1-1) as being important in the initial
7
This confirms data from personal communication between A. L. Young with the Department
of Life and Behavioral Sciences, United States Air Force Academy, Colorado, 1973.
Reference:
VII-1. Shields, L. M., and L. W. Burrell, 1964. Algae in Relation to Soil Fertility, Bot. Rev.
30:90-128.
135
�TABLE VII-4. AVERAGE NUMBER OF ORGANISMS PER GRAM OF SOIL
FOR EACH GRID LOCATION SAMPLED (0 - 6 INCHES DEPTH) 1973
GRID LOCATION
ACTINOMYCETES
BACTERIA
FUNGI
C-13
394,000
870,000
58,750
G-13
366,670
722,500
30,000
G-7
255,000
630,000
24,375
H-8
290,000
980,000
60,000
J-9
360,000
575,000
39,909
K-2
285,000
428,000
55,000
L-6
353,330
ND
20,710
0-7
363,000
468,000
32,166
TABLE VII-5. AVERAGE NUMBER OF ORGANISMS PER GRAM OF SOIL
FOR EACH GRID LOCATION SAMPLED (0 - 6 INCHES DEPTH), 1970
GRID LOCATION
ACTINOMYCETES
BACTERIA
FUNGI
C-13
440,000
ND
23,400
G-13
612,000
ND
78,750
G-7
460,000
173,000
74,500
H-8
536,000
224,000
27,500
J-9
21,465
ND
17,968
K-2
54,333
29,000
11,366
L-6
276,000
ND
10,315
0-7
NOT SAMPLED IN 1970
136
�TABLE VII-6. AVERAGE NUMBER OF ORGANISMS PER GRAM OF SOIL (0 - 6
INCH DEPTH), VEGETATIVE COVER, 1973
VEGETATIVE COVER
ACTINOMYCETES
~\
BACTERIA
FUNGI
5
310,000
1,015,000
50,000
4
300,000
1,070,000
110,000
722,500
30,000
3
1,860,000
2
283,330
890,000
32,166
1
357,000
416,000
30,800
0
326,360
529,000
25,800
CONTROL 5
235,000
ND
48,370
CONTROL 4
370,000
810,000
55,000
CONTROL 3
303,000
740,000
51,000
TABLE VII-7. AVERAGE NUMBER OF ORGANISMS PER GRAM OF SOIL (0 - 6
INCH DEPTH), VEGETATIVE COVER, 1973
VEGETATIVE COVER
ACTINOMYCETES
BACTERIA
FUNGI
5
460,000
173,000
74,500
5
612,000
3
536,000
2
1
ND
78,750
440,000
224,000
ND
23,400
54,333
29,000
11,366
0
21,465
ND
17,968
0
276,000
ND
10,315
137
27,500
�TABLE VI 1-8. WATER CONTENT OF TEN C-52A SOIL SAMPLES (0 TO 6 INCH DEPTH)
SAMPLE
VEGETATIVE
COVER
GRID LOCATION
PERCENT WATER
1
5
G-13
1.22
2
1
C-13
0.45
3
5
C-13
0.63
4
3
G-13
0.52
5
1
C-13
0.48
6
0
K-2
0.35
7
0
L-6
0.40
8
1
J-9
0.44
9
0
0-7
0.41
10
1
J-9
0.47
TABLE VII-9. ORGANIC MATTER OF SIX C-52A SOIL SAMPLES (0 TO 6 INCH DEPTH)
SAMPLE
VEGETATIVE
COVER
GRID LOCATION
PERCENT ORGANIC
MATTER
1
0
K-2
0.75
2
0
J-9
0.81
3
1
J-9
4
1.19
G-13
4
a
a
5
5
C-13
6
3
G-13
a
2.58
4.29
1.88
Samples taken from directly beneath a clump of panicum grass and contained root
material.
138
�ecological succession of barren areas. Other investigations (Reference VI1-2) have
indicated the effects pesticides have on algae (Reference VI1-3).
Grab samples were obtained from the pond located near the one square mile grid. Two types
of samples were collected: Sample One was a collection of the suspended and precipitated algal
material in the pond and Sample Two was a collection of the dense algal mat which occurred just
beneath the surface of the water. The one liter samples were returned to the laboratory for algal
genera identification.
Seven genera of algae were identified from the samples collected (Table VI1-9). All genera
were present in both samples: Sample Two being predominantly Zygnema and Sample One
being predominantly Zygnema and Tripjoceras. The seven genera represent two divisions,
Chlorophyta, the green algae, and Chrysophyta, the yellow-green or yellow-brown algae.
Data collected during the course of this study included some physical data. Of interest
specifically with respect to the aquatic algae is the pH which was found to be 5.51, or slightly
acid. Genera represented in the samples collected are those expected to be found under conditions
of this type^.
The previous study, conducted from September to November 1967 was more extensive
than the current study and encompassed the periodicity of algal species with time. In the
previous study, genera representative of two divisions were found. Representative of
Chlorophyta (green algae) and Cyanophyta (blue-green algae) were identified. The present
study, based on a single collection time, would be expected to identify less diversity of orders
and families. No genera were found to be common to the two studies. The previous study,
however, addressed only Chlorophyta (green) and Cyanophyta algae (blue-green). These data
do not however necessarily indicate changes in algal populations as the previous.study dealt
exclusively with soil populations.
7. CONCLUSIONS
In tests performed 3 years after the last application of 2,4-D/2,4,5-T herbicide, the Test
Area C-52A grid, Eglin AFB Reservation, exhibits a population level of soil microorganisms
identical to that in an adjacent control area of similar soil and vegetative characteristics not
exposed to massive quantities of herbicide. There are increases in Actinomycete and bacteria
populations in some test site areas over levels recorded in 1970. This is possibly due to a general
increase in vegetative cover for those sampling sites and for the entire test grid. No significant
permanent effects could be attributed to the presence of herbicides.
Data on aquatic algae populations from ponds previously exposed to repetitive applications of
herbicides indicate that the genera present are those expected in warm, acid (pH 5.5), seepage,
or standing waters.
o
°Personal Communication with R. Lynn, Utah State University, Department of Botany,
Logan, Utah, 1973.
References:
VII-2. Schluter, M. 1966. Investigations of the Algacidal Characteristics of Fungicides and
Herbicides. Int. Rev. Gestamten Hydrobiol. 51:521-541.
VII-3. Wolf, F. T. 1962. Growth Inhibition of Chlorella Induced by 3-amino, 1,2,4, Triazole,
and its Reversal by Purines. Nature, 193:901-902.
139
�TABLE VII-10.
AQUATIC ALGAE* FROM PONDS OF TEST AREA C-52A
DIVISION
CLASS
ORDER
FAMILY
GENERA
Chlorophyta
Chlorophyceae
Zygnematales
Desmidiaceae
Closterium
Cosmarium
Triploceras
Chlorophyta
Chlorophyceae
Zygnematales
Zygnemataceae
Z.ygnema
Chlorophyta
Chlorophyceae
Tetrasporales
Palmellaceae
Asterococcus
Chrysophyta
Bacillariophycaeae
Pennales
Suborder:
Fragilarineae
Fragilariaceae
Asterionella
Chrysophyta
Bacillariophyceae
Navjculaceae
Navicula
Naviculineae
*Smith, G. M. 1950. The Fresh-Water Algae of the United States. McGraw-Hill. 2nd. Ed. 709 pp.
�INITIAL DISTRIBUTION
AFSC (SOW)
AFSC (VN)
AF (RDP)
DDR&E (Env & Life Sciences)
DDR&E (Tech Lib)
USA FA (DFLS)
AF (SAFILE)
AFLC (MMNO)
AFLC (DS)
DDC
Deseret Test Center (Tech Lib)
EA (SAREA-TS-L) (Tech Lib)
EA (SAREA-CL-V)
USAMC (AMCRD-WB/AFSC-SDWC)
OOAMA (MMNO)
SAAMA (SFQT)
USNWC (Tech Lib)
USNWL (Tech Lib)
USDA (Agriculture Resch Serv)
CINCPAC (J3A1)
USAF(Environ Health Lab)
ARL (ARC)
USDA (ARS)
USAF (SAMI)
ASD (ENYS)
AUL (AUL-LSE-70-239)
TRADOC (TAWC-DO)
AFATL (DL)
AFATL (DLOSL)
AFATL (DLIF)
2
2
2
10
5
200
10
2
10
12
5
2
5
10
2
2
2
2
25
5
5
5
5
1
1
1
1
1
2
100
141
(The reverse of this page is blank)
��
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
010
Folder
The folder containing the original item.
0090
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Creator
An entity primarily responsible for making the resource
Young, Alvin L.
Description
An account of the resource
<strong>Corporate Author: </strong>Environics and Flame Munitions Branch, Flame, Incendiary and Explosives Division, Air Force Armament Laboratory, Eglin AFB, Florida
Date
A point or period of time associated with an event in the lifecycle of the resource
1974-01-01
Title
A name given to the resource
Ecological Studies on a Herbicide-Equipment Test Area (TA C-52A) Eglin AFB Reservation, Florida; Final Report: January 1967 to November 1973
Subject
The topic of the resource
ecological impact
herbicide application
dioxin
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/cab342d090450d0c45ccc9a74da3d320.pdf
d02154fbf5254f834959993017be82e1
PDF Text
Text
Item ID Number:
Author
00091
Odum, Howard T.
Corporate Author
Environmental Engineering Sciences, University of
Florida, Gainesville, Florida; and Department of Biology,
Center for Regional Environmental Problems, California
State University, San Diego, California
ROpOrt/ArtlGlO Title
Effects of Herbicides in South Vietnam: Part B, Working Papers, February 1974:
Models of Herbicide, Mangroves, and War in Vietnam
Journal/Book Title
Year
1974
Month/Day
February
Color
Number of Images
305
DeSCriptOU Notes
Subcontract No. BA23-72-28 December, 1973; Subcontract Report #5 Auxiliary Field
Work Supported Under contract AT (04-3) - 807
Friday, December 08, 2000
Page 91 of 106
�.,"3-779 031
THE EFFECTS OF HERBICIDES in SOUTH VIETNAM
PART B, WORKING PAPERS! MODELS OF HER!/'
MANGROVES., AND WAP. IN VKETNAM
NATIONAL ACADEMY OF SCIENCES-NATIONAL RESEARCH COUNCIL
FEBRUARY 1971
»>-.B»CTj^a^^^
'4*
�\
\
THE EFFECTS OF HERBICIDES IN SOOTH VIETNAM
PART B:
WORKING PAPERS
FEEKUASY 1974
MODELS OF HERBICIDE, MANGROVES, AND WAR IK VIETNAM
HGK&SD T. OD0M, MAOR2CS SELL, MARK BROWN, JAMES ZOCCHETTO,
CKAKLKS SMAKLOWS, JOAN BRCKDBR, T. AHLSTRQH, AND L. PETERSON
ACADEMY OF SCIENCES - NATIONAL
WASHINGTON, D.D. 20418
"""NATIONAL TECHNICAL
INFORMATIONof SERVICE
U S D*p<»r*rr«!nt
Corrmnarce
COUNCIL
D DC
VA 22151
MAY 29 1974
Apps'ovod for public release;
Dlaiributian Unlinvitad
EBEinJTS
�MODELS OF HERBICIDE, MANGROVES, AND WAR IN VIETNAM
Final Report to National Research Council
Subcontract No. BA23-72-28
December, 1973
Howard T. Odium, Maurice Sell, Mark Brown, James Zucchetto,
Charles Swallows, Joan Browder, T. Ahlstrom, and L. Peterson
:
Environmental Engineering Sciences
University of Florida
Gainesville 32601
with Subcontract Report (#5) by
Philip C. Miller, James Ehrleringer, Barry Hynum, and Wayne Stoner
Department of Biology, Center for Regional Environmental Problems,
California State Universtly, San Diego, California 92115
with Auxiliary Field Work Supported Under AEC Contract AT (04-3) - 807
Contents
1. Abstract
2. Introduction and Project Narrative
3. Model of Mangrove Productivity, Herbicide Spraying, Wood Cutting and
Seedling Availability in the Rung Sat Zone of South Vietnam - M. Sell
4. Nutrient Models and Perspective on Mangrove Recovery in Rung Sat - J. Browder
T. Ahlstroa, and M. Sell
5. Digital Simulation of Potential Reforestation Problems in the Rung Sat Delta,
Viet Nam - P. Miller, J. R. Ehrleringer, B. Hynura, and W. Stoner
6. Ordering and Disordering in South Vietnam by Energy Calculation - M. Brown
7. Simplified Simulation Model of Vietnam and the Impact of Herbicides J. Zucchetto
8. A Simplified Simulation of the Impact of Herbicide and War on Productivity
in Vietnam - C. Swallows
9. Effect of Aerial Application of Herbicides On a Mangrove Community in
in Southwest Florida - M. Sell
10. Effects of Herbicides on Ecosystems
11. Mangrove System Analysis - Appendix A - A. Lugo, M. Sell, and S. Sncdaker
�. 2
\
/.),
ABSTRACT
:'>K(
i ..
-^
This ,ie a final report of a contract between the Systems Ecology group
of Environmental Engineering Sciences and the National Research Council for
developing data models and simulation of herbicide, mangroves, and the relative
role of these in the overall energy system of Viet Ham at war, Work started
with a special conference on mangroves and models in June, 1972 from which a
work plan evolved for models of recovery of mangroves of the Rung Sat district
and a visit by H. T. Odum to Vung Tau. Simulations of the Rung Sat system
showed serious delays in mangrove reforestation possible from seed shortages
and shortage of seed trees due to high levels of wood cutting and extensive
defoliation. Data on seedlings and other parameters from Viet Nam were
supplemented with data from south Florida, where H. Teas conducted a herbicide
spray test on Marco Island. Mode3a of nutrient balance showed that loss of
wood and leaves due to spraying removes a large fraction of available phosphorus
but not a large fraction of available nitrogen. However, annual river flows in
the Rung Sat situation bring in enough phosphorus for regrowth so that nutrient
limitations do not seam to be limiting reforestation.
Under a subcontract extending thermal studies done in Florida, modelling
initiative of the systems ecology group at San Diego, California showed high
surface mud temperatures and dessicatlon potentially inhibitory in much of the
deforested mangrove area. Poor survival of planted seedlings in unshaded mud in
Viet Nam suggest possible importance of these factors.
•- Simulations of two simplified models of Viet Nam as a whole suggest a pulse
of overall war disruption followed by a t><:imulated recovery, the energy loss
during a 20-year period being about 1%. Perspective from comparing energy flows
ahowed an impact of herbicide as 2% of the energy budget of Viet Nam in years of
iN^
spraying a greater effect than the rest of the war's disruption.rr;
Thus models and measurements were used to estimate relative factor magnitudes
and tines of recovery and to show perspective of the herbicide spray in the
overall pattern of Viet Norn.
�INTRODUCTION AND PROJECT KARATIVE
Systems modelling and energy perspectives evaluations were needed by
the National Research Council Committee for the Evaluation of Herbicide
in Viet Nam for several purposes and a contract was arranged for the work
to be done for these purposes:
1. Since modelling and simulation is regarded also as a research
planning tool, our contract activity was also directed at clarifying
questions, scarmirv, knowledge and concepts among specialists concerned with
mangroves and war nodeIs for the general input to the main committee. Thus,
as contracted, a mangrove modelling conference was held in June, 1972 from
which a number of special questions and needs vere raised concerning planting
of mangrove seedlings further testing of the sensitivity of mangrove communities
and their roles following herbicide action. The results of the conference
discussions, the additional literature search, the field data and the
suggestions derived from planning nodalo were fed back to the various
deliberations of the main cfuaaittee.
In the work with models a language of energy symbols was used. See
Fig. 1„ These are used to express differential equations. See also Odum, 1971.
For example, the qualitative model in Fig. 2 was drawn to summarize committee
discussions of important factors at a Puerto ilico meeting.
2. In the early examination of the questions about herbicide action,
a special problem wae identified in the mangrove districts as represented by
the Rung Slat couth of Saigon(Fig. 3 . Here, the ground was remaining almost bare and
)
vegetation did not &*.em to be coining back very rapidly. The committee arranged
for various measurements to be made to verify the rate of recovery and test
VfiE.ift«S iiXafflfMasa lS£ £h& . 3 8 K XfiMOreXV.. Among the possible limitations to
S,!
�Figure 1
SOME SYMBOLS USED IN ENERGY CIRCUIT DIAGRAMS*
TWO WAY FLOW
ONE WAY FLOW
STORAGE
HEAT SINK
-.
SOURCE
WORK GATE
X
~S^
SELF-MAINTAINING
TRANSACTOR
SWITCHING ACTION
BLACK BOX
More details may b.3 shown within each symbol
�LOSS a
EXPORT
Figure 2
MODEL OF HERBICIDES
IN MANGROVES IN VIETNAM
�peas
0
5
10
kilometers
15
Cutover - Unsproyed
Figure 3
�regrowth were microclimate, adequacy of seed source from remaining trees
In the district, and adequacy of nutrients for plant growth. These are
quantitative questions for which models may show perspective and simulations
of the models show the ultimate consequences for various alternative factors.
In the work of this contract mangrove models were developed and simulated with
special attention to seed source, nutrients, and wood cutting of potential
seed trees. Some field measurements were made in Viet Nam and in Florida to
get data for the model. Sections 3, 4, and 5 concern these objectives.
3. Initial examination of the extent of herbicide action raised the
question of the relative importance pjf country-wide herbicide actions to the
normal processes and economy of the whole country and the relative importance
of herbicide among other disruptive aspects of war such as bombs, military
actions, plowing, guerilla activity, displacement of people, etc. If main
relationships could be shown in a systems model, and if the correct orders of
magnitude of energy flow could be assigned to these pathways, then these numbers
would provide quantitative estimates of the relative role of herbicide action
at the time of action. If approximate computer simulations were also done
showing the time of disruption and recovery, these quantitative estimates
could be extended to show the overall cumulative effects. The cumulative
effect could be considered with and without financial stimulation to the energy
recovery processes. The general effect of herbicide in defoliating upland
vegetation and stimulating various recovery growths was to be considered in this
way. Also a model of the whole country's response to war dioruption was to be
considered with an order»disorder-sln:ulatioa in which the role of herbicide
could be isolated. Sections 6, 7, and 8 concern these objectives.
�*• Measurgmenta were made by project personnel to get some numbers needed
for models, to utilize comparative situations in Florida, and on one trip to
Vung Tau in Viet Nam. Measurements were made of a herbicide treated mangrove
experiment on Marco Island arranged by Howard Teas and these results are given
in Section 3. Other data are included here in Table 1 - 3 on seedlings and
forest flo jf characteristics. Phosphorus data in waters are given in Section 9.
5. A brief summary of the perspectives developed by the models, simulations,
and model-based comparative calculations was prepared and worked over by
subcommittees and then the general coronittee with the result given in Section
10. This was intended for the Part A to go to Coi.gress. Unfortunately this was
deleted by a second review committee who had never seen the fletailed Part B.
�Table 1
New Seedlings at Vung Tau in Cleared Plot; Transect 100m x 2m
W. Drew, 1972
Transect
I
Species
Number
of Seedlligs
Avicennia sp.
C_eriop3 sp.
Phisophpra sp.
Othf.rs
,12
545
23
29
Avicennia sp.
Ceriopa sp.
jfaizophpra sp.
Others
0
408
56
58
Avicennia sp.
Ceriogs sp.
Rhtzophora sp.
Others
6
121
63
1
Avicennia sp.
^eri_ogs_ sp.
Khizophgra sp.
35
77
98
�Table 2
Counts of 0.5 m Quadrats In Vung Tau Spray Sites, March 1972
(H. T. Odum, M. Newton, Nepfcura, Goes, A. Lang, & others'!
10
2
Raw Data
Quadrat
1
2
3
4
5
6
7
8
9
10
11^
12/
13|
14j
Ify
17\
• «/
i9\
20]
21 /
22J
23
24
25
26
27
28
29
30
31
32.
34
35
36
37
38
39
40
41
42
43
44
No. of Yellow & No. of Black
Green newly
(ind Brown
Leaves
Fallen Leaves
(Older)
6
7
G
3
5
11
2
0
4
2
7
6
3
8
7
2
7
9
4
7
G
3
3
2
2
3
4
4
2
3
2
1
4
2
3
4
4
5
4
5
2
5
0
6
11
5
5
16
48
3
31
31
17
.1.4
24
27
14
17
12
27
9
13
30
28
11
18
11
13
28
20
16
11
32
27
22
22
27
8
11
14
33
15
21
32
11
1
1
Livft
Seedlings
(In last
Yeari
0
0
0
0
0
0
1
3
4
2
4
0
0
11
1
6
1
0
0
7
0
0
0
0
0
1
0
0
0
2
1
0
2
1
2
0
0
10
1
5
3
2
5
Crabs Snails 3e<_a
Seen on Grnd. or
Upper 6" of
Stems
2
0
1
1
2
2
0
1
4
0
0
0
1
1
3
0
0
0
3
1
0
0
0
1
0
0
0
0
4
2
0
0
1
0
1
0
1
0
0
0
0
0
(;
C
1
5
A
1
1
4
5
1
10
5
0
3
1
0
2
j
2
6
1
4
0
0
1
0
0
1
1
1
4
2
3
0
.0
0
4
>
4
2
1
0
No. of
Crab
Holes
Est.
7
-1
1.1
Hi
1"
29
12
22
14
23
2.1
?0
21
23
17
25
10
21
28
18
32
19
33
23
27
36
.-9
30
33
19
17
26
37
34
24
24
35
25
2C
9
25
34
Black
Mangroves
Pneuraar.ophores.
i:-
i!';''.
o
2
r ••
0
0
0
,'.'
0
1
0
22
31
16
16
13
-;
13
27
<?
0
0
4
.:0
33
0
0
0
0
39
0
0
0
0
0
0
0
0
c
0
0
�1.1
TABLE 3
Data on Seedlings Sampled from Rookery Bay on July 13, 1972
Seedling Lengths, centimeters
27.6
31.7
24.4
21.3
25.6
26.1
#2
*3
#4
#5
#6
Dry weight of Seedlings, grams
9.1
12.6
7.0
4.8
7.7
11.6
Seedling Counts of _ M £ ? 2 £ HaasJSjl Along the Perimeter of Rooktry Bay
B2£!!.
Number c seedlings tn
102
74
90
98
80
50
6
3
52
4
0
0
32
14
38
12
4
4
8
0
0
0
22
18
14
0
12
0
12
34
y - 783
y - 26.1 "T2
STD DEV • • 32.25 m-2
Overhang, feet
10,404
5,476
8,100
9,604
6,400
2,500
36
9
2,704
16
0
0
i,024
196
1,444
144
16
16
64
0
0
0
484
324
196
0
144
0
144
1,156
6
36
49
7
8
64
64
8
49
7
100
10
100
10
25
5
6.25
2.5
64
8
100
10
49
7
49
7
12
144
15
225
64
8
9
81
64
8
20
400
400
20
15
225
20
400
12
14420
400
y£' 3,302
yi-252.5
y " 10.52 feet - 3.2 meters
( y,)2 " 63,756
STD DEV - 6.4
�12
Mangrove-Modelling Conference in Gainesville, June 1972
and Acknowledgements of Collaboration
The mangrove modelling workshop conference was held June 19-21
in Gainesville with travel funds (no honoraria) from the contract.
Several of th« participants were paid by their home organizations.
Invitations went to those who were doing mangrove ..Celling or who were
doing experiments or making measurements of key parameters needed in
modelling such as reproduction, seedling germination, herbicide action,
etc. We tried to draw representatives from each on-going mangrove research
activity we knew about.
Each person attending took a half hour to input various data, results,
Ideas, questions bearing on the problems of herbicide and mangrove with
the others participating in vigorous, prc.bing discussion. In some ways
this was like the main committee discussions except that in this group
focus was on mangroves by people who were mangrove specialists.
Unfortunately, the marvelous reworking of ideas and concepts did not
adequately feed back into the main committee as well as hoped because at
the last moment Drs. Lang and Ross had to cancel. However, Teas and
associates were there and Golley sent a representative. William Odum
had been in on the original Masalaon MAS deliberations and vas most
helpful in integrating the mangrove-nutritions concepts. Gerald Walsh
had potted mangroves under herbicide treatment in Pensacola (Gulf Breeze)
and had special knowledge of mangrove plant physiology to draw from. Later
he sent an extensive mangrove bibliography, which he forwarded to the
committee office. Gilberto Cintron of the Puerto Rico state conservation
organization brought much knowledge of mangrove responses to disturbance
and report of some spraying in Puerto Rico, One of the most active mangrove research projects is that of the Puerto Rico Nuclear Center in
�13
relation to proposed nuclear plants and this work waa discussed by
Seppo Kolehminen (see below).
Howard Teas and Joan Browder (later
joining our contract work) from tb«: Miami group discussed their seedling
work and took the lead among the conference group in organizing a proposal
to the main committee for a Florida test experiment to verify sensitivities
and generate & focus for this group to augment the work of the main
committee.
The conference in effect organized itself into a branch activity with
a plan to the committee that would allow them to enlist some of their own
organization's support in a common interest activity. Unfortunately,
we failed to get enough enthusiasm frost the main committee to do this as
planned although after some delay in initial spraying was authorized,
with Dr. Teas (rather than the conference group) providing most of the
cost. In Section 9
are results of our measurements on the Marco Island
plot which along with the main effort of Teas help established the
sensitivity of American mangroves to "Agent Orange".
Linda Lefler contributed a review of mangrove, physiology which
•he had done for Dr. Galley. Phil Miller flew in from Alaska and the
discussions oriented him to the needs so that he could organize his work
as our subcontractor for simulation work in San Diego done by James
Ehrlerlnger.
In this work Miller's work in simulating Florida mangroves
on a Power Corporation project made his team ready to consider the
microclimate limitations in sophistication on relatively small funds.
W. Xieman attended with W. Cdum and has since on his own done mangrove
modelling receiving intellectual stimulus from the conference.
It may be
desirable for the cora&itcee to invite him to contribute whatever results
and insights may have come from this. E. Kuenzler of NSF and E. Heald
�could not come and several others of Miami Marine laboratory were not
invited because we did not know they were involved. Armando de la Cruz
at Mississippi State had worked in Philippines and gave us input later.
J. Lincer was in Florida (Cape Haze) but we didn't know it then.
One of the most pertinent projects was the Fakahatehee slough
project of S. Snedeker and A. Lugo of Univerdity of Florida on structure
and function of mangroves in South Florida under support of Dept. of
Interior. Progress report on this (written and oral) was made available
giving critical numbers on bioaass and seedlings. Later M. Sell did a
special simulation on hurricane effects on mangroves with Lugo and Snedeker
and this is appended as an appendix since it was partly an outcome of the
conference communication. The surge of destruction by hurricanes is
somewhat like that of herbicide, with great thickets of dead vood remaining
and much kill that la not yet explained (broken stems? sedlraented
pheumatophorea? stripped leaves?). The difference is that there was a
scattering of Seed trees end there were no peasant wood cutters in south
Florida and the wood lias been standing for 10 years gradually decomposing
as new growth comes froia surviving trees. Dr. R, Goodrich of the Centr-L
and South Florida Flood Control District, West Palm Beach reported on his
seedling restoration experiments on spoil islands in south Florida. One
of his main points was that seedlings need to be planted in water depths
and wave energy situations that are the normally suitable ones rather
than general broadcasting of seedlings. Both Teas and Goodrich found low
mortality rates with aerial broadcasting of seedlings. Seedlings need not
be weighted, for they will turn their new roots earthward in growth and do
not have to be stuck into the mud. Tha consumption of roots of red mangroves In South Florida was described. Some regard It as possibly an
adaptive regulator of horizontal extent of mangroves. Questions were
�is
raised about nitrogen fixation in mangrove muds and Teas proposed work
by them on this. Both Teas and Goodrich felt that the topography (or
immediate environment) of the place the seedlings landed was the most
important factor in seedling survival. Mangrove could grow where there
was fin accrueing shore line (low energy), and available moisture (elevation).
Contributing to the discussions and plans were many staff and students
of the Environmental Engineering at the University of Florida.
J. Ewel aided the work in many ways especially in his plans and discussions
at the first meetly of the herbicide committee in Washington. He proposed the use of the Holderidge approach to the uplands—later the subject
of Bethel's proposal. Frank Nordlie participated from Zoology. Joan Browder
supplied an 8-page review:
"The Role of Birds in Mangroves" with 10
references and special, reference to Cattle Egrets and this was forwarded
to F. Golley for the animal write-up. Knipling attended from the Department
of Agriculture providing maps and liaison with the work by Wcatherspoon.
In the year that followed the conference, varied mangrove studies continued
among those who attended the conference. Gerald Walsh published a note on
herbicide studies on seedlings. Stimulated by the conference, J. Zicaian and
W. E. Odum (University of Virginia) have separately and on other funds developed
some mangrove models to be reported at forthcoming scientific meetings. In the
year that followed the conference, under Department of Interior funds related
to the Fakahatchee strand in south Florida, S. Snedaker, A. Lugo, L. Burns and
others made extensive measurements and some further modelling of the Florida
mangrove swamps.
Following one of the herbicide conference meetings, H. T. Odum and P.
Zlnko of University of California visited the Marco Island herbicide site,
collecting samples that were analysed along with Viet Nam samples by Zinke.
�16
Included were some samples from the Snedaker-Lugo project sent to him at that
time. In July of 1973 another Mangrove conference was 'held under auspices of
the Conservation Foundation with Department of Interiov funds at St. Petersburg
coordinated by S. Snedcker. This conference was not definately related to the
herbicide work but parts of those at the other conference continued
their
research communication concerned with mangrove health and reforestation.
The following not« was received from Puerto Rico participants:
ENVIRONMENTAL CHANGES AND RESEED1NG OF A
KILLED MANGROVE AREA IH PUERTO RICO*
by G. Cintron** and S. Kolehmalnen
In Puerto Rico there is a mangrove area, a few acres in size, that
was killed by human activities, probably with a herbicide. This area
is on the north coast of the island in the estuary of Rio Grande River.
The mangroves have been dead over a year, and consequently, similar
factors as in the Rung Sat area in Viet Nam have been affecting the
sediments for an extended period. Therefore, it is felt that this area
in Puerto Rico can be used to study the possible changes in the environmental conditions of water and sediments that could have happened in
Rung Sat. A healthy mangrove area may be used as a control area.
The herbicide sprayed areas of mangrc"ea have been barren for two
to seven years. During this tirae the soil and the sediments have been
exposed to sunlight, tides and rainfall. This means that the oxidation
rate of organic matter must have increased due to the higher temperature,
lessened input of organic matter and increased flushing rates of tidal
and runoff water. When the foliage of mangroves were destroyed, the
increase in the light intensity increased greatly. This, in turn,
probably increased the production of benthic algae.
�17
ORDER-DISORDER, MANGROVES, HERBICIDE, AND WAR
Ecological Modelling for Evaluating Disruption and Recovery
Large scale systems of man and nature such as forests, mangrove districts,
agricultural country sides and urban areas have regular and normal process of
construction, replacement, and reconstruction that tend to maintain ecosystems,
human settlements, trees, soils, leafy matter, houses, streets, riverbeds,
wildlife, social organization, etc. Working against these constructive processes
are the natural tendencies for all structures and information to deteriorate
with time as required by the second law of thermodynamics. In addition there are
frictional and accidental losses that occur as part of constructive efforts and
that form special disruptive processes such as earthquakes, hurricane, and war.
The action of herbicide is a special disordering action.
To gain perspective on the Importance of a disruptive process, one may
estimate the magnitudes of direct and indirect energy involved to find what
percentage its effects have been of the total energy budget of the whole system.
One may compare herbicide action in energy measures with that of the whole
system but with the aid of a model to consider main actions, interdependcncies,
feedbacks, self regulatory actions, times of action, and time of recovery of
the system to former state. Systems methods relate parts to wholes and thus are
helpful for impact studies. Here, we use four systems methods to ^ain perspective
on the relative action of herbicide in relation to the war disruption as a whole
and the role herbicide played in the general process of South Viet Nam as a whole,
1965 and after.
Tha four methods used were the following:
1. Systems were diagramed to show interactions believed important.
2. Energy flows were estimated for comparison in diagrams and tables to
evaluate importance of the pathways.
�18
3. Computer models were simulated to show consequences in time that
disruptions produced in models. The simulations were used to test
whether concepts for the manner of action of disruptions svch as
herbicide produce the patterns observed in the real situation.
4. Models were tested to generate forecasts, determine what future actions
might be considered, and test the consequences of proposed measures.
Models and simulations were wade on two scales of size as follows:
1. The Rung Sat mangrove district, the largest mangrove area defoliated,
was studied with emphasis on biomass, productivity, land coverage, and
reproduction of the mangroves. The models included disruption and
recovery, factors of herbicide, seeding, cutting, nutrient, and mud
temperature.
2. An overall view of Viet Nam was modelled to determine the effect of
herbicide on the maintenance of organized structure. Evaluations and
simulations included disruption by war and herbicide, the recovery
feedback stimulation from the disruption, the energies and monies of
order and disorder from nature, from communist source?, and from the
U.S.
Steady States and the Balance of Ordering and Disordering
Any system that sustains continuous life in the long run r.ust develop a
balance of its ordering and djj.Borderjj.ng processes. We visualize these as
circular relationships as in Fig. 4
a balance after disruption.
Such circular systems tend to return to
A system in such a balanced state is said to be
*n steady state. Surviving systems devalop an ability to repair and accelerate
restoration and recovery when disrupted by recycling materials and energy from
its storages combining these with new potential energies to stimulate reconstruction
of the disrupted zone. We are all familiar with these processes in a forest
where new trees accelerate growth to fill a spot where a tree fell.
Fertilizer
nutrients from fallen and disrupted trees are released and recycled by the animals,
micro-organisms, and root: actions, stimulating regrowth.
Pathways of supply of
energy resource of sun, rain, and geological substrate are free to be harnessed
•again.
:
• •'
' - • • • ••••••'•
••: • • • : ; : ; . .
-...,-
• . - • ' , \;;:':'::
•'.'
�19
Similar processes stimulate recovery on the larger scale of whole countries.
Parts and fragments of the disordered state stimulate regrowth provided there is
available abundant energy sources or sources of money to purchase the energy resources.
For example, disrupted land, displaced people, disordered materials and released
nutrients tend to stimulate reconstruction activity.
Summarizing the concept of self-nsalntaini-ig systems we find there is a
symbiotic balance be_«een ordering and disordering process in the normal system
with cycles of disordered materials back to reuse in new construction. When
there is a surge of disruption, there is a surge of stimulation by land, people,
and materials in symbiotic action that accelerates the reconstruction somewhat
later (if there is an energy source). Any ultimate judgment of the effect of a
process umst consider the short term, and long tern effects.
Some actions of war are short pulses that have Immediate surges to
disorder followed by resurgeo to the reordering process. Where actions of war
or other disturbances ar& chronic and continuous, the effect of the disruption
being more continuous causes a more continuous drain from the resources so
that a new steady state balance is achieved, one with more disorder on the
average. We can call this a stressed steady state. In some ways the portracted
period of wars In Viet Nam has been a stressed steady state, although l.iere have
been surges uithin it with intensive periods of herbicide actions, bombs,
military actions, etc.
Given in the systems diagram in Fig. 4a Is the simple idea of the
constructive actions cantributing to structure of man and nature over the
countryside, balancing the destructive actions of nature and man. Notice the
pathway by which increases in disordered areas and components stimulate the
regrowth. Herbicide is one of the special disruptive stresses (Fig. 4b).
The systems diagrams of pathways of action and storage are also pictorial
�Pig. 1. Cycle of
Order and Disorder
20
�21.
ways of representing mathematical equations that are another way of indicating
an ecological model. For example, the equations that go with Fig. Vb are
shown in Fig. fo to help the readers understand the connection between the
diagrams and mathematical statements. Each mathematical term refers to one
pathway and the several equations together summarize the systems diagram. For
each pathway, the**: is cocffient (k) which indicates how much flow there is
in that pathway per unit: of driving action coming from upstream storage unit or
units.
In computer simulation, the mathematical equations are allowed to interact
together and continuously so that the various inflows, interactions, stresses,
etc. take place with the complexity shown in the diagrams and as a result,
graphs arc plotted that show the rise and fall of various properties of
the system with time for comparison with those observed in the real world
or as a prediction of possible future action.
The systems diagrams show the various kinds of important storages (tank
symbol, Fig. 1) of a system (such as structure, disordered parts) and the
pathway lines show where one flows into another or where one interaction acts
on another In a otlmulatory control action (workgate, Fig. Id').
Many control
actions at workgates are amplifying, multiplicative (indicated by pointed
block with multiplier sign X, example, Fig. 1). The ultimate sources of
actions in the system are the energy sources outside such as the sun's
energy or the source of support to armies or the fuel energies brought
In by tanker (Circles, Fig. lc).
The diagrams may also be used to show relative magnitudes of actions and
storages by writing in the numbers for storage in the tanks or numbers for
flows on the pathways. (See, for example, Section 3, Fig. 3. In that model
data are used to evaluate coefficients of the mathematical equations and
analog and digital computer simulations are given. For others, we use
�22
descriptive energy diagrams to show perspectives on the role of herbicide
In mangroves and In the war and Vietnam as a whole. More details on
symbols and procedures are given in a recent book (Odutn, 1971, Environment,
Power,_._and_Soclety_. John Wiley).
Analog Simulation of Order-Disorder Model
Given in Fig. 4^ is the result of a simulation of the order-disorder model
which verifies the general stability of the provision for the symbiotic balance
and recycle between order and disordering tendencies.
In the first graph the
levels of order and disorder are immediately established, these being somewhat
different from the initial conditions first established. Thus Q, rises to a
level as Qt disorder falls to a lower level.
•
In the second simulation a disordering stress is applied that pumps order
into disorder, a relatively easy process since it goes in the direction of the
normal degradation that ultimately accompanies any storage of order. While this
disordering stress is operating, the levels of order and disorder shift to a new
leveling that is equally stable. Turning up the disordering action pulls order
down so that it is in short supply and the rate of disordering is diminished for
lack of further structure to disorder.
Disorder becomes so abundant that it
stimulates rapid recycling recovery as long as there is a regular unlimited
energy source to be tapped. Diminishing order beyond its point of scarcity
becomes difficult. With removal of the special stress, the system returns to its
original levels of order and disorder.
.: ,
�23
Without
With
Stress
Stress
Q
Figure 4d
�Models of War and Stress
Because we use simplified war models in relating herbicide to overall
energy budget, we give here some background on var models.
We have not made an exhaustive review of political modeling or those
with war, but those earlier efforts many help set our Viet Nam simulations
in perspective.
Through the aid of Gary Murfin we located a simulation of the Viet Nam
conflict by J. S. Mllstein and W. C. Mitchell ( 196$ and on' by John
Voevodsky 0 9 8 .
.6)
Milsum (1968) building on Richardson's armament model (I960) has the
competition between nations as summarized in our diagramming of their
equations . Since these models fail to put In an enerev
constraint and do not have the environmental interaction, they may not be
very real or pertinent.
Odum ( 9 1 has two models of war interaction that include energies
17)
and losses with distance with both offensive and defensive war (Figures 5 and 6).
Saaty (1972) proposed a model which M. Sell diagrammed and put on
analog simulation as given in Figures
7 an(j g
. It has the feature
of each controlling the other's energy input and one pathway of inhibition.
None of these have the environmental Impact.
t
.'r
�\
I
&
M
O
Regulatory organization systems whici prcvide ooexiitenoe. (a) Smnnurizing diagram fur war el
> coasumci drawing more power from die larger QmS. (&) DeUib o{ war system of power rrguUtion with conflict zone clc-"- to smaHar unit, (e) A governmental organizational sytterr vlth vntes proportional to power but
power Bow* regulated to equalize ttandards of livtag and limit povtti. *r><e prevmting competition.
�26
Eiwrgy diagram] reptenndng three stagn of history suggested by
theory of Toynbee: (fl) period of ex«u power; (fc) (Miioi of constant power; (c)
period of eroded power. Dashed lints indicate p*tiiw»y» which are lost
Figure 6
War Models (Oduis 1971)
�Weapons
to
Viet.
to
r
:: U.S. Troops
Marginal Superiority
�28
A
10% Effective
B
C
20%
30%
10
YEARS
15
Figure 8.
�29
Milstein and Mitchell tested the models for the stimulation of one
sides warring activity by the other with such parametets as troops killed,
indices of negotiation initiatives, indices of confidence, etc. and
economic support. Good fit was obtained to the intensity of war as it
varied month to month in terms of the interplay of military decisions.
The model did not have an energy constraint and may have succeeded at its
predictions because neither fide was really energy limited except through
its own decisions as to what resources to commit, based on decisions of
the other environmental impact was not involved.
Christine Paddock working in our group last year (unpublished
manuscript) simulated the course cf oscillating war and peace in the
primitive tribe based on 4 criteria of decision related to resources,
especially pig crop. The simulation was quite like that qualitatively
documented by Rappaport(1971).
Voevodsky (1968) has a model for war as dependent on some exponential
declining storage whose time constant and initial conditions of resource
ultimately determine the end of the war. This single decay tank is a
little like the pigs for the ancestors pig accumulation theory.
�30
Stress Amplifier War Interaction
Maurice Sell
• ' . . . , .
In addition to the models of war and stress developed by Zuccher.to and
Swallows and Brown for this report to the committee studying the effects of herbicide on South Vietnam, other models have also appeared in the literature. One
such model was discussed briefly by Saaty(1972) as an example of game theory.
Saaty considers three variables in his discussion: the United States
supply of vital weapons, Q. , the supply of weapons for North Vietnam, Q_ , and
the accumulated marginal superiority of either of the two warring nations; v.
Each nation according to Saaty has a choice as to the fraction devoted to
depleting the reserves of the enemy. That nation able to accumulate resources
would be the victor.
In Saaty's model, the accumulation or loss of U.S. weapons with time depends
on the rate at which weapons are obtained from outside sources, N.
and the rate
of depletion by Notch Vietnamese forces, k,k_Q9. In equation form this becomes
*
*•
.
<*
'
Q - NL - k Q ,
^.
.
(1)
0<k 2 il
where k.. is a measure of North Vietnam's effectiveness against the United States
and k Q represents the weapons used by North Vietnam for the purpose of attrition.
..
A similar equation for the accumulation or loss of weapons by North Vietnam is
Q2 •"
N2
• - . .-,0*k4*1
- k3k4Qt
•
-
(2)
.. .
-
•-,'-. .. -
.-
•; , : , . • : ...
,
One of the two nations in conflict may ultimately be more successful than
the other and will accumulate marginal superiority according to the equation
V
where
1 - k.
and
-
(1 - k2)Q2
1 - k,
-
(1 - k4)Q1
(3)
are the fractions of North Vietnamese and U.S. forces,
attacking each other.
Saaty then proceeds to determine optimal strategies for each side and
concludes that as the war ends both sides are spending all their resources attacking
each other rather than trying to deplete the reserves of the other nation. If it
is assumed that the North Vietnamese are less effective than the U.S. in depleting reserves, then Saaty concludes that North Vietnam switches to full attack
some time before the end of the war and this equals the reciprocal of the
effectiveness of North Vietnam. In other words the less effective North Vietnam
is with attrition, the faster they switch to full attack.
�31
Since Saaty presented no data or curves to support this model, a
simplified model was drawn using the equations developed by Saaty. This model
is shown as Figure 7. In this simulation that follows no data were used so that
the results are entirely qualitative. Also, the model does not include conditions
for switching more reserves to attack or attrition, whichever is needed. Intelligence reports would also have an effect on the fraction used for attack and
attrition of the enemy.
Figure 8 shows the accumulation of marginal superiority as it varies with
time for the following conditions:
1. North Vietnam is at 807. full strengt.i and 50% of this goes to
attrition of U.S. resources with 50% effectiveness.
2. The United States is at 50% full strength and 50% of this goes
to attrition of North Vietnam's resources with varying rates of
effectiveness. Supply rates are the sfme for each nation.
In Curve A the North Vietnamese are only 10% effective In depleting U.S. resources
and develop very little superiority. Within 5 years the U.S. begins to develop
superiority and continues to increase its superiority. At 25% effectiveness the
U.S. begins to become superior after about 9 years and at 30% effectiveness it
takes about 16 years. A curve not shown Indicates that if the North Vietnamese
are 50% effective, they maintain superiority. As one side begins to lose the war,
it seems that the rate of supply of resources would be increased. This was not
considered here and is indeed a shortcoming of the model. However, this paper was
not intended to fully detail the Vietnam war but only to indicate trends. As
mentioned previously, a vital clement missing is the adjustment one or both
conflicting nations would make to keep the other from becoming superior
militarily.
�32
References
1. Mllsteln, J.S. and W.C. Mitchell, "Dynamics of the Vietnam Conflict: A
Quantitative Analysis and Predictive Computer Simulation," Papers, Peace
Research Society(International), 10 pp. 163-213 (1968)
2. Mi 1 surn,J.H., Positive Ij^edbajek; A ^eney^l^^
Negative Feedback and Mutual Causality, Pergamon Press 1968
3. Rappaport, R.A., "The Flow of Energy in an Agricultural Society," Scientific
American, 224. No. 3, 116-133 (1971)
4. Richardson, L.F., Arms and[ Insecurity Stevens and Sons, London 1960
5 Saaty, T.L.,"Operations Research: Some Contributions to Mathematics,"
Science r/8, 1061-1070 (1972)
6. Voevodsky,J,, "Quantitative Behavior of Warring Nations"(Source unknown) 1968
�3.
Model of Mangrove Productivity, Herbicide Spiaying,
Wood Cutting and Seedling Availability in the Rung
Sat Zone of South Vietnam
Maurice G. Sell, Jr.
Probably the most important, economically, of all the mangrove species
found in the Rung Sat are those belonging to the genus Rhizophora. The species,
Rhlzpphora mucrqnata, is very prevalent in the Rung Sat and has economic value
as charcoal (Van Cuong, 1964). Since this species comprises about 75% of the
mangroves, the data compiled for the simulations relate exclusively to Rhizophora
spp. For the purpose of orientation a map of the Rung Sat is shown in
Figure 1.
An Important concept used in simulating the mangrove community of the Rung
Sat was that of being able to omit raany of the detailed occurrences in the
mangroves. For example, the process of photosynthesis produces organic matter
used by the mangroves for growth and metabolic processes.
The actual process of
photosynthesis includes many steps or chemical reactions that eventually result
in the production of organic matter. This detail was not needed in this model
since the primary concern of this study involved events on a larger scale.
This technique of lumping is probably valid whenever the overall result of some
process is desired rather than the Intricate details.
A simplified model of the mangrove forest in the Rung Sat is shown in Figure
2 using the symbols previously described in Fig. 2, Section 1. This model has
several parameters operating on the mangrove forest as outside forcing functions
(circular symbols). The state variables (tank-shaped symbols) are those variables
whose levels were thought to be important in this model. Each line represents
a pathway that connects state variables with each other or with one or more of
the outside forcing functions.
�eedhngs
From Other
Areas
Seasonal Stimulus to Seedlings
Seedlings
on Trees
Area of
Seeded
Land
Seedlings
in Water
Photosynthesis
Herbicide
Action
Mortality
Area of
are Land
ft
<D
Metabolic Costs
Seedlings
Lost to
Sea
�Rice
_
...
Paddies
Cutover - Unsprayed
South
China
Sea
�36
The sun is shown as a forcing function that interacts with the amount of
land covered by the mangrove trees. In this model the amount of solar energy
available to the mangroves is taken as 50% of the incoming solar energy. The
flow from the sun-land interaction is going to be called gross photosynthesis.
In reality the value of this pathway probably lies somewhere between the upper
value of gross photosynthesis and the lower value of net photosynthesis. Sine?
net photosynthesis carries K different meaning for each individual, let it
suffice to say that the pathway ia slightly less than gross photos-mthesis.
This pathway of organic matter flowo into mangrove biomass and increases as
more land is covered by mangroves. The organic matter produced through the
sun-land interaction is used by the Mangroves for growth and metabolic activities.
Woodcutters are very important in their influence on the mangrove forest. They
are shown cutting wood at a rate proportional to the level of mangrove biomass.
The production of seedlings is shown as a seasonal occurrence. In May of each
year the mature mangrove trees begin to use some of the organic matter to grow
seedlings which continue to growuntil about October when seedlings begin to
fall from the trees. The fall of seedlings was assumed to occur during a period
of sixty days (Gill and Tomlinscm, 1971). Tha number of seedlings hanging from
mangrove treea was included an & state variable. When these seedlings drop from
the trees„ many of them remain beneath the parent tree, but actual numbers were
not available. This should depend on the effectiveness of tidal flushing. Some
of the seedlings are carried by tidal or river currents to other area. These
seedlings ara shown as a state variable labelled seedlings in the water.
Some
of these seedlings may eventually colonize an area devoid of mangroves. This
colonization is shows as an interaction between seedlings in the water and bare
land to give land that Is covered by mangroves. In the Republic of Vietnam
extensive spraying with herbicide has brought about vast acreages of bare land.
Spraying with herbicide is shown as an outside stress draining land covered by
mangroves to eventually cause bare land resulting from death of the mangroves
�37
through spraying and removal of the trees by the woodcutters. A pathway has
also been included that represents the planting of mangroves by man if thin
is a desired course for Vietnam to follow.
Figure
3 shows the values used for the state variables and pathways
in the model. These numbers represent the total size of the variables or flows
in the Rung Sat. The numbers for the simulations were obtained primarily from
mangrove research studies in Puerto Rico or Florida.
Solar radiation data and
land and water areas were obtained for the Rung Sat.
Data Used in Model Calibration
Solar Radiation
Data for solar radiation at Saigon for the period January 1964 through
October 1967 were used to derive a curve that approximates the data. The data
were supplied by the United States Department of Commerce, Weather Bureau.
Values are given in Table
1 in units of kcal m~* day"-'- on a monthly averaged
basis. These values are also plotted in Figure
the curve is approximately sinusoidal.
4 where it can be seen that
For the simulation a sine wave was used.
Leva1 of Mangrove, Biomaas
Biomass values were unavailable for the mangrove forests in South Vietnam
so a value was chosen from the literature for mangrove forests of similar stature
The biomass of mangroves in Puerto Rico was measured by Golley et .al (1962) as
5000 grams per square meter ( 0 0 grams per square meter is equivalent to 4.5
10
tons per acre) in leaves and wood. This was used as the initial condition valie
for mangrove biomass In the Rung Sat model. Rates of gross photosynthesis and
respiration were also from the Puerto Rico study. Cutting rate was estimated
as 3% of the mangrove trees per year.
.
�G
s
u>
Mangrove
Biomoss
3.75 x 109
fens
kgs yH
�39
TABLE
Monthly Solar Radiation Data for Saigon From January 1964 to October
1967 (Units of kcal W 2 day-1)
Month
Solar^Radiation (kcal m~2 day"1)
January
3500
February
4220
March
4560
April
4380
Muy
3680
June
3910
July
3860
August
36%
September
3560
October
3350
November
3160
December
3160
�4500
Actual Values
——-• Function Used on
Analog Simulation
2
O
H7
1 t 400°
31 35OOH
O
CO
3000
JAN
(B
*-
FEB MAR
APR MAY
JUL
AUG
SEP
OCT
MOV DEC JAN
�In an experiment in Florida Rhizophora mangle seedlings were found to weifih
12.6 grams (dry weight) for a seedling of length 31.7 centimeters. If the
assumption is made that this seedling is six months old, then the yearly growth
rate is 12.6 grams per seedling. A density of about 26 seedlings per square
meter was counted in the trees in July 1972.
Therefore, growth of seedlings
is at least 327 grants per square meter per year. For this simulation a value
of 660 grams per square meter per year was chosen,
Seed! ings in the wat er
The number of seedlings falling from the trees into the water to be carried
away by the tidal currents was calculated by estimating the amount of tree overhang above the water and determining the total length of waterways in Vietnam.
The overhang was about three meters in Florida and the Rung Sat has about 500
km of waterways in the unsprayed area. The sprayed area also has another 500
taa of waterways. Before spraying the number of seedlings that could be in
water would therefore be about 1 X 10$ seedlings. Seedling movement was calculated on the basis of a period of sixty days during which the seedlings fall
frost the trees into the water.
The total area of the Rung Sat was already given previously as 750 km2.
If the woodcutters are assumed to have some influence on the amount of bare
land, then the initial conditions should consider this. Therefore, bare land
initially will occupy 50 km2 of the Rung Sat and seeded land the remaining 700 km2.
The above sections are a brief insight into what procedures were followed
to obtain data for this simulation.
As one can plainly see, much of the data
haa baen only roughly approximated. Hopefully, more reliable field data will
be obtained for the mangroves in the Rung Sat soma time in the future. Initial
�42
numerical values for the state variables and process variables are given in
Figure
3 and Table
2.
In addition to describing the methods of getting the. data, this methods
section will also deal with the procedures that need to be followed for a
computer simulation. The method used for this simulation involved describing
each pathway by an equation that wae & linear or nonlinear function of the
variables and outside forcing functions discussed in an earlier part of this
paper. When these functional relationships have been defined, the rate coefficients can be determined for the pathways. Equations are also written showing
the time rate of change of a given state variable baaed on the inflows and
outflows for that state variable. Also, for this simulation an analog computer
was used and this meant that each time rate of change equation had to be scaled.
Theae procedures will new be discussed.
Pathway equations
Figure
5 Is another diagram of tfea model and is identical to Figure IXI-3
except that each pathway has been described by an equation. For example, the
rate of gross photosynthesis ia given SB bating equal to some rate coefficient,
kj,times the land area covered with live mangroves, Q2>tiroes available sunlight,
03. In other words gross photosynthesis equals k3Q2Q3. Similarly, one can
determine the equations for the reat of the pathways.
Calculatjlgn^gfjcate coefiictenes
Now chat the pathway equations are known, one can begin to calculate the
rate coefficients or k's. To determine the value for a rate coefficient set
the equation for a given pathway equal to the numerical value of the rate of flow for
that pathway. Substitute for all tha known values and solve for k, the rate
coefficient. As an example, let's use the mangrove respiration pathway,
�TABLE
Descriptions and Quantification of Forcing Functions,
State Variables and Flow Processes Between State Variables
OF INTEREST
DESCRIPTION
VALUE
Forcing Functions
S
Solar energy flux hitting the
mangroves of the Rung Set
Approximately sinusoidal (See Table 1 and
Figure 1) units of kcal kn~2 day"* (kcal
ba-2 yr-i)
'
Herbicide application to sangi-oves
of the Rung Sat by the U.S. Military
91,525 gal. (355,000 liters) in 1966
361,435 gal. ( , 0 , 0 liters) in 1967
14000
407,175 gal. (1,580,000 liters? la 1968
127,500 gal. ( 9 , 0 liters) in 1969
4400
21.400 gal. (82,900 liters) in 1970
17009,045 gal'3.911.9GQ liters'
Total
o
i
External seedling source that saay be
needed to regenerate the nangroves.
This may involve planting by soae
means (by hand, dropping from planes,
etc.)
IS X 10 seedlings day"1
( 4 X 106 seedlingsffio-1)would be the raaxi50
ffiiia value to give an insta&t mangrove forest
in 50 days; figure basftd on Moquillon's ( 9 4
14)
recommendation of 50 days to plant seedlings
at a density of 20,000 per heciare
Cutting effort of the South Vietnamese
in harvesting mangroves for charcoal &
other uses
K
Not actually determined but will be a value 6
that would yield a harvest rate of .36 X 10
kgs day"* (Flow #5) 1.0 X 107 kgs iao-1
12 X 10? kgs yr-1
Mangrove land that has been converted
to bare land by herbicide spraying
Maximum value would be the estimated total
manprove ares of 750 km2. Estimated value
was 524 km2 broken down by years as follows:
65
tan2
1966
State Variables
359 km2
. 0 km2
10
1967
1968
�TABLE
ITEM OF IHTEREST
2 (contH)
DESCRIPT1OH
VALUE
State Variables
Land occupied by mangroves in the
Hung Sat
Qs
Seedlings that are present in the water
at an? chosnp peviod in time for the
Tectire Rung aat
Total biossass of the Rung Sat mangroves
•
750 km2 prior to spraying by U.S. Military
possibly reduced to 226 fan2 by 1968
Maximum value of seedlings 2 x 10^
Average value of seedlings 1.0 x 10°
Maximum value of 7.5 X 10^ kf?s ( 0 0 0 gms m"2)
1,0
Average value of 3.75 .T 109 kgs (5,000 gas m~2)
Seedlings that are present on the mangro- *s of the Rung Sat
Maxiasum value of seedlings 7.65 X 1010
Average value of seedlings 1.S5 X IfllO
Flow of solar energy flux
Annual variation can be approximated by a sine
wave of maxiBKsm value 4550 X 10$ kcal km~2 day""-'-
Process Variables
.
1
1.66 X 1012 fccal kia'2 yr1"1
and tainisuss value 3150 X 106 kcal ksa~2 day ~^
1.15 X 1011 keal km"2 yr~l
Flow of solar energy flux into multiplier Annual variation also approximated by a sine
interaction with seeded land .
wave of maxisum values -1 of flow 2Si 1
50%
units of kcal Van"2 day
Ckcal km" yr" .
Flow into mangrove biomass compartment
in terms of gross production
12 X 10^ kgs day"1 1
A380 X 10& kgs yr"
Harvest rate of woodcutters to use
mangrove wood for making charcoal and
other uses
.36 X lof kgs day"1
120 X 106 kgs yr-1
Respiration and other losses (litter
fall, etc) in mangrove biomass
12 X 1 6 kgs day-1
0
4380 X 10& kgs yr-1
�TABLE
ITEM 07 INTEREST
2 (cont'd)
DESCRIPTION
VALUE
Process Variables
Rate of mangrove bicmass going into
seedling production
2.7 X 10® kgs day"1
490 X 106 kaa yr"1
Rate at which seedlings appear on
mangroves
1.03 X lo seedling- :--!
1.94 X 10 seedlings yr-1 for a month period
froas April - October each year
10% of flow 7 or .108 X 10sQseedlings/day'1
.194 X 10I ssedling/yr"1
Loss rate of seedlings to disease,
a eteorological conditions, predators
Rate at which seedlings fall froa ths
aangroves (ia Oct. and Hov. costly)
3.25 % 108 seedlings day'1; 1.94 X 1010 seedlings/
JTC~I over a two month period each year
10
Rate at which sesalings Eska it into
ths water for coloaiaatica of cthar
areas
0.7 X 108 sasdliags/day"1; 4.2 X 107 seedlings/yr"1
cvsr tha tr«o month interval menticsed for Flow 9
11
Loss rate of seedlings that are in the
water
0.35 X 10s seedlings/day"*
4.2 X JO7 seedlings/yr"3-
12
Rate of seedlings colonizing bare land
for conversion to mangrove land
0.7 X 106 seedlings/day"1
4.2 X 107 sasdlings/yr-1
13
Rate of application of herbicide by
military over the Rung Sat
355,000 liters 1966; 1 4 0 0 0 liters 1967;
,0,0
1.580,000 liters 1968; 494,000 liters 1969;
82,900 liters 1970
(65 liters/yr"1) 1966; (359 liters/yr'1) 1967
(100 liters/yr-3.) 1968
14
Rate of conversion of Mangrove land
into bare land as a result of spraying
15
25.6
Rate of conversion of bare land to
mangrove land thru natural regeneration
16
Planting rate
Variable
��k6Q5 - 2.19 X 1CT kg year"1
(1)
Calculations for the irate coefficients are shown In Table
all of the rate, coefficients are given in Table
3. Values for
4.
Differential equation writing
For each state variable of interest a differential equation can be written.
All this says is that A® ttea rate of change of variable is equal to all the
input ratea minus all the output rates for the state variable in question.
look at the level of matagrove biosnaas as an example.
Let's
The rate of change of
mangrova bioraass, dQ^/dt, is equal to the incoming rate of biomaaa production,
k3Q2JRJrainus the amounts lost through plant respiration, kgQ5, through woodcutting,
cQj, and through soraa amount needed for growth of seedlings, k^Qj. In equation
form this becomes
;
k?Q5
- Q5
,
^
•.
.
•••>••
;
(2)
The differential equations for all the atate variables are given in Table
5.
Scaling aqua tions^f or analog epaiput: er use
Because the decision was made to run the simulation on an analog computer,
it was necessary to scale all of the differential equations describing the state
variables. Scaling is required becaue® analog ccwouierfi have built into them
a naxlmurc voltage output constraint. ExcoetUr-e -hie value may yield erroneous
results. For scaling, each state variable ~4 assigned some maximum level that
�48
TABLE
3
CALCULATION OF KATE COEFFICIENTS FOR THE
PATHWAYS THAT OCCUR IN THE MANGROVE MODEL ( FIGURE III-3)
Flow #2 - Incoming Flux of Sunlight, 1 2JR
^
k2Q2-JR - .83 x 1012 fcal m"2 yr"1
- «83_x 1012
.83 x 1 ( 0 )
^70
k
2
- 1 4 x 10~3 km"2
.3
k2
Flow #3 - Gross photosynthesis for mangroves,
k3Q2Q3 - 4.38 x 109 kg yr-1
k,
3
- 4*18 _» lO9
.83 x 1 * ( 0 )
0270
k3
- 7.54 x 10~6 kcal'1
Flow #4 - Rate at which woodcutters are cutting wood, cQ.
cQ - .12 x 109 kg yr-1
c - i1?-*-1?9
3.75 x iP
c - 3.06 x 10~2 yr-1
Flow #5 - Respiration of mangroves, kgO.
k6Q5« 2.19 x 109 kg yr'1
kf-6
m
i^AzJSLiiL.
3.75 x llF
kfi - .585 yr-1
Flow #6 - Rate at which bicntase is translocated to seedlings,
k?Q5 - . 9 x 109 kg yr-i
41
k7
-
.75
- 1.311 x 1C
1
-1
�Flow #7 - Rate at which seedlings are produced,
k8Q5 - 1.94 x 1010
ko
8
- I .
3.75 xT69
kg
»5.17 seedlings 8cg"^ yr~*
Flow #8 - Kate at which seedlings go into the water to colonize new areas,
k Q6 - 3.94 x 10<J seedlings yr"1
ko
9
- 3.94 x 109 ro
1.95 x l~o"
k9
- 2.02 x ID"1 yr-1
Flow #9 - Kate at which seedlings remain beneath the parent tree,
- 1.95 xx1010 0seedlings yr'1
101
k
. 1.95 x 1010
k10
- 1.0 yr-1
"10
Flow #10 - Rate at which seedlings are available to actually colonize new areas,
*2 x ^ seedlings yr-1
.
.
11
ku
*2JL10.6
1.95 x 1010
- 2.15 x 10"3 yr'1
Flow iCll - Rate of loss of seedlings that are in the water,
2.1 x 107
8
TTTTd "
10 y '
.5 r 1
Flow tf!2 - Rate at which seedlings colonise naw areas,
k13C|1Q4 - 42 x 106 seedlings yr""1
k
13
- 42 x IP6
( 0 ( 2 x 108)
5) .
�50
- 4.2 x 10~2 yrFlow #13 - Rate of conversion of seeded land to bare land (maximum value),
k15Q2H - 365 km2 yr'1
kc
k 15
. ^
.
365
I(700)
k
is "4*8 *10~7 llter8"1 y*"1
Flow #14 - Rate of conversion of bare land to seeded land,
klfi
- 25.6
"
.2
- 2.56 x 10"8 seedlings"1 yr"1
"1
Flow #15 - Variable Planting Rate
�51
TABLE
4
Values Used for Rate Coefficients in
Mangrove Model of South Vietnam
Flow Number u;
Coefficient
____
Coefficient Value
'
1
2
V
1.43 x 10"3 km"2
3
k3
7.54 x 10~6 kg kcal"1
4
c
3.06 x 10~2 yr~l
5
k
6
5.83 x 10-1 yr-1
6
k?
1.311 x 10-1 yr-1
7
fee
5.17 seedlings kg~l yr"1
8
k
2.02 x 10"1 yv"1
_1
9
k
1.0 yr *
10
k
2.15 x 1 " yr"1
03
9
io
ll
11
K
1.05 yr"1
12
k
!
3
4.2 x 10"2 km"2 yr"1
13
H
sine wave pulse
14
k.
.
15
4.8 x 10~7 liters"1
15
k
16
12
!
6
N
2.56 x 10~8 seedlings-1 yr-l
variable yr"1
�TABLE
5
Differential Equations that Describe the State
Variables Appearing in the Model (Figure III-5)
1) Bare Land
2) Seeded Land
Q2 - A - Qj
where A is the total land area of the Rung Sat
3) Available Light
JR - J - k2JRQ2
4) Seedlings in the Water
5) Mangrove Biotaass
$5 - k3Q2JR - k6Qs - kyQ5 - cQ5
6) Seedlings in the trees
�53
is not expected to be exceeded. To illustrate, the initial value for mangrove
biorcass was chosen as 4.2 x 1G6 tons (3.75 x 109 k&s) for the entire Rung Sat and
the maximum value was chosen to bs twice that amount.
state variables are given in Table.
Maximum values for the
2.
The following steps era involved in the scaling process:
(1) Write the differential equation that describes the time rate of change
of a state variable. As an example, mangrove biomass will be used.
Si - WR * V*5 -CQ5 " Ms
at
(2) Divide and multiply each variable on the right side of the equation
by its maximum value. This gives the following result
3.26 x 1012
dt
05
750 j
109)
1
2
3.2^6 x 10 '
- c(7.5 x 109)
,(7,,5 x 10V>
7.5' x 10*
()
3
(3) Divide both sides of the equation by the maximum value for the state
variable on the left side of the equation to give
1
dQ /dt
R
x
5
-iii
>*
H
- k.
10*
- c
?7Tx io9
3.26 x 1012
i
7.5 x 10
(4)
Equation (A) ia the scaled equation that should be used for mangrove bioaass.
�54
All that needs to be done la to substitute the rate coefficient values into the
equation. The numerical values that appear outside the brackets would be the
pot settings for the analog diagram. All of the scaled equations are given in
Table
6.
A diagram of the simulation model as it would appear in the language of
analog computer symbols is shown in Figure
6. These symbols will not be
explained here but any boot, on analog computers adequately explains the meaning
of each symbol.
Simulations were run on an Electronic Associates, Inc. analog
computer, the EAI 680.
�55
TABLE
6
Scaled Equations for Mangrove Model
1) Bare land
750
" °-528i_!?L.
750 '
I
J
2) Land covered by mangroves
J75Tr~j .2 x 10
Q
2 .'-.JQll
75TT " 1 jTsT]
3)
Seedlings in the water
" '
f
Q
1 - 1.05
6
7 65
I '
*
;
- 31.5 _^
<?4
10l
°J
4) Mangrove biotaaaa
,
« 2.458 T Jn
i 3.26 x 101?-
7.5 x
,j
-
i
5)
Q
2J 750:
0.585
i775"x 10
oi . 0.1311
0.0306 _JJL. Q'
y
; 7.5 x 10 (
Seedlings hanging from trees
1
1010
6) Available Light
- 0.202
�56
Ih TM
Figure 6
�57
RESULTS
Several situations were simulated to assess the impact of selected pathways
on the level of mangrove blomaes. In most cases a family of curves will be shown
in each figure. This was necessary bacausa of the many approximations made to
obtain data for the simulationa. Another reason was the unavailability of data
for the mangroves in the Rung Sat. 'ty generating a family of curves for variables
such as gross photosynthesis, woodcutting and herbicide spraying, the actual
patterns followed by the Rung Sat mangroves may be included.
Steady-statej conditions
What would tha levels of mangrove biomass be if no spraying occurred and
the woodcutters were cutting at the rate of 3% of the trees per year? Figure
7 shows tha levels of mangrove biossaso for several rates of gross photosynthesis.
Theue rates ware 3.5, 7, 14, and 19 grama of organic matter produced per square
oater per day, respectively.
To convert these values to pounds per acre, divide
by 0.112. From an initial bioraass of 5000 gras par m2 steady state levels were
reached in 8, 6, lo end 12 years from tha lowest to the highest rate of gross
photosynthesis.
Figures
>
8a and 8b show the effect of woodcutting on mangrove biomass.
8a the rate of gross photosynthesis is 14 gins per m2 per day. If
2
no mangroves are cut, the mangroves attain a biomass level of 7200 graa per m .
In Figure
At cutting rates of 3%, 30%, 60%, and 3003 of the trees, the steady state levels
of blonasa were 7000, 5000, 4000, and 1500 gma p«r B , respectively.
In Figure
8b the rate of gross photosynthesis was lowered to 7 gms per
v? par day. In tha absence of cutting, the mangroves would be able to attain a
biomass of 4000 gas per m2. Cutting rates of 32, 30X, 60%, and 300%, would give
nangrove Morass levels of 3800, 3000, 2200, and 900 gms per m2, respectively,
at steady state.
�00
0
I
v>
to
IA Gross Photosynthesis = 3.5
B
"
"
= 7.0 "
C
D
"
"
=14.0 "
=19.0 "
"
"
"
"
"
"
"
"
5 s 10000
0
o
O
2 fc, 5000
B
D
1 \^
g
0
i
i
25
50
75
years
KX)
�I
A No Cutting
8 Cutting Rate equals 400
11
1500
C
"
"
n
Q
II
H
2400
13
(>
4500
"
2«i. ! 0,000 E
E
A
Li.i o
> Q.
O
S
gm frf2year~!j
" " "
10 x!0 4 &
"• " "
a
" " 5I
o
5,000
Bl
j^—
IL
cl
TO
0
CO
5x!0
4
•o
c
3
o
Q.
s\
!
a.
25
50
75
10
TIME, years
Ul
o
�CO
CO
<
IA No Cutting
T-lOxl0 4 £
lonooJB Cutting Rate equals i!4 y grn rn^yr"1}
8
I0 000
H
»
•c
„ y
„
n
«, u *.,
900
D
UJ <»
"
"
11
it
ow
er |
^2
<£ C3>
s
"
"
1300 "
2700
i!
I
'
Q.
to
5xl0 4
5000
A
wV
\
D
att
ai
"
0
25
50
TIME, years
75
E
(
_™1
100
o
0_
�6J
Herbicide intensity
In Figure
9 fiva intensities of herbicide spraying are shown occurring
during a five /ear period. This is roughly the number of years widespread spraying occurred in the Republic of Vietnam (period from 1965 to 1970). The greatest
level of spraying is represeutad by
curve A which shows a maximum level of
about 1.1ra.tIH.onliters sprayed for any one year. For the full five-year period
this curve would give a total amount of herbicide sprayed of 3.5 million liters.
For curve B the peak level wao 0.55 million liters and the total was 1.66 million
liters.
Curves C, D, and E gave peak levels of 0.28, 0.14, and 0.05 million
liters and total levels of 0.89, 0.45, and 0,16 million liters, respectively.
Effect ofL IMrbicide spraying
Figures
lOa and lOb show the effect of herbicide spraying on mangrove
land and mangrove biosaas, respectively, whati :he rate of gross photosynthesis
is only 3.5 gms per m2 per day. In Figure
lOa the land that the nangroves
cover is reduced from 750 km2 to 615, 410, 245, 140, or 25 km2 at total herbicide
dosages of 0.16, 0.45, 0.89, 1.66, or 3.5 million liters, respectively. To convert these values to acres multiply km2 by 247, The times required for the. land
to be recolonized by mangroves would be 45, 65, 90,>100 and»100 years at
increasing rates of total herbicide dosage.
Figure
',
lOb shows the effect of herbicide on mangrove biomass. At the
five levels of total herbicide dosage of 0.16, 0.45, 0.89, 1.66 and 3.5 million
liters, mangrove biomasa was reduced to 2100, 1500, 1200, 700 and 200 gms per m2,
respectively, from an Initial oteady state biomass level of 2000 gms per m2. The
mangroves returned to the initial level of biomass in 10, 40, 60, 90, or>100 years
depending on the total herbicide dosage applied during the five-year period. As
spraying Increased, so did the time for complete recolonization to initial steady
state levels.
Figures
. H ^ i-j.£*.;'., I \) V..
t-.' [
y;v V A.
lla aad lib show the effect of herbicide on mangrove land and
�3x105
6
IxlO -
CO
LsJ
2xl0 5
o
L.J
x
?
o
,5xl0 6 -
0
0960)
e
I
JO
15
TIME, years
20
(ISSO)
N)
�A No Spraying
B Total Herbicide Sprayed
II
II
C "
O CM
II
UJ £
y
iLJ
sr
E
, 900 HF
il
fl
II
JBxfO 6 liters
.45x!06 "
.89x!06 "
II
II
225,000
600 -i
150,000
in
a>
L.
O
D
300 -|
ft
n
75,000
50
IB
O
tD
TIME, years
75
100
�0.16 x 10s liters
m E
10,000
100
E, years
lOxlO4 2
�J 900
A No Spraying
B Total Herbicide Sprayed = QJ6xiOs lifers
C "
"
«
= 0.45x!0s «
S
D "
"
"
0.89xf06 "
E "
p
>>
"
»
-
lL§
225,000
O
600
o
n
B
150,000
300
75,000
0
25
50
TIME, years
a
�CO
s
2
OCM
m e
10,000
LU
§ g
^ o
5 fe 5000
A No Spraying
B Total Herbicide Sprayed= O.ISxfO6 lifers
C
"
"
' "
=0.45xl06 "
"
D
"
"
»
=0.89x10® "
IJ
E
«•
= L66x!06 l!
h 5x !04
B
£
50
TIME, years
75
100
�67
mangrove biomass when the rate of gross photosynthesis was 7 gms per m per day.
In Figure
lla the land covered with mangroves vas reduced to 600, 430, 275,
150, or 75 km at herbicide dosages of 0.16, 0.45, 0.89, 1.66 and 3.5 million
liters. The times required for recolonization of the land were 20, 35, 50, 60,
and 80 years as spraying increased from lowest to highest rate.
Figure
lib shows the effect of herbicide on mangrove biomass. From en
t\
initial steady state biomass of 3800 gms per m" the biomass level was reduced
to 3400, 2800, 1800, 1200 and 500 gas per IE* from the lowest to the highest
amounts of herbicide dosage. The mangroves returned to the pre-spraying•levels
in 10, 20, 30, 50, or 75 years after spraying at the various levels of herbicide.
Figures
12a and 12b show the effect of herbicide on mangrove land and
mangrove biomass when the rate of gross photosynthesis was 14 gms per m2 per day.
In Figure
12a the mangrove land area was reduced from 750 km2 to 660, 470,
310, 160, or 80 km2 at herbicide dosages of 0.16, 0.45, 0.89, 1.66 or 3.5 million
liters sprayed over the five-year pariod. The times required for recolonizacion
of the sprayed areas were 15, 25, 35, 4£, or 60 years for increasing levels of
herbicide.
In Figure
9
12b mangrove bioiaass was reduced from 7000 gms per m to 6600,
2
5700, 4000, 2500, or 1100 gma per ro depending on tha level of herbicide application. The mangroves returned to presp«.aying biomass level in 10, 20, 25, 30, or
40 years at the selected herbicide dosages.
Figures
13a and 13b show the effect of herbicide spraying and a 30%
cutting rate on the mangrove land area and the mangrove biomass. In Figure
13a
mangrove land area in reduced to 655, 510, 350, 220, or 55 km2 at the five levels
of herbicide application. The times required for recolonization were 15, 25, 35,
45, or 65 years.
In Figure
13b mangrove biomass is reduced from 5400 gms per m2 to 4800,
4100, 2600, 1300. or 700 gms per or at the five levels of herbicide application.
�68
fi"6
g"
8g
A No Spraying
B Total Herbicic^ grayed5 0.16xlO6liters
C
"
"
"
»0.45x!0® "
0 "
"
"
»0.89xl06 "
a
E "
"
M.SSxId8 "
"
"
"
=3.50j(l06 " -225,000
900- F
600-
^150,000 «
o
300H
"75,000
UJ
§*
< CD
25
50
75
100
TIME, years
Figure 12a
�vO
CO
CO
O^
5 ^
10,000
B
UJ o
> 0.
g co
g g
2 E
A No Spraying
B Total Herbickie Sprayed = O.I6xl06iiters
r
it
C
"
• ••
»II
= 0.45xl06 "
it
(I
D
II
= 0.89xi06 « hJOxlO4
ii
II
II
E
= I.SSxIO6
o
I
!
II
o
6
II
F
= 3,50xl0 "
o
i*
a
CD
Q.
5xl0 4
5,000-
I
25
50
TIME, years
75
�70
A i\Jo Spraying
B Total Herbicide Sprayed*0.16xlOfliters
C "
•
" » 0.45x10® »
D "
"
" «OB9xlOf "
6
E
900- F
"
"
"
"
"
"
* | .66x I0 "
«3.50xl06 " -225,000
O O UJ
600-
H50000 «
u
300J
"75,000
I
25
T
SO
TIME, years
75
100
Figure 13a
�CO
CO
10,000
A No Spraying
B Total Herbicide Sprayed* 0.16xID® liters
it
II
19
C
= 0.45x!06 "
H
IJ
II
D
= 0.1
10 x I04
II
It
II
E
11
II
II
F
= 3.5xl06
©
LLJ
Q.
Q.
O w
o: s
5xt0 4 > f
5,CK)0-
3
<£
I
CO
cr
25
50
TIME, years
75
106
�72
The times required for the mangroves to return to the prespraying biomass were
15, 25, 35, 50, or 60 years.
Figure
14 shows the effect of seedling availability on the rate of
recolonization when the level of herbicide dosage was 3.5 million liters and
the rate of gross photosynthesis was 14 gma per vr per day. The time required
for recolonization by the mangroves was 40, 70, or 100 years for seedlings
available all year, 6 or 3 months out of each year. As the availability of
seedlings is decreased, then the time to recjh a steady state level of mangrove
biomass is increased.
Figures
15a, 15b, 15c show the effect of artificial planting of seedlings
on the recolonization by mangroves. Each figure gives two planting rates of
15 to 75 seedlings per acre per year in addition to natural recolonization. In
15a the rate of gross photosynthesis is 7 gms per ra2 per day and the
Figure
cutting rate is 3% of the trees per year. Under these conditions and no additional
planting by man,recolonization occurs in about 80 years. At a successful planting
rate of 15 seedlings per acre the mangroves recolonize in 35 years and in 12 years
at a successful planting rate of 75 seedlings per acre. Success in planting is
10% of the seedlings planted.
In Figure
15b the rate of gross photosynthesis is 14 gms per m* per day
and cutting is 3% of the trees per year. These conditions and no additional planting by man result in recoloniz&tion by the mangroves in 40 years. At successful
planting rates of 15 and 75 seedlings per acre per year, times for recolonization
were 25 and 12 years.
In Figure
15c the rate of gross photosynthesis is 14 gma per day and the
cutting rate has been increased to 30% of the trees per year. These conditions
and no additional planting by man result ir recolonization by the mangroves in
60 years. At successful planting rates of 15 and 75 seedlings per acre per year
'
•'
V •
.
' • - • , ' • • , . . • . •
the timee for recolonization were 30 and 12 years.
�73
A Seed! ings Always Available
3 Seedlings Available 1/2 of each year
C Seedlings AvoiSabis 1/4 of each year
s
m<
-lOxlO 4
g 10,000-
f- o»
-5xl0 4 "I
5,000
0
23
50
75
100
TIME, years
Finure 1A
�74
A No Planting
B Successful Planting
o
Seedlings Per Acre
OQcu
E 10,000-< C Successful Planting
Seedlings Per Acre
Rate of 15
Per Year
Rate of 75
Per Year
I*
O
r-
VI
4
-5xl0 l
£
5,000 J
TIME, y©ars
Figure 13b
B .Successful Ptanting Rdt© of
Seedlings Per Ac/e P©r
C Successful Planting Rat® of
e
8
E 10,000 -
1 I 5,000'
TIME, years
15*
�CO
C/5
!<vxx>
A No Planting
B Successful Planting Rate
Seedlings Per Acre Per
C Successful Planting Rate
Seedlings Per Acre Per
of 15
Year
of 75
Year
lOxlO 4 g
a.
LsJ
5
cr
5xl0 4
I 5,000
g
o
Q.
A
•jj
H00
Ul
r> .
I
25
50
TIME, years
§
T
75
100
�76
DISCUSSION
An important factor that may influence the size of a mangrove forest is the
availability of nutrients. In Figure
7 the several different rates of photo-
synthesis represent cases of different nutrient availability. The curves in this
figure demonstrate that in conditions of plentiful nutrients the mangroves are
healthy and form large trees. If nutrients are scarce, then the mangroves are
low in biomass,, This would tend to support observations that the largest mangroves tend to grow along the banks of tidal rivers where the currents constantly
bring nutrients to the trees. The bicmaas values at steady state are relatively
low compared to eoaio values that have appeared in the literature. Golley (1968)
reports a standing crop of 28,000 grema per square metar for mangroves in Panama
and Lugo and Stiedaker report bioroass values ranging from 8700-13,400 grams per
square taster for roangrovea in Florida, For Thailand, Banijbatana (1957) reports
yields for mangroves of 10,000 grams per square meter. Also, the value used in
this simulation was 5000 grams per square meter from the study by Golley ££ jtl
(1962) in Puerto Rico.
The low values may have also resulted from choosing a rate of respiration
that w&a too high. If respiration la very high, then the rate of net production
will be low. The effect of this is to give the low biomaes values shown in Figure
7. The low biomass values could represent areas of mangroves in the Rung
Sat such as thosa areas colonized by species of Ceriojts, a bush-type mangrove
that can colonize disturbed areas. The higher biomass values would correspond
to mangroves growing along the banks of the tidal channels.
The curves in Figure
9 wars simulated to show the effect that varying
rates of herbicide application may have on the Rung Sat mangroves. From Figures
10 -
13 thla effect can be easily noted. The circles in Figure
9
Indicate the herbicide levels that actually occurred during each of the years
�77
from 1965 to 1970. Curve A In Figure
9 is the closest approximation to the
actual spraying conditions. The total amount of herbicide sprayed on the mangroves
of the Rung Sat was 3.9 million liters which compares with the 3.5 million liters
of Curve A in Figure
-9. Tor this reason the discussion will be involved with
this rate of herbicide application.
At this high leyel of spraying and a rate of gross photosynthesis of 3.5
gms per tn2 per day(Figure
lOa) the area of bare land produced was 725 km
or 72,500 hectares. Therefore, the amount of spraying was 48.3 liters per hectare
or 5.05 gallons per acre. This corresponds roughly with the stated application
raff: of 3 gallons per acre. Under better nutrient conditions (Figure Ha) the
A
area of bare land produced was 675 km . The herbicide application rete in this
case was 51.9 liters per hectare. Under possibly nutrient-rich conditions (Figure
12a) the area of bare land produced was 670 km for an application rate of 52.3
liters per hectare. Since the application rate is greater than 3 gallons per
acre (28.7 liters per hectare), this probably means that many areas were sprayed
more than once.
Figures
lOa, Ha and 12a show that the rate of recolonizatlon can depend
quite strongly on the level of nutrients available. If nutrients are a problem
as in Figure
lOa, then the mangroves take over 100 years to reach prespraying
land areas. In addition the mangroves that do become established are low in
blomass per m2 (Figure lOb)« With no nutrient problem, (Figure 12b) the mangroves
recolonize the sprayed areas in years and reach reasonable level of biomass(Figure
12b).
Woodcutters were also shown to have an Impact on the rate of recovery of
mangroves. The bare land was colonized in 60 years at a, cutting rate of 3% (Figure
12a) and in 65 years at a cutting rate of 30% of the trees (Figure 13n). Thus
a tenfold increase in cutting rate delays the recovery only 5 years, but Che biomass Is lowered by 1600 gms per m2 (7000 gma per m2 in Figure
12b and 5400 gms
�78
per m^ in Figure 13b). An Interesting outcome of these results is that the
resulting mangroves would probably be undesirable for use as charcoal. The
highly prized trees would be continually selected against by the woodcutters and
the poorer valued trees would proliferate.
If the results of these simulations .ire correct, then both woodcutters and
nutrient availability could act to delay tha recovery of the mangroves of the
Rung Sat. The need arises here for data on the level of nutrients in various
sections of the Rung Sat. Also, at what rats are the woodcutters harvesting the
remaining live mangrove trees?
Another variable that could very easily be the most important single factor
limiting the recovery of the mangroves Is the availability of seedlings to
colonize the bare areas. Figure 14 shows very positively that if seedlings are
only available two months during each year then recovery rates are extremely
slow. Recently, E. B. Knipling of the University of Florida and others returned
from Vietnam with photographs of the sprayed areas. These photographs support
the hypothesis that lack of seedlings in the primary reason the bare areas are
not being colonized by mangroves. In these photographs the seedling density was
estimated to be one seedling per62m2 of laud. When one studies the photographs,
it becomes quite apparent that seedlings are not reaching these areas with any
regularity.
Even areas flushed regularly by the tides contain very few seedlings.
Some seedlings are present, however. What is th<i source for these seedlings?
If seedling scarcity is the primary reason for the very slow recovery of
mangroves, then one alternative might be to plant seedlings. Figures 15a~c,
show that planting seedlings will speed recovery, if lack of seedlings
Is the only problem, then a mangrove forest of adequate biomass is possible very
S
':
quickly by artificial planting as shown in Figure 15b. If nutrients or woodcutters are the limiting factor, then planting will speed up recovery, but the
steady-state biomass levels are low.
�79
VALIDATION OP SIMULATION RESULTS AND DATA USED
Validation of the data used in the model has been difficult because of the
war In South Vietnam. However, several people on the Committee have made trips
to South Vietnam for onsite investigations. Golley made several counts of the
density of seedlings. He found the seedling density in the water to be .02
seedlings m~2 in the sprayed area. Golley also counted a density of 46 sellings
2
per ra along the banks and levees. Farther away from tidal influence, the seedlings
density was only .03 seedlings m""'-. Teas counted the number of seedlings on trees
°f Ceriopg sp. and found a range of 364 to 586 seedlings per tree. Knipling and
Weatherspoon took many photographs from ground level of the Rung Sat. From these
photographs the area of land in each photograph was calculated and the number
of seedlings counted to give only 1 seedling per 62m2.
in Puerto Rico the
needling density ranged from 7-35 seedliugs m~^.
More detailed analysis of maps for the Rung Sat (see Ross's text) have
revealed that the total area, including water, is 1050 km2 of which 23% is water.
This would giv* 242 km of water area as compared to 250 km* used for the simulation.
The detailed analysis also revealed that only 51% of the land area was
2
In mangroves prior to spraying. This gives an area of 535 km as compared to
2
700 km used in the simulation. A more detailed analysis also came up with 600
2
km as the area sprayed as compared to 525 for the simulation.
�80
REFERENCES
Banijbatara, D», "Mangrove Forest in Thailand",
Science Congrpi«, Pacific Science Assoc.
Proceedings Nintt» Pacific
22-34.
1957.
Golley, F. B. Mineral Cycling in Tropical Forest Ecosyatetts. Institute of
Ecology. University of Geoi^ia.
1968.
Golley, F. B., H. T. Odum, and R. F. Wilson. The Structure and Metabolism of
a Puerto Rican Red Mangrove Forest in May. Kcology 43, 9-19.
Lugo, A. and S. C. Snedaker.
1962.
The Role of Mangrove Ecosystems in the. Maintenance
of Environmental Quality and a High Productivity of Desirable Fisheries.
Progress Report to Bureau of Sport Fisheries and Wildlife.
1972.
Lugo, A., M. G. Sell, and S. C. Snedaker. Mangrove Ecosystem Analysis. Presented
at the Modelling Conference at the University of Georgia.
Kinarik, C. L. and A. L. Bertram.
;
1973.
Evaluation of Camau Peninsula- Defoliation
Targets of 9 November 1962 in Republic of Vietnam. U.S. Army Biological
Laboratories Report. 1962.
Van Cuong, H. Flore et Vegetation de la Mangrove de la Region de Saigon-Cap
Saint Jacques, Sud Vietnam.
1964.
Yearly Weather Summary for Saigon 1964-1967 Directorate of Meteorology. Republic
of Vietnam.
�81
LIST OF FIGURES
1. Map of the Rung Sat zone southeast of Saigon
2. Model of the mangrove community in. the Rung Sat zone of South Vietnam
showing the important storages, forcing functions, and pathways
3. Model of mangrove forest in the Rung Sat /one of Vietnam with numerical
values for the state variables and selected pathways
2
4. Annual variation in solar radiation (kilocalories per m per day) for
Saigon, Vietnam during the period January 1964 to October 1967
5. Model of mangrove forest in the Rung Sat zone of Vietnam showing the
equations for each pathway of interest
6. Analog computer circuit diagram of the model of the mangrove forest in
the Rung Sat jsone of Vietnam
7. Steady stat j levels of mangrove biomass attained by the Rung Sat mangrove
forest in Vietnam at four rates o" gross photosynthesis (cutting rate
equals 3% of the trees per year anJ initial biomass equals 5000 gm per m^)
8. Effect of cutting on the mangrove forest of the Rung Sat in Vietnam (a)
j
Kate of gross photosynthesis equals 14 gms per nr per day (b) Rate of
•*
gross photosynthesis equals 7 gms per m4 per day
9. Variation of selected herbicide application rates during a five year period
of spraying
10. Effect of herbicide spraying on (a) mangrove land and (b) mangrove biowass
in the Rung Sat area of Vietnam (wood-cutting rate equals 3% of the trees
per year and rate of gross photosynthesis equals 3.5 gms per m^ per day)
11. Effect of herbicide soraying on (a) mangrove land and (b) mangrove biomass
in the Rung Sat area of Vietnam (woodcutting rate equals 3% of the trees
per year and rate of gross photosynthesis equals 7 gms per sn* p)ar ,jay)
�82
12. Effect of herbicide spraying on (a) mangrove land and (b) mangrove blomass
in the Rung Sat area of Vietnam (wood-cutting rate equals 3% of the trees
per year and rate of gross photosynthesis equals 14 gms per m^ per day
13. Effect of herbicide spraying on (a) mangro\e land and (b) mangrove biomass
In the Rung Sat area of Vietnam (wood-cutting rate equals 30% of the trees
per year and rate of gross photosynthesis equals 14 gms per m^ per day)
14. Effect of seedling availability on the rate of recolonization by the man—
groves of the Rung Sat in Vietnam (wood-cutting nte equals 14 gms per m
per day and total herbicide applied equals 3.5 million liters or an average
of 48.3liters per hectare)
15. Effect of seedling planting by man on the recolonization by the mangroves
of the Rung Sat in Vietnam (a) Wood-cutting rate equals 3% of the trees
o
per year, rate of gross photosynthesis equals 7 go- per m per day and
total herbicide applied equals 3.5 million liters; (b) same as (a) except
2
that the rate of gross photosynthesis is 14 gms per .« per day; (c) same
as (a) except that the wood-cutting rate is 30% of t. i trees per year and
rate of gross photosynthesis is 14 gma par m2 per day.
�83
LIST OF TABLES
1. Monthly solar radiation data for Saigon from January 1964 to October
1967 (units of Real per 0)2 per day).
2. Description and quantification of the forcing functions, state variables
and flow processes between state variables or between state variables and
forcing functions that are given in Figure 3.
3. Calculation of rate coefficients for the pathways that occur in the mangrove
model (Figure 3).
4. Values used for rate coefficient's of pathways in model (Figure 3).
5. Differential equations that describe the stt.te variables appearing in
the model (Figure 5).
6. Scaled equations for use in the simulation.
�A.
Nutrient Models and Perspective on Mangrove Recovery in Rung Sat
Joan Browder, T,, Ahlstrom, and M. Sell
After the trees of the Rung Sat were killed by herbicides, their
leaves and wood were almost entirely removed by wood-cutters, tidal
action, or decomposition, with a loss of nutrient content. Models that
summarize the orders of magnitude of nutrients such as nitrogen and
phosphorus per area of land are useful for providing seme perspective
on the fraction of nutrients remaining in muds, roots, and water.
By comparing the stocks present and those removed with the rates of
flow it is possible to gain some idea of the approximate time required
for nutrient restoration. Preliminary models for nitrogen and
phosphorus are given in Fieure 1.
Details of the bases for
estimatea shown in the energy diagrams are presented in Tables 1
and 2. More detailed data arc- being developed in another subcontract by P. Zinke, and additional diagrams and more precise numbers
for compartments and flow rates can be added when totals are available
from that work.
The models are drawn in energy language with some of the main
driving functions shown but highly simplified. Notice that the
phosphorus model has a higher percentage of total supply in leaves
and wood than does the nitrogen model. There is an apparent stockpile
of nitrogen in the mud. Therefore phosphorus may be the more limiting
of the two nuorients in terras of regrowth.
The estimates of river inflow are very rouf^i approximations,
pending receipt of better data. If the magnitude assumed is correct,
the Rung Sat obtains mora than enough phosphorus to supply nutrient
needs for regrowth. Even if the order of magnitude were less by a
�85
factor of 100 there would still be enough.
Because of the river situation,
the models suggest that nutrients are not limiting. However calculations
imply that soil organisms such as algae and bacteria may play an important
role in incorporating nutrients from the river into the mud, thus making
them available to mangrove roots. Exchange of nutrient-rich water with
the mud ie limited by the extremely low rate of water penetration due to
permanently water-logged conditions (Clarke and Hannon,1967). The ability
of mangrove soils to supply nutrients for the reestablishment of mangrove
vegetation in the Rung Sat may be greatly dependent upon the status of
soil organisms in the period following herbicide application.
in Fig. 2
is the model that has some main aspects of coupling of nitrogen and phosphorus.
�1.9
2
Rates in g/m /yr
Quantities
in
g/m
^
\8.5
To
Sea
Deeper Mud
2
Woo'.'
Cutting
14.7
'To Sea ^ To Deeper Mud
Fig. 1. Summary of nutrient cycles in mangroves forests of the Rung Sat.
�Table
1.
Basis for calculation of nitrogen stocks and flow rates,
to compartments and pathways in Figure 31.
Explanation
(IT Rate of incorporation into above-ground biomass
This is a function of tha rate of photosynthesis. Lugo, Sell,
and Sne*5afc@r (unpub.) found that, In tha mangroves on th@ west
coast of Florida, rate of photosynthesis was approximately
10.72 grams Carbon/ra2 day. The ratio of nitrogsn to carbon
taken Into the tree roust be roughly equal to the ratio of
nitrogen to carbon in the tvital biosiasa of tha trea. Golley's
(1968) value for nitrogen of 0.7psrcent organic matter was
divided by ths ainount of carbon in organic natter (approximately 0.5) to determina tha ratio of nitrogen t© carbon.
(2)Export of nitrogen by woodcutters
Stands of inangrovas in Vietnam are generally cutovsr about
ones every tk-snty years, so the removal rate is approximately
5 percent of tha rat© of photosynthesis. Ths ratio of nitrogen to organic matter in eangrovs ^ood is approxiisately ths
same as that for th« overall trsa, 0,7 percent. Ths ratio
of carbon to organic natter is 50 percent.
Numbers in parenthesis relate
Equation
( 0 7 gC/ra2'Day)(.007 gN/lg OM)
1.2
(lg CM/.5g C) «(.15 g N/ra2'day)
(365 days/year) * 54.75g N/m2.yr.
(10.72g C/m2-day)
(.)
05
( 0 7 H/l g OM) (lg OM/,5g C) *»
.0g
(d0075g N/m2«day) (365 days/year)'
2.92g N/m2.yr.
(3)Miscellaneous loss of nitrogen from biomass
In a steady state system the rate of outflows should roughly
equal rate of inflows. Nitrogen loss may occur through transpiration and unknown mechanises as well as by leaf and wood
fall and wood removal. The flow rate for miscellaneous nitrogen loss is calculated as followst
(,15g N/m2-da^-(.048g K/m2.day) incorporation leaf & wood fall
(4)Rate of nitrogen contribution to water pool by leaves,
wood, and miscellaneous material falling front mngrove trees
Heald' (1971) showed that 2.4 grams organic !aatter/zr,2.day fell
from mangroves in a riverine forest in south Florida. This
value multiplied by the amount of carbon per gram organic
( . g CM/n»2.day) (,5gC/lgOM)
24
(.003g N/m2-day)(0,094g
(365 days/yr.) « 34.31g N/m2-lay
(.02g N'/g CM) (lg CM/.5g C)
( . 4 g N/m2.day) (365<1ays/yr.} =
006
17.52g W
�Table -1. Continued
Explanation
Equation
matter (.5g C/lg OM> gives the aiaouat of carbon entoring ths
water pool from this source each day. This is isultiplied by
tbe amount of nitrogsn par gram carbon to giva grsss nitrogen/
Rjz»day entering tha water pool. Gollsy found that, tha ratio
of nitrogen to organic ratter in ths leaves of Panamanian
tropical forest trees, including raangroves, was higher than
th&t in overall biesaass—-2.0 percent.
(5)Rate of nitrogen entry into the Rung Sat water pool froia
rainfall
The acounfe of nitrogen contributed to ths tsater pool of Rung
Sat by rainfall waa estimated frost values for Lake County*
Fla., reported by Snedaker and Pool© (1972), which was 7.0Kg/
hectare^yr. Rainfall in the Lake County area is approximately
50 in/yr., whila that in the Fang sat is ebout 80 in/yr.,so
tha value for Lake County was adjusted to tha area of greater
rainfall by multiplying by 1.6 ( 0 5 )
8/0.
(6)Flow of nitrogen from the Saigon River into the wster pool
of ths Rung sat
The flow of tha Saigon River at a point insvsdiat^ly below Saicon and above entry into the Rung Sat is 60-90 meters/min. {an
averag© value of 75 naters/min. was used in calculations).
This assounts to 75(60 min/hr) (24 hr/day)*1.08xl05 maters/day.
This valua was doubled because one other river also flows
across £be Sung Sat. Tha width of the Saigon River at the
point measured is approximately 400 testers. The depth of the
river at that point was approximately 12 meters. By raultiolying the meter flow per day by the depth of tha river end
the width of the river, the total aiaount of river water flowing over the Rung Sat was estimated. Th© total area of the
Rung Sat is 700 Sca2»7xlOs ro2. This value divided into the
total amount of river water entering the Rung Sat provides
an average amount of river water flowing across the average
meter square of Rung Sat substrate each day. The concentration of nitrogen in the river is approximately equal to that
(7.0kg N/ha) (lOOOg/kg)
(1 ha/10,000 m2) ( . ) <
16
1.095g H/m2.year
2 4 0 m) (12 m) (l.OS x 105 m/day)
(0
(1/7 x 108m2) (2g N/m3) =
( . 6 N/m2'day) (365 days/yr.) =
29g
.4g N/m2/year
CD
09
�Table -1. Continued
explanation
Equation
of any other large river that receives sgwage frcsa a large
city* This value is approximately 2 g/ra (Gdura, pars.
( ) Export of nitrogen from a mangrove swarap as dst.ri.us end
7
river runoff
This is a3 two way flow because there is always son® eacKjr.t
(.14 g/K5 «day) of nitrogen entering the s^amp from the ssa.
The flow in the other direction is greater, hessav@r9 for the
combined stion of river flow and tidal flux carries out to
the estuary 13.4 percent of the gross photosynthesis (dstritus
from leaf, wood, and miscellaneous fall) and all tha nitrogen from tha rivsr that is not absorbed into the mud with soil
eater.
( 0 3 N/ra2.day) + (2.9Sg N/m2'day} +
.0g
from rain
from river
(.04Sg N/m2*day) * (.005g N/mz'day)from detritus
from mud
(.0279g N/wz»day) = 2.93Sg N/»2*day =
concentration of nitrogen in the water
pool without export to sea
(2.S!3Bg N/sn2'day) - (0.21g N/m 2 'day) =
2
H/K*d£y)(365 days/yr.)
*
1013. 61g N/m2>year
( ) Movement of nitrogen from water pool into mangrove mud
9
Calculations based on data from Clarke and Hannoa (1967)
indicate that the rate of water penetration into mangrove
soils varies from approximately 1 to 10 centimeters par
day, depending on the number of crabholes the soil contains
The slow rate .of water movement is due to the almost consi stantly water-logged state of these soils, which are located almost entirely in the intertidal sons. The presence of burrows maintained by Uca and other crabs increases
the rate of water penetration about tenfold.
The amount of water from the water pool that can be
absorbed into one square meter of mangrove mud each day can
be estimated as followsi
i
•>
Absence of crabholesi (.Olm)(1m2) 2* 0.01 7nfwater/hr«day
°roxittiity to crabhojesi ( in») (la ) = .1 -n3 W9ter/m2»day
.
The flow of nitrogen into the water pool from the
river and the sea is aporoxiraately 1.55 g/nr'day, assuming an average deoth of one meter over the entire Rung Sat
(0.155g K/m2*day) * (0.02og N/m2.day):
(O.lSSg iv/m2.day)(365 days/yr.) =
62.05g N/m2.year
�Table
1.
Continued
gxolanation
Equation
and that river tratsr end sea watar are, on the averag©, mixing in a 1*1 ratio. If this mixture is absorbed into one
raster square of substrate psr day according to tha above variation thsn the flow of nitrogsn into ths ©abstrsts varies
also, as follc^-Si
Without crabhoies« (.01 Bs3*sater/m2arsa)(l.|5g
0.0155 g N/sr»day
With
crabholest ( 1 8s3water/r&2area)(i.|5g
.
0.155 g K/ra2»day
Enough nitrogen taust move into the soil to replace the 0.15 g/
m*«day of nitrogsn being used in photosynthesis. It th© concentration of nitrcgan in th© soil is a@ high (4CO-800 g/m2) as
estiTtuated'^by Sinks even issors nitrogsn may be moving into ths
soil than is taken up by tha trees. Othar methods of nitrogen
absorption maybe operating. Perhaps algae, bactsria, and filtssrfe®<3ing organisms oa prop roots and at ths surface of tha mud
ara actively taking in nitrogen, concentreting it in th®ir tiss-oss, end releasing it in excrement and with death. A nitrogen
concentration of 400-SOO g/ra2 in the soil compared to 0.21 g/
Rj2 {assuming 1 ra d©pth) in the w&tsr pool suggests that am
effective means of reisoving nitrogsn froa ths water snd holding it in the soil raust be operating. In addition, nitrogen
measurements ars nesded on this aspect of tha problem of nutrient cycling in sangroves.
Meanwhile, the flow of nitrogen from the water pool to the
mud has bean set at 0.1S3 g N/m2*day to allow for enough nitrogen to mast the requirements of the rate of photosynthesis by
mangrove tress plus some excess to allow for lev rates of nitrogen loss into the deep mud and back to the water pool.
(9) Nitrogen flow from suf~fa.ce soils to deep mud
The concentration of nitrogen in deep muds suggested by 2inks is
.383 gN/m2-day
.020 g N/:n2«day vary high compared to that of the surface muds (see last entry in
from water pool
from roots
this table). The soils on which the mangroves were growing may
have accumulated over a bed of nitrogenous peat, or leaching of
.170 g N/m2-day - .005 g N/m2-day »
nitrogen into deep soils may be taking place. The rate of leaching
to roots
to water pool
,023 g N/m2-day x 365=10.22 gN/mz.yr
�Table
1. Continued
Explanation
Equation
to deep muds can be abprcximated for a steady-stats system.
(10) Rate of loss of nitrogen from mud to water pool
Loss to the water pool is probably lees than th@ loss to
deep eoils, since the deep muds have such a high concentration
as reported by Zinke. This was assumed to be ths case and
tha flow rate was calculated for*.a steady-state system.
.193 g N/m2«day + .020 g N/m2*day from water pool
from roots
.170 g K/m2«day - .023 g N/m2*day »
to roots
to deep mud
.005 gN/m2'day x 365=1.325g N/m2«yr.
(11) Rate of uptake of nitrogen from mud by mangrove rorts
Nitrogen uptake from raud by the roots* like nitrogen incorporation into above-ground biomass, is a function of the
rate of photosynthesis, which is approximately 10.72 g C/m2«day
in South Florida (Lugo, Sell, and Snedaker, 1973). According
to Gollay (1858), the nitrogen content of roots of tropical
trees is 0.8 percent of the organic matter, a value slightly
gr@atsr than that of the overall tree. Tiie ratio of carbon
to organic natter &s about 0.5.
(12) Rate of nitrogen loss from roots to mud through root death
and decay.
In a mangrove forest in South Florida, Sell {pars, comas.) found
that approximately 15% of the trees were d*aa. With the death
of tress, roots gradually decay and release tueir store of
nutrients back to the soil. Decomposition precedes very slo&ly
in water-logged mangrove soils, which are highly anaerobici
however, the fact that death is a continuous process ta©ans that
some decay is always going on. If we assima that 155S of the
roots in ths soil are in a state of slow decomposition, *hen
aooroxinately 0.15 tines the rate of uptake by the roots is being
released to the soil.
OS/ Pulse of herbicide apolication, increasing the rate of leaf
fall and rate of wood removal by woodcutters until the supply is
depleted.
Trees are killed and the above-ground biomass is reiaoved by woodcutters, tidal flux, and decomposition.
(1C.72 g C/m2-day)(.OOS g N/lg CM)
(Ig CM/.5 g C) 4.1699 g N/m2*day)
(365 days/year) * 62.05 g N/m2«yr.
.15 (0.1699 g N/m2-day) =
(.020
g N/m2-day)(365 days/year}'
7.30 g N/m2«yr.
�Table
1. Continued
BxolanaticB
(14) Nitrogen present in compartments, according to
estimates by Zink@ (pars, cossa.).
Equation
Leaves and wood
60 g
Roots
30 g
tfater pool
.21 g N/m2
Mud
600 g N/m2
Deep mud
1700 g N/m2
�¥
ANGROVES/
VD
U>
Figure 2.
�Table
2.
Basis for calculation of phosphorus stocks and flow rates.
Numbers in parenthesis relate calculations
to compartments and pathways in Fig. B2.
Explanation
Equation
(1) Rate of incorporation into above-ground biomsss
(10.72 g C/m2'day)(.0009 g P/l g OM)(1 g OM/.5 g C)
This is a function of photosynthesis. Lugo, Sell, and
Snedaker (1973} found that, in the mangroves on the west
coast of Florida, rate of photosynthesis was approximately
10.72 grama Carbon/m "day- The ratio of phosphorus to
carbon taken into the tree is equal to the ratio of
phosphorus to carbon in the total tree biomsss. Golley's
( 9 8 value for phosphorus of 0.09 percent organic matter
16)
was divided by the amount of carbon in organic mat *r
(approximately 50 percent) to determine the ratio of
phosphorus to carbon.
0.0193 g P/m2-day X 365 - 7.05 g P/m2-yr
(2) Export by woodcutters
( 0 7 g C/ni -day)(.05)(.0009 g P/l g OM)(1 g OM/.5 g C)
1.2
Stands of mangroves in Vietnam are generally cutover about
once every twenty years, so the removal rate is approximately 5 percent of the rate of incorporatica through
photosynthesis. The ratio of phosphorus i-o organic
matter in mangrove wood is approximately the same as that
for the overall tree, 0 0 percent. The ratio of carbon
.9
to organic matter is 50 percent.
0 0 1 g P/m2-day X 365 = 0.365 g P/m2-yr
.0
(3) Miscellaneous loss of phosphorus from biomass
(.019 g P/m 2 -day) - (.003 g P/m 2 'day) - (.001 g P/m 2 -day)
incorporation
leaf & wood f a l l
woodcutters
2
2
0.015 g P/m -day X 365 = 5.73 g P/m -yr
In a steady-state system the rate of outflows should roughly
equal the rate of inflows. Phosphorus loss n"jy occur through
transpiration and unknown mechanisms as well as by Itrf and
wood fall and wood removal.
(4) Rate of phosphorus contribution to water pool by leaves,
wood, and miscellaneous material falling from trees
o
Keald (1971) showed that 2.4 g organic matter/m -day fell
from mangroves in a riverine forest in south Florida.
(2.4 g OM/m 2 -day)(.5 g C/l g OMM-0011 g P/g OM)
(1 g OM/.5 g C) • 0.003 g P/m2-day X 365 - 0.95 g P/m -yr
�Table '2. Continued f page 2
Explanation..
Equation
This value multiplied by the amount of carbon per gram
organic matter ( 5 g C/l g OM) gives the amount of carbon
.
eaterieg ;:Ve water pool from this source each day. This
is ssultiplied by the anioun^ of phosphorus per gram carbon
to give grass phosphorus/a -day entering the water pool.
Golley ( 9 8 found that the racio of phosphorus to organic
16)
matter in the leaves of Panamanian tropical forest trees,
including aangroves, was 0.02 percent higher than that in
overall bicmass, so the value of 0.05 percent +0.02 percent
= 0.11 percent phosphorus was used in this calculation.
(5) Rate of phosphorus entry into the Rung Sat water pool
from rainfall
The amount of phosphorus contributed to the water pool of
the Rung Sat by rainfall was estimated from values for
Lake County, Fla., reported by Snedaker and Poole ( 9 2 ,
17)
which was 0-.6 kg/hectare-yr. A.iinfall in the Lake County
area is about SO in/yr, so the value for Lake County was
adjusted to the area of greater rainfall by multiplying
by 1.6 ( 0 5 ) The contribution of phosphorus by rain8/0.
fall is very small compared to that from the sea and
especially compared to that from the river.
(.6 kg P/ha)(1000 g/kg)(l ha/10,000 m ) l . )
('6
2
0.1095 g P/ra -yr
2(400 in)(12 m)(1.08 X 105 m/day)(1/7 X 108 m2)(l g P/m3)
(6) Flow of phosphorus from the Saigon River into the
water pool of the Rung Sat
1.48 g P/m2'day X 365 = 540.20 g P/m -yr
The flow of the Saigon River at a point itamediately below Saigon and above entry into the Rung Sat is 60-90 a/min
(an average value of 75 n/min was used in calculation).
This amounts to 75(60 min/hr)(24 hr/day) • 1.08 X 10 m/day.
This value was doubled because one other river also flows
across the Rung Sat. The width of the Saigon River at
the point measured is approximately 400 m. The depth at
that point is approximately 12 m. By multiplying the
meter flow per day by the depth of the river and the
width of the river, the total araount of river water flowing over the Rung Sat was estimated. The total area of
vo
In
�Table
2. Continued , page 3
Explanation
Equation
the Rung Sat is 700 km «• 7 X 108 zi2. This value divided
into the total amount of river water entering the Rung Sat
provides an average amount of river water flowing across
the average deter square of Rung Sat substrate each day.
The concentration ofphoephorus. in the river is approximately
equal to that of any other large river that receives 5ewage
from a large city. This value is approximately 1 g/m'
(Odum, pers. consa.).
(7) Rate of export of phosphorus as detritus and river runoff
This is a,two-way flow because there is alw».-» some amount
( . 2 g/m "day) of phosphorus entering the swamp from the sea.
00
The flew in the other direction is greater, however, for the
combined action of river flow and tidal flux carries out to
the estuary 13.4 percent of the gross photosynthesis of the
trees (detritus from leaf, wood, and miscellaneous fall) and
all the phosphorus from the river that is not absorbed into
the mud with soil water.
( 0 0 g P/m2-day) + ( . 8 g P/m2-day) + ( 0 3 g P/m2'day)
.03
14
.0
from river
from rain
from detritus
(.0120 g ?/m2-day) - (.0756 g P/u/'day) =
to mud
from nud
1.419 g P/ns 2> day X 365 - 518.04 g P/m 2 -yz
(8) Rate of movement of phosphorus from water pool to asud
Absence of crabholes:
( 0 ia)(l m2) = 0.01 m3 water/m2'day
.1
Calculations based on data from Clarke and Uannon (1967)
indicate that the rate of water penetration into mangrove
soils varies from approximately 1 to 10 centimeters per day,
depending on the number cf crabholes the soil contains. The
slow rate of water movement is due to the almost constantly
water-logged state of the.se soils, which are located almost
entirely in the intertidal zone. The presence of burrows
maintained by Uca and other crabs increases the rate of
water penetration about tenfold.
Crabholes present:
(.1 m)(l m ) = 0.1 m3 water/m2-day
The flow of phosphorus into the water pool from the river
and the sea is approximately 0.75 g/m2*day, assuming an
average depth of 1 meter over the entire Rung Sat and that
river water and sea water are, on the average, mixing in a
1:1 ratio. If this mixture is absorbed into 1 m2 of substrate per day according to the variation shown in the
Without crabholes: ( 0 m3 w/m2)(.75 g P/n3 w-day) - 0.0075
.1
g P/m2-day
first two equations, then the flow of phosphorus into the
With crabholes: (.1 in3 w/m2)(.75 g P/ai3 w-day) = 0.075
P/
�Table ' 2. Continued , page 4
Explanation
substrate varies also. The naxiaum rate appears on the energy
diagram (Fig. B2). A family of curves based on flow rates
ranging fron the minimus to the maximum calculated can be
achieved through analog simulation. The taajftmura rate provides
an access of phosphorus relative to the rate of incorporation
into bioaass through photosynthesis. If Zinke's estimate of
a surface soil concentration of 0.5 g P/m3 is substantiated,
then phosphorus accumulates very little in surface muds,
leaching to deep muds or back to the water pool instead.
Much acre information is needed on the behavior of phosphorus
in mangrove soils.
(9) Phosphorus flow fron surface soils to deep mud
The concentration of phosphorus in deep muds suggested
by Einkc ia very high compared to that of the surface
cuds (see last item in this table). The soils on which the
mangroves were growing msy have accumulated over a bed of
phosphatic sediaent, or leaching of phosphorus into deep
soils may be taking place. The rate of leaching to deep
muds can be approximated for a steady-state system.
(10) Rate of loss of phosphorus from mud to water pool
Loss to the water pool is probably less than the loss to
deep soils. This was assumed to be the case and a rate
value was calculated for a steady-state system.
(11) Rate of uptake of phosphorus from mud by mangrove
roots
Phosphorus uptake from mud by roots, like phosphorus incorporation into above-ground biomass, is a function of the
rate of photosynthesis, which is approximately 10.72 grams C
per m2-day in south Florida (Lugo, Sell, and Snedaker, 1973).
The phosphorus content of mangrove roots is approximately
0.11 percent. The ratio of carbon to organic matter is
about 50 percent.
Equation
.075 g P/m2-day X 365 - 27.59 g P/m2.yr
.08 g P/ia2-day + .0002 g P/m2-day - .0195 g P/m2'day
from water pool
from roots
to roots
- .0120 g P/sa2-day = 0.0443 g P/m2-day X 365 - 4.38 g P/
to water pool
ro
yr
.08 g P/m2.day + .0002 g P/m2-day - .0195 g P/m2'day
from water pool
from roots
to roots
- .0443 g P/m2-day = 0.012 g P/m2-day Z 365 - 0.012 g P/
to deep soil
m2«yr
(10.72 g C/m2-day)(.0011 g P/l g OM) (1 g OM/.5 g C) «=
0.02 g P/m*-day X 365 » 7.12 g P/m2-yr
�Table .2. Continued, page 5
Explanation
(12) Rate of phosphorus ir.ss from roots to said through
root death and decay.
Equation
=15(.0195 g P/m2-day) - 0 0 0 g P/m2-day X 365 - 0.07 § P/
.02
m^-yr
In a mangrove forest in south Florida, Sell (pers. coma.)
found that approximately IS percent of the trees were dead.
With the death of trees, roots gradually decay and release
their store of nutrients back to the soil. B-ecctsposition
procedss very slowly in water-logged mangrove soils, which
are highly anaerobicj however the fact that death is a
continuous process in the mangrove coasaunity means that
&->na decay is always going on. If we assusae that
15 percent of the roots in the soil are in a state of
slow decomposition, then approximately 0.15 tisaes the
rate >f. uptake of phosphorus by roots is bsing released
to the soil. The concentration of phosphorus in the
soil is one half that in the roots, an entirely different
case froa that of nitrogen, where the concentration in
the soil was several hundred times that in the roots.
(13) Pulse of herbicide application, increasing rate
of leaf fall and rate of wood removal by woodcutters
until the supply is depleted
Trees are killed and the above-ground biomass is removed by woodcutters, tidal flux, and decomposition.
(14) Phosphorus present in compartments, according
to estimates by Zinke (pers. coma.)
Leaves and wood
Roors
Mud
Water Pool
2.5 g P/m2
l
g p/m2
0.5 g P/m2
0.03 g P/m2
sC
CD
�99
LITERATURE CITED
Clarke, L.D. and N.J* Kannon. 196?. The mangrove swamp and salt
marsh communities of th® Sydney district. I. Vegetation,
solle and climate. J. Eool. 55: 753-771.
Golley, F.B. 1968. Mineral cycling In tropical forest ecosystems.
of Florida Institute of Ecology. Athens, Georgia.
Goll®y, F.B, 1H.T. Odum, and R.P. Wilson. 1962, The structure
andra@t-a'boliemof a Puerto HI can red mangrove forest in May.
Ecology 43: 9--19.
Hcald, E.J. 1971. The production of organic detritus in a south
Florida estuary. Sea Grant T^ch. Bull. No. 6. University
of Miami S< .. (jrant Program. Miami, Florida.
Lugo, A.E., M.O. 8®11, and S.C. Snodaker. 1973. Mangrove ecosystem
analysis. Fr©»@ntod @t th& Systeras Ecology Conference in March,
1973, at th® Uolveraity of Georgia. Athens, Georgia.
8.C. &nd A.E« Lv^o. 1972. The role of mangrove oystema
In thai mainte*3@3)@o of onvix>on@ental quality and high productivity of desirable fioharled. Progress Report to Bureau of
Sport Fisheries «®& Wildiif®. Center for Aquatic Sciences.
Unlv@raity of Florida. Gainesville.
Snedaker, S.C. and D0 Pool®. 1972. Water management and nutrient
cycling at Wild Kingdom (Lake County, Florida).
�100
5. DIGITAL SIMILATION OF POTENTIAL REFORESTATION PROBLEMS IN THE RUNG SAT
DELTA, VIET NAM
Philip C. Miller, Jatsea R. Ehleringcr, Barry Hynutn, and Wayne Sterner
Department
Center for
California
San Diego,
of Biology
Regional Environmental Problems
State University, San Diego
California 92115
�JU.'.
INTRODUCTION
Between 1962 and 1969 about 5 million acres of forest land and crop
land In Viet Nan were sprayed with herbicides. Agent orange, containing
2, 4-D and 2, 4, 5-1; and agent white, containing 2, 4-D and picloram,
were applied at rates of 11.7 pounds per acre and 5.6 Ibs. per acre res«
pectively in multiple applicatirns
CGolley, 1971; Tschirley, 1969). In
much of the sprayed areas, reestablishmcnt of the original forest has been
negligible.
(Golley, 1 7 ) One such, area, the Rung Sat Delta, south of
91.
Saigon, was chosen to study the possible causes of the lack of colonization. The area is thought to have f»een last sprayed in 1970.
Mangroves
which once covered about 80% of the area have been killed and the remaining dead wood harvested for fuel. Aerial photographs taken in 1971
indicate little or no seedling growth in this area.
Originally the area consisted of a gradient from predominantly red
mangroves (Rhizqphora sp.) on the seaward side to-a mixture of red and
black mangrove (Ayicennia sp.) on the inland side. The seaward side is
indunctated daily with salinities ranging from 25 to 35 parts per thousand, while on the Inland side inundation occurs only during the highest
tides and salvnitles are leas, ranging between 15 and 25 ppt. The Saigon
River borders the area to the west. Mangroves still occur to the north,
interspersed with farmland.
Climatic data for the region are scarce, but some data are available from Tan-Son-Nhut (Saigon). Rainfall Is greatest in September
and lowest in February (Table 1 . Temperatures are warmest in May, but
)
the mean monthly air "temperatures vary less than four degrees annually.
�102
Table 1. Maximum, minimum, and SKtan monthly air temperatures (*C)
a&d mean precipitation (mt) for Saigon, Viet Nam (after
Conway ( 9 3 and Cuong ( 9 4 )
16)
16).
month
Maximum air
temperature
Minimum air Mean air Precipitation
testgerature 1t*2ESES£HES»
January
32
17
24
February
33
18
25
March
36
19
27
6
April
38
20
28
55
May
38
18
21
200
June
35
18
26
205
July
33
18
25
..20
,'0
August
32
18
25
184
2epte@ber
33
17
26
198
October
31
17
26
202
November
31
16
24
64
December
31
15
24
35
6
.
3
�103
Solar radiation remains at about 323-375 langlcys day" most of the year
because of the constant cloudiness. The sunniest months, February, March,
and April are also the driest (Table 2) , with the daily radiation
total increasing to 400-450 laagleys day" .
The reasons why the mangrove vegetation is recovering slowly
or possibly act at all are not yet known. It is however possible to speculate as to what is currently happening. The purpose of this paper is
to bring together existing knowledge of the area in terms of climatological,
geological, and physiological characteristics in order to attempt to understand the processes and interactions influencing redevelopment in the Rung
.
t
Sat area. The method we shall use is digital modeling. Without giving
an extensive review of the history and validity of digital modeling,
digital KKteling as a technique in understanding relationships and
Interactions within & system, whether it be biological, chemical,
or•physical, has demonstrated itself ia the past to be a useful tool. .
A Kodel ia only beneficial if it helps to clarify our understanding
of relationships within a system. A model is most useful if it utilizes
relationships and parameters which can be measured. Also the model should
yield insight into the processes of the system that 1) require further
•
•
investigation and 2) are most crucial to the system. This is the philosophy used in this modeling exercise. The model is based on data
recorded in the literature and from field research on mangroves carried
out ia south Florida on «n A.E.G. contract.
Although the reasons why mangrove vegetation is not recovering or
is recovering very slowly are not clear, several hypotheses that could be
�104
Table 2. Mean monthly values of total solar radiation for Saigon
from.the Dept. of Coamercc ( 9 8 . Units are langleys
16)
day .
Month
Mean Lani»le^3
January
350
February
422
Hatch
456
April
438
May
360
June
391
tfoly
386
August
369
Saptetabcr
356
October
335
Hoveobev
316
December
316
�1U5
tested using digital simulations wera constructed. These hypotheses
arc attempts to delineate the physical and biological processes acting
to constrain the redevelopment of the mangrove forests. The hypotheses
stem from the idea that upon removal of the vegetation, the microclimate
la changed. The new microclimate will then influence all of the vegetation attempting to establish in that area. Four principal hypotheses
vere constructed to be tested by the digital simulations. These were:
1) Surface temperatures lethal to propagules and seedlings may be
produced at certain times of the year.
2) High leaf temperatures may be reached in the exposed seedling
canopies causing a decrease in net. production, and if leaf
• temperatures are high enough, an increase in seedling mortality.
3) The substrate surface dries faster than the mangrove seedlings
can grow roots, and the propagules die of desiccation at certain
times of the year.
4) Low immigration and high mortalities result in slow propagule
establishment and reforestation.
Fredatioh by man and herbivorous animals were not considered,
nor was competition between mangroves and other spec'.js, such as grasses,
because the principal constraint on the mangrove redevelopment was thought
to be due to environmental factors or to physiological responses.
Two modeling approaches were undertaken: a total ecosystem m. del
which simulates the redevelopment of mangroves over a span of several years,
and a detailed physical and physiological response model (CANOPY) of mangrove-environment interactions, which simulates a period of twenty-four hours.
�Description of each model and a dis-.vssion if the data base, simulation
results, t-J conclusions are presented separately in the following section.
�107
DESCR7.PTION OF THE DETAILED PHYSICAL AND PHYSIOLOGICAL
RESPONSE MODEL
I.
CANOPY
CANOPY is a canopy-s»icrocliBiate-"pri8»ary production model which
estimates hourly values of net pjriaary production and transpiration by
strata throughout a canopy. CANOPY calculates tha microclimate of the
strata *md than evaluates the effect of the microclimate on the vegetation. The model will be discussed in two parts: 1} a description of
the processes influencing tha laiercBttstaoralogical profiles and 2) a description, of the processes influencing leaf t«mp«ratura and primary production.
.
To best understand &w CAKOP7 works, «a sill briefly run through on«
cycle of the program (Figurt 1 . TMs description is given hero in order
)
Co give t&a reader an idea of tna proe<asa®8 and interactions involved in tha
nodal. Input data necessary for CMOf? include hourly microclimate values,
canopy leaf area distributions, «ad physiological parameters for the species
•
•
being modeled (Tables 3-5). Hourly calculations ars then mads on the processes within the canopy which ta£luane.« primary production, transpiration,
and energy exchange. Short wave radiation penetration through the canopy
*
t
is calculated as described by Millar (1969, 1972b)« Transpiration, internal
leaf water status, and vatar uptake ratas are then calculated. The pvofilas
of microcllroatic variables are daterained by a. modification of the model
discussedl by Waggoner and Reifenyder ( 9 8 . &eaf temperatures are calcu16)
lated by an iterative solution of tha leaf energy budget, Finally, net photosynthesis is «atimated. Hourly susaarisa are printed, after. wMch the model
•
proceeds to tha next hour with the information needed fro» the previous hour.
A flowchart of CANOPY appaa?8 as Figura la.
�loa
Input Data
Begin hourly calculations:
Calculate by strata throughout the canopy.
1. Short wave, radiation
2. Transpiration stream variables
3. Microcliroatic profiles
4. Leaf temperatures
5. Net photosynthesis
6. Hourly output
Figure 1. General flowchart of the program CANOPY.
~
�Radiation processes
| leaf processes
' other microclimate
processes
£
Fie la Flow charts illustrating the interrelations between canopy variables and physic-j processes. Symbol* are deBned and explained in the text. The upper chart illustrates the interrelations (or one level in the
canopy; too tower chart, for a canopy divided into three kvels. (after Miller, 1972)
109
�110
Table. 3 . Microclimate input data for CANOPY. All values are for
a point just above the top of the canopy. Units for
radiation are cal era" 2rain""*,for air temperature degrees ,
Celsius,for vapor density g- m , and wind velocity cm sec .
Febry srv
Hour
Total
solar
Diffuse
solar .
Infrared
from sky
Wind
Air
Air
temperature vapor den. velocity
1
0
0
0.60
23.0
19.0
60.
2
0
0
0.60
12.0
19.0
60.
3
0
0
06
.0
21.0
19.0
6.
0
4
0
0
06
.0
2.
00
1. .
90
6.
0
5
0
0
0.60
19.0
18.5
60.
6
0.
..
0
0.60
20.0
19.0
80.
7
0.10
0.10
0.60
21.0
19.5
100.
• 8
0.50
0.10
0.60"
24.0
20.0
125.
9
10
.0
0.20
0.60
27.0
20.0
150.
10
1.15
0.25
0.60
29.0
20.0
175.
u
12
.0
03
.0
06
.0
3.
10
2.
00
200.
12
1.30
0.30
0.60
32.0
20.5
225.
13
12
.0
0.30
06
.0
31.5
21.0
250.
14
1.15
0.30
0.60
30.5
20.5
* 200.
w
1.00
0.25
0.60
30.0
20.0
16
0.80
0.25
0.60
30.0
20.0
150.
17
0.50
0.20
0.60
29.5
20.0
150.
18
0.10
0.10
0.60
29.0
1.
95
80.
19
0
0
0.60
23.5
19.5
80.
20
0
0
06
.0
2.
80
19.5
6.
0
21
0
o
0.60
. • 27.0
19.0
60.
22
23
24
0
0
0
0
0
0
06
.0
0.60
0.60
2.
60
25.0
24.0
1.
90
19.0
19.0
6.
0
60.
60.
t
•
175.
�111
Table 3. (continued).
February average
Total
solar
Hour
Diffuse
solar
Air
Air
Wind
temperature vapor density velocity
Infrared
from sky
1
0
0
0.60
22.0
19.0
6.
0
2
0
0
0.60
22.0
1.0
9*
60.
3
0
0
0.60
22.0
19.0
60.
4
0
0
0.60
22.0
19.0
60.
5
0
0
06
.0
23.0
19.0
60.
6
0
0
06
,0
24.0
19.0
8.
0
7
0.10
0.05
0.60
25.0
19.0
100
8
0.40
0.20
0.60
26.0
19.0
125.
9
0.70
0.30
0.60
27.0
19.0
150.
10
0*80
0.30
0.60
27.0
19.0
175.
11
0.90
0.40
0.60
27.0
19.0
200.
'l2
1.10
0.50
0.60
28.0
19.0
225.
0.60
0.60
28.0
19.C
250.
*
13 *
;
0.90
•
0.80
0.60
0.60
28.0
:.9.o
225.
07
.0
0.50
0.60
27.0
19.0
200.
16
0.60
0.40
0.60
27.0
19.0
150.
17
0.40
0.30
0.60
27.0
19.0
150.
18
0.10
0.10
06
.0
26.0
19.0
100.
19
0
0
0.60
26.0
19.0
80.
20
0
0
0.60
25.0
19.0
60.
21
0
0
0.60
24.0
19.0
6.
0
22
0
0
0.60
. 23.0
19.0
60.
23
0
0
0.60
22.0
19.0
60.
24
0
0
0.60
22.0
19.0
60.
14
' 15
*
.
�Table 3.
(continued).
Hay^minny
Bour
Total
, aolar
Diffuse
solar
Infrared
from sky
Air
Air
Wind
temperature vapor den. velocity
1
0
0
0.60
25.5
24.0
60.
2
0
0
0.60
25.0
24.0
60.
3
0
0
0.60
24.5
24:0
60.
4
0
0
0.60
24.0
24.0
60. '•
5
0
0
0.60
24.0
24.0
60.
6
00
.5
0.05
0.60
25.0
24.0
8.
0
7. .
0.35
0.10
0.60
28.0
24.0
100.
8
0.70
0.20
0.60
31.0
24.0
125.
9
1.10
0.50
0.60
33.0
24.0
150.
10
1.15
0.60
0.60
35.0
24.5
175.
11
1.00
0.60
35.0
24.5
200.
12
09
.0
0.70
06
.0
35.0
24.5
225.
. 13
08
.0
08
.0
06
.0
33.0
24.5
250.
14 ,
0.70
0.70
0.60
32.0
25.0
225.
u
0.65
0.65
0.60
31.0
25.0
200.
16
0.60
0.60
0.60
30.0
24.5
150.
17
0.50
0.50
0.60
29.5
24.4
150.
18
0.40
0.40
0.60
29.0
24.5
100.
19
01
.0
0.10
0.60
28.5
24.5
80.
20
0
0
0.60
28.0
24.0
60.
21
0
0
0.60
27.5
24.0
60.
.0 7 .
.0
.
V
22
0
0
0.60
27.0
24.0
60.
23
0
0
0.60
26.5
24.0
60.
24
0
0
0.60
26.0
24.0
60.
�Table 3. (continued).
Eour
Total
eol&r
Infrared
from sky
Diffuse
solar
Air
Wind
Air
temperature vapor den. velocity
0.60
26.0
24.0
60.
0
06
.0
26.0
24*. 0
60.
0
0
0.60
26.0
24.0
60.^
' '4
.
0
0
06
.0
26.0
24.0
60.
5
0
0
06
.0
26.0
2.
40
60.
6 •
0
0
06
.0
2.
60
2.
40
8.
0
7
02
.0
01
.0
06
.0
2.
60
2.
40
10
0.
8
05
.0
03
.0
06
.0
28.0
24.0
125:
9
07
.0
C.40
06
.0
2.
90
24.0
ISO.
w
0.80
0.40
06
.0
3.
00
24.0
175.
11
07
.0
06
.0
06
.0
30.0
2.
40
200.
12
0.70
0.70
06
.0
30.0
24.0
225.
13
0.60
0.60
06
.0
3.
00
2.
40
250.
14.
06
.0
0.60
06
.0
3.
00
. 24.0
225.
15
0.50
0.50
06
.0
30.0
24.0
200.
16
04
.0
04
.0
06
.0
3.
00
2.
40
175. -
17
0.25
0.25
06 '
.0
3.
00
2.
40
10
5.
13
01
.5
01
.5
06
.0
2.
90
2.
40
10
0.
., IS
O.oO
01
.0
06
.0
2.
80
2.
40
80.
20
0
0
06
.0
27.0
2.
40
60.
21
0
0
0.60
27.0
24.0
60.
22
0
0
0.60
27.0
'40
2.
60.
23
24
0
0
0
0
06
.0
0.60
27.0
26.0
24.0
24.0
60.
60.
1
0
3
.
0
2
'
0
.
.
�Table 4. Stand structure used in the CANOPli simulations. The
total LAJ is approximately 0.45. Strata 1 is at Che
top of the canopy. The actual data is hypothetical,
but canopies of similar structure are found in mangrove swamps.
Strata
Leaf Area Index
Leaf angle 1°)
1
.0
02
60.
2
.050
54.
3
.075
48.
'4
.100
42.
5
.100
36.
6
.075
30.
7
.050
24.
8
.003
18.
�Table 5. Physiological incut parameters to CANOPY and values used in
the simulations. All data are for Rhizophpra mangle.
Variable
Symbol
minimum leaf resistance
r .,
rate
cuticular leaf resistance r
cut
photosynthesis light
parameter ap
Value
Data Source
0.04 rain cm
Miller and Ehleringer(1972
0.50 sain cm*
Miller and Ehleringer(1972;
-1
2.5 CEJ2 ly(gCO~)
Miller ( 9 2
17)
0.03
Miller ( 9 2
17)
0.60.
Miller ( 9 2
17)
0.30 oia cm
Moore,et al. ( 9 2
17)
Killer and Ehleringer(1972;
Miller and Ehleriuger(1972;
photosynthesis light
parameter bp
•beorptance
'•
neeopbyll resistance
root resistance
r
etomatal light parameter
D
0.2ffiiraa a b a r "
_^
14.
leaf resistance parameter
X
16.
Miller and Ehleringer (1971
saturation leaf density
DT
50 rag csf
Miller ( 9 2
17)
10 °C
Noore.et al. ( 9 2
17)
37'*C.
Moore,et al. ( 9 2
17)
27 -C
Moore,et al. (1972)
10 *C
409C
30 *C
Hypothesized
Hypothesized
Hypothesized
Photosynthesis System 1
leaf temperature w/ 0 0 net
.
photosynthesis
X,
f
leaf temperature v/ 0.0 net
photosynthesis
I«
.optimum leaf temperature
T
op
for photosynthesis
Photosynthesis System 2
T,
�116
CANOPY Incorporates several digital models which have been or are being
described in the literature. These ares
1) a model to describe solar
radiation penetration into the canopy from Miller ( 9 9 1972b); 2) a
16,
model to estimate net primary production, leaf temperatures, and physical
processes within a canopy from Miller (1972a) and Miller and Tieszen ( 9 2 ,
17)
*
3) a model to describe water relations within plants from Killer and
Ehlfcringer ( 9 2 , 4) & model to calculate microclimatic profiles from
17)
Waggoner and Reifsnyder ( 9 8 , and 5) & model to calculate soil tempera16)
tures, soil water content, and the-, movement of heat and water in saturated
and nonaaturated soils from Ng sad Killer ( 9 2 . No attempt will be made
17)
•
here to give a complete description of the models as more complete discussions
can be found in each respective paper.
CANOPY is an updating of these models, incorporating equations which
express a more detailed mechanistic understanding of processes effecting
I r." '. • " •
primary production than were discussed J.n the*Miller ( 9 2 ) primary production
17a
Eodel. These additional equations will be discussed later. CANOPY is further
modified to simulate processes affecting primary production and revcgetatlon
of mangroves in the Rung Sat Delta, Viet Ham.
;*••••
.
- •, "
Specific features of CANOPY for the Rung Sat simulations include the
hypothesized effects of herbicides on photosynthesis and the effect of salt
water on the soil water potential and on transpiration.
*
:.'.
..:
.......
*
II. MXCROMETEOROL0GICAL PROFILES
Micrometeorological profiles are calculated by four submodels: WAR,
RABMOD, SOILT, and INFRA. WAR is the submodel to calculate air temperature and vapor density profiles, modified from Waggoner and Keifsynder ( 9 8 .
16)
RAJDMOD is the Miller (1972b) submodel for calculating short wave radiation
f
�117
profiles within the canopy. The submodel for the calculation of values
for soil variables is SOIL! and is adapted from Ng and Miller ( 9 2 .
17)
INFRA IB a submodel which calculates infrared radiation profiles.
As microclimatic input data to CANOPY, we need 24 hour values of
total short wave radiation, diffuse short wave radiation, Infrared radiation
from the sky, air temperature, and the vapor density for a point Just above
the canopy. Given also the leaf area, leaf angle distribution, and the
declination of the sun for the 24 hour period, the microclimatic profiles
for air temperature, vapor density, and short and long wave radiation.
Utilizing the canopy leaf area distributions, RADHDD calculates profiles of
direct, diffuse, and reflected radiation.
The WAR submodel uses as input ths solar radiation profiles, air temperature and vapor density above tha canopy, the soil surface tenperature, the
vapor density just above the soil surface, find the profile of diffusive leaf
resistances. The values for the profile of leaf resistances come from the
transpiration stream calculations portion of CANOPY. Soil temperature and
vapor density just above the soil surface are calculated by SOIL'S. SOIL!
calculates the surface temperature, sail water content (volume/volume), soil
suction, and soil water potentials (bar&) to a depth where daily fluctuations
no longer occur.
The WAR submodel then proceeds to iteratively solve for the air temperature and vapor density profiles while leaf temperatures are being calculated. An Intermediate infrared radiation submodel INFRA supplies calculated values of infrared radiation from leaves, ground, and sky to the
I'eaf and air temperature calculations.
�118
III.
LEAF TEMPERATURES
Leaf temperature calculations are based on the heat transfer equation
for a single leaf (Gates, 1962; Killer, 1967) which states that in an
equilibrium state the energy absorbed by a leaf equals the energy lost.
Moreover the absorbed energy from solar aad infrared radiation and con*
vection is lost, by reradiation, ceavectlosi, and transpiration.
Thus
•S + cIR » XRA i C + LB
(J.)
where: a is the leaf absorptance to solar radiation; S is the solar radiation incident on tits leaf; e is thy. absorption of the leaf to infrared radiation; IE is the, infrared radiation from the. environment incident
on th@ leaf; IK. is t'fee infrared retaliation by the leaf; C ia the convsctional energy exchange; L is the latent beat of evaporation; and, E
is thfii evaporation rate.
--
• • • . - • ••;••'•
Each process by which energy is loat frost the leaf depends on the
leaf t em-para tura. '£hus if tlt& leaf temperature is T, ia *C,
c - h.or. - i )
.
• • - , • •
C3)
' • ' • • •
where: o is the Stefan Boltzmann coa&tant; h is the convection coefficient; ps.T^ is the saturation vapor density at leaf tempeature; pa is
_
.
th« vapor density of the air; r. is the leaf resistance to water loss;
and, r is the laminar boundary layer resistance. Once the absorbed radiation is kr.oan, leaf temperature end transpiration can be calculated by
solving the above equations simultaneously by Iteration.
�119
"T 'IV. PRIMARY PRODOCTiOif CALCULATIONS
The net photosyathetic rate is a good Index of the rate of primary
production. This being the case, we focus our model of primary production
on determining the rates of net photosynthesis at thr. iifferent strata
within a canopy. The physiological leaf parameters determining the rate
of pliotosyuthesis become quite important. If a model Is to accurately simulate photosynthesis, it must also accurately simulate those parameters
which indirectly determine the rate of photosynthesis.
Net photosynthesis is related to the absorbed solar radiation, atmospheric carbon dioxide content, leaf resistance, boundary layer resistance,
and meeophyll resistance by tha equations:
p *.
•__££&.
foodified
PH - (aS) (a as + b )"1
P
a
a f te r
Gaaatra, 1963)
(5)
Ofontcith, 1965)
P
(6)
where: PM is the unadjusted net photosynthetic rate; [COg] and
Ate the carbon dioxide concentrations in the air and at the chloroplaeto; r
la the mesophyll resistance to carbon dioxide transport; and, a and b are
parameters empirically derived from the photosynthesis light response curve.
the leaf resistance to water transfer is modifl
*
'
for carbon dloxiue diffusion
.
.
'
•
"
..
by multiplying by the ratio of the diffusion coefficients of carbon dioxide
and water.
.....
'
" • • • • • _ --:
- .:~:.: ...--.
Leaf temperature and herbicide influence net photosynthesis through the
equations*
•
•
P
KT* C
�120
P
NTH * <P
;
' -
;
H - bhc"kt
(9)
where: PN_ is the net photosynthetic rate after the effect of temperature
is included; Xe is the leaf t.emf erature at which net phototsynthesis equals
zero; T
is the optimum leaf temperature for photosynthesis. There are
two values for T , one on either side of T9£>C. The one used depends on which
.
..
side of the optimum leaf temperature the leaf temperature falls.
P
NTH *8 thc net P^°Co9yat^eti<: rste after the effects of the
herbicide have been included; H la the relative effect of the herbicide on
photosynthesis; b relates the herbicide concentration to its effect on the
photoeynthetlc process; h is the initial herbicide concentration; k is
the decay coefficient for the herbicide; and t is the elapsed time since
the herbicide application.
• •1 "
.
•
'
- -
Net photosynthesis is first calculated by equations (5) and ( )
6,
and the smaller of the two values is taken as the actual valua. This
allows photosynthesis to be limited by both light and by carbon dioxide
diffusion. The calculated value of net photosynthesis is then corrected
for the effects of leaf temperature and herbicides. Temperature and
herbicide effects arc assumed to be linear. Linear Interpolation for
the temperature effects on photosynthesis yields a fair approximation to the
temperature response data of Moore et al. ( 9 2 .
17)
.....,,>...
* ' ' Net photos" .thesis for the canopy is calculated as
: .: • •.:•.:
'. -: a.. - . - . . . .
....
,PT - £
"
1 K - - Li )
( NTH. X A .
..
I
,;
.
^;
'
(0
1)
�121
where: P , is the total net photosynthesis; jf^ya *» the net photosynthetic
.
rate at: the i-th level; LAI. is the leaf area index at the i-th level; and,
a is the number of levels in the canopy.
V. TRANSPIRATION STREAM CALCULATIONS
t
Water movement out of the leaves is related to the vapor density gradient and to thi reiiistfinc.es to water diffusion by the equation as previously described in equation ( )
A.
._
Internal loaf water status is dependent on tha leaf water deficit.
Thie in the relative saturation deficit (Barrs, 1968) frosa the fully
turgid state. It is expressed as a percentage and is related to the
transpiration and water uptake rates as
.
(11)
vheret' VD' and HI* - are the leaf water deficits at tine t and titae t-1;
DT' is the saturation leaf density, and W
is tha water uptake rata. The
»aturation leaf density is defined as tha fully turgid leaf weight per square
centimeter.
.
:
'
•.
'••-.
Th« leaf water potential is calculated as a second order regression
from the data of'Miller and'Ehleringer ( 9 2 . The regression is
17)
::
:
'
*A - -0.78 - 0.46WO - 0.032MD2
'
(12)
where ty. is'the leaf water potential.
The water uptake rate is calculated using the Ohm's Law analogy, where
the potential driving force is the water potential gradient between the leaf
and the soil. Resistance to water uptake is offered by the roots and the
�122
soil. The uptake rate .Is also moderated by the relative surface areas of the
roots and leaves. Thus,
W
u? ' a<*8 - *i>/<«r + V
(3
1)
where: a is the ratio of root to shoot surface areas; * is the soil water
potential; and, rf and r are the resistances to water transfer of the roots
•nd soil respectively. These resistances are assumed to be constant.
Soil water potential is related to the seswater and is herein assumed to
contain only sodium chloride, so the equation for soil water potential simplifies to.
•'.•
'
'
•'''••'•
-- ' • '.••'-•""' " '• •" ' • •"'•••"•
where: 0 is a conversion factor relating maim sail suction (S ) to water
potential; y is a conversion factor relating aolerity of sodium chloride
to water potential; and S__ is the salinity of the scawater.
oc<
leaf resistance to water loaa is related to the solar radiation ab• •
•orbed by the leaf and the internal water status by the equation,
(froa Miller and Ehleringer, 1972)
where: r
fc
ia the cuticular resistance, the resistance with the stomata
completely cloned; g and m are constants related to the water deficit at
which the minimum resistance occurs; x is an exponent related to the steep.
•
ness of the leaf resistance-water deficit curve at high water deficits; and,
D is a parameter related to the stoaatal opening with light.
Transpiration stream calculations eomsxmce with the calculation of the
�123
the-leaf water deficit, based on the transpiration rate and water uptake
rate of the previous period. Calculation of the leaf water potential
follows, afterwhich the leaf resistance can then be calculated. The soil
water potential and uptake rates are calculated after the leaf resistance.
Transpiration is solved for iteratively as the leaf temperature IB being
calculated.
Total water loss by the canopy is calculated in a manner
identical to the calculation of net photosynthesis in equation ( 0 .
1)
VI.
CLIMTIC INPUT DATA
The CANOPY simulations used climate data for tha months of February
end May as input date. These two months w«e chosen as they represent extreiasa in climate conditions. February is the driest and one of the sunniest
months of the year, whereas May Is one of the warmest and cloudiest months
(Tables 1, 2).
If the environment is too harsh for mangrove seedling survival, then
through the simulation of the prisary production processes on these extreme
tsoaths insight into tha potential reforestation problems may be gained. Our
interest is in tasting conditions which eight be straining tha system, not
conditions underwhich tha system will swimily survive. Accordingly, four
input days were used to CANOPY simulations). These were an average February
day ( 5 ly), an extrema sunny February day ( 0 ly), the average May day
40
60
( 5 ly), and a sunny May day ( 0 ly) in which the maximum monthly temperature
30
50
was reached.
' "
•'•• '•' ••• •': '" ;•
''. /•
• . '<-.•
J: -'•'
»
Th« probabilities oS having the sunny February day or having the sunny
Nay day are not known, because we do not have daily temperature records for the
�124
area. By comparison though with climates of other areas we put forth the
possibility that the chances of having these extreme days could be between
0.25 and
0.10.
RESULTS AND DISCUSSION
Canopy Simulation
A series of simulations were run using the four climate days*previously
described. Additionally, two different photosynthesis temperature response
curves (Table 2) and three different substrate salinities were simulated.
Two different photosynthesis temperature response curves were used as the temperature adaptations of the Viet Nam mangroves were not known. The temperature
response curve for the lower optima temperature has been measured on
5M8joj>hora mangle, in south Florida (Moore et al., 1972; Moore, unpublished data).
The temperature response curve with the higher optimum temperature was used as it may
be « wore reasonable adaptation by swuagroves to the warmer and swre stable
climate of Viet Nam. These results provide a complete matrix for comparative purposed to different locations along the salinity gradient of the Rung
S*t Delta area.
.-,,
_ .. ;i ./ .
r..
_ ...... . . . . ; • ' . . . . . .
The soil characteristics and properties used in the simulations wera
that of a clay soil. Zinke ( 9 2 after visiting the Rung Sat area describes
17)
the soil as being a silty, clay soil. There is a small difference in the two
11
soils, but because the physical properties relating to the clay soil were the
only ones available at the time of the simulations, they were the ones used.
In .the current simulations, it was also assumed that the soil surface was
saturated, but not inundated. lu essence, this is saying that the soil water
potential is equal to th« solute water potential of the incoming tide.
That leaf, area index for these simulations was 0.45 which roughly correa-
�125
ponds to a seedling density of 40 individuals per square meter. This assumes
that each seedling has four leaves, and that each leaf is approximately 30
cm2 In area (Table 4). This leaf area ia used only for purposes of convenience
in the simulations. In actuality, the appropriate leaf area would be less
than 0 4 . The main idea to renumber is that in small sparse canopies, such
.5
aa propagule canopies, the principle interactions are between the climate
and the leaf, not between leaves. The use of a canopy with a leaf area index of 0 4 is small enough that interactions between leaves are still small.
.5
^
The effect of herbicides in these simulations is assumed to be zero.
This was done partly for simplification of the model, but mostly because residual concentrations, if any, and decomposition rates were not known.
The first simulation results are estiiaates of productivity, transpiration,
and the internal physiological response to the four microclimate days. Comparing the February sunny day with the average February day (Figures 2-5),
it appears that net photosynthesis on average days is three times higher than
on sunny days
( . 3 g O.M<,sT?-day~l vs. 0 7 6 g O.K. m~2day°1 at a sali022
.0
nity of 1 % ) From Figura 5 it can be seen that the reason for this drop
2..
in production ia that the leaf temperatures on the sunny day are much higb r.
Transpiration is much higher on the sunny day as expected, but transpiration
does not drop off as steeply when the salinity ia increased on the sunny day
as it does on the shady day. This suggests that on sunny days the role of
solar radiation intensity ia more important than that of substrate salinity.
•
Mangroves on the sunny February day are under more water stress (Figure 4)
and this in part is reflected in the higher leaf temperatures. Net photosynthesis appears to be almost constant with increasing salinity on both
�126
Legend to Figures 2,3,4,5
O
average February day
•
sunny February day
4
average Hay day
A
asiimy May day
L
literature photosynthesis temperature response curve
H
hypothetical photosynthesis temperature response curve
�Figure 2
40O-?
Daily
transpiration totals for
the microclimate days as a function of salinity
average February day
sunny February day
average Kay day
sunny May day
>>
o 300=|
•o
N
E
v.
Z
O
t-
CL
-O
200-1
100
s
16
SALINITY, ppt
24
32
ro
-j
�1. 2 T
e
•
A
A.
L
H
N
c
Figure 3 Daily production for the microclimate
days as a function of salinity
average February day
sunny February day
average May day
sunny May day
literature photo, tempu curve
hypothetical photo, tanp. .curve
0.8QL
o
P
r>
o
a.
er 0.4-
c:
c.
0.0
8
8
r
16
SALINITY, ppt
i
24
32
to
CO
�Figure 4 Minimum leaf water potential for the
aicrocliaate days as a function of salinity
o average February day
* sunnv Fsbriiary dav
* averaze Mav dav
* sunnv Mav dav
<0
k
.
O
Z
w
O
u
I
u.
-25-
z
s
-35
8
T
16
SALINITY, ppt
24
32
�42
o average February day
* sunny February day
A average May day
* sunny May day
5 Maximum leaf temperature for the
microclimate days as a function of salinity
UJ
E
1 38
UJ
a.
£
us
iu.
<
Its
§34
30
8
SALINITY, ppt
�131
February days. There is,however, a alight peak In production at a salinity
of twenty parts per thousand.
A comparison of the sunny May day and the average May day shows
similar trends. The discrepancy ia production has increased so that on
the average day the nee production is five times greater than on the sunny
day ( . 9 g O.M. sf2 day"1 vs. 0.542 g O.M. m~2 day"1 at a salinity of 1 %)
008
20.
The difference is decreased when the hypothetical photosynthesis temperature
renpoasa curve is used. By oiaply shifting the photosynthesis temperature
response curve to the right three degress C, we have lowered Che difference
down to « factor of two ( . 7 g O.M. m day
069
«t 12 £«). 0.5 g O.M. m
vs, 1 0 5 g O.M. of ' day"
.6
day" is gai'isd by shifting the response curve
because leaf temperatures are to the right of the optimum temperature and
in « zoo® when production is sensitive to leaf temperature. Transpiration
on ths etatay Hay day compares well with transpiration of the sunny February day
(Figure 2 . However, transpiration on the average Hay day is ouch lower
)
than' say of the other days because the leaf temperatures were not abnormally
high and the air vapor density was high, maning that the vapor density gradient between leaf and air was low. Minimum leaf water potentials exhibit
•lailar trends (Figure 4). The highest minimum leaf water potential and the
lowest: transpiration were on the average May day. This is because the vapor
density gradient is lowest then.
•
'
• Water stress can exist during either month. It can occur in February,
becausa of the higher radiation loads and the diier air. It can occur
in May because of the potential for high leaf temperatures.
Tha possibility of high leaf temperatures is interesting for several
reasons. First, high leaf temperatures place a stress on tha physiological
�132
processes of photosynthesis and transpiration. Secondly, high leaf temperatures pose a threat when temperatures approach or exceed the lethal limit of
the plant. Just exactly what the lethal limit is we do not know. One would
suspect that the lethal temperature is close to the maximum temperature of
positive net photosynthesis.
Once this temperdture is passed the respiration
*
rate IB very high and the breakdown of enzyme systems is occurring. Miller
( 9 2 ) has limited data showing that seedling mortality in Rhizophora mangl£ from
17c
south Florida starts when the temperature exceeds 36°C.
If high temperatures are not teaediately lethal, then there still exists
the possibility that some physiological functions in the developing propagule
stay have beau impaired and that death may occur in later development. The
iwaefiiate effects though of high leaf temperatures other than death are water
stress through excessive transpiration and a decrease in the net photosynthefcic rate. Following the daily course of leef resistance, leaf water potential, leaf temperature, and the photcsyjithatic rate for each of the four days
*•
•
•
•
•
-..".,
•
wili permit us to observe how close to i stress condition the leaf is. Figures 6-9 show these physiological responses for the four climate days at
• substrate salinity of thirty parts per thousand. The photosynthesis-'tenf
.,,.•••
• . . •perature response curve used is the one measured by Moore, et al. (1972)
*O3: S?i^SE&2JJ. .SH.S* Across each graph a dashed line for a leaf tem'3SI.
perature equal to thirty-six degrees is drawn. This corresponds to the
potential lethal leaf temperature. •
Potential lethal temperatures are reached for four hours on the May sunny
eliasata and for one hour in the. February sunny climate. No lethal temperatures
�133"
Legend to Figures 6,7,8,9
A
^»
+
P
net photosynthesis
mg C02 dm" hr~
A
T
leaf temperature
*C
B
W
leaf water potential
bar's
o
R
leaf resistance
tain cm*"
�Fienire 6 The daily course of physiological functions for the February average day
*• P net photosynthesis, n.g. CO, per dn-X per hr
A T leaf temperature, c
W leaf water potential, bars
o R leaf resistance- min per cm
-2,
�Figure 7 The daily course of physiolog ical functions for the February
P net photosynthesis, mg «°2 per dm2 per hr
R *
j*
«
T lesf tett^erature, C
W leaf water potenctai.bars
K ieat resistance, min per cm.
�rigure a Tne aaiiy course or physiological functions tor the May average day
R
^
*
net
Photosynthesis,mg C02 per da* per hr
T
leaf temperature. C
W
R
leaf water ootential. bars
leaf resistance, min per cm.
�Figure 9 The daily course of physiological functions for the May sunny dav
P
net photosynthesiss mg C02 per dm
per hr
�138
appear to be reached on tha average climate days. Excessive water stress
reflected in stomatal closure hardly occurs on tha May sunny day.
Tha input parameters used may be underestimated here, and in reality, water
•tress may be core prevelant than the model would predict.
The model predicts about a 7-10 bar gradient between soil and leaf
water potentials. As this soil continues to dry this gradient will increase,
*
placing the propagule under additional water stress. The frequency of inundation will then play an important role in the mangrove propagule water
relations. Ats the soil is a clay, infiltration will be alow and the soil
will achieve • low water potential at volumetric contents as high as 20%.
Soil Moisture
These points suggest that perhaps tha soil may be limiting the revegetatioa rate. It my ba possible that the soil is drying out so fast that
propsgules are elthar unabla to establish themselves or that the soil moisture evaporates before the propagults can utilize it, because of the radiation load on the soil surface. Simulations) vure performed to follow
••
t&e'vater content change for the opan soil surface for each of the four
day*. These siaul&tions were done using three initial soil water contents
I
'
' "
(volume H20/volume soil). These were 33%, 20%, and 15%. These correspond
to -4, -9, and -16 bara soil water potential respectively. The water content
After it twenty-four hour period is noted and a percentage change is calculated
(Table 6).
:
- -
•
•<
:• '
<-•
• •••.-••
-.•-;
The results indicate that the vatas content drops off quickly frost
the saturated state. By the time the water content reaches 20%, the rate
of water loss has becoaa small. At e water content of 15%, water loss
during « twenty-four hour period is neglible.
This water content has
a water potential of -16 bars. Additionally, we must add to this the
�139
Table 6. Estimates of the rate at which the soil surface is
drying out under open sky condition* and at different
....water contents for th© three test days. Water content
ie in volume/volume.
Climate two
typs
Initial water content
afc the begjLnning of the day
February sunny
-,. .,...( ... • ., .-. . . ..
Kay awrage
0.300
..'•;.
• M&y euRUj
,„ ,, .j:i ... _,.
. ; . . • •:
0.200
., .
February average
:
* ''"' • ' • • ' :
• "
. ' • < • ..
' " '' '•"•"""'"
• •', Q 1 O
. S
0*300
020
.0
010
.5
0.200
010
.5
s; ox
0.274
018
.9
010
15.
0.5%
00
.%
"
024
.7
<.. .
v
8.7%
0.7%
0.0%
010
.5
.> ,.-
030
.0
•
percent chang
in one day
0.276
0,199
010
.5
030
.0
020
.3
010
.5
"• " "' ''•' ~ • ";; "•
..-.- ...
water content
24 hours
after
'
8.7%
0.7%
0.0%
0.277
• 019
.9
010
.5
7.9%
O.J%
00
.%
• . '9 •
° 18
•• -:
�140
•oiute water potential of the salt from sea water. This total would put
tbe plant under in high water stress condition. By adding the solute
water potential, tha plant may become under stress at water contents between 302 end 20%. Tha tine to go from saturation down to a water content of 20% has not been calculated as it is also dependent on the
drainage, patterns.
•
• . Soil Temperature
. . . .
*
The temperature at the eoil surface is also of interest. Zt will
be hotter in the dey than if there was & canopy there, and colder at night.
Just how ouch hotter during the day esy be important. Simulations of the
ground surface temperatures for b«a soil and for an immature canopy of LAI
1.5 were mad© for the four climate: days. The itmature canopy IB to serve
cs a contrast to the bare soil. The bare soil temperature is indicative
of the temperature of a propagul® lying flat on tha surface of the soil.
IE ia assumed that the prop&gule wald be at or at least very close to
the temperature of the bare soil. The bare soil in tha simulations is
•fltsuaed to be saturated, but with no standing water.
Figures 10-13 show that the surface temperatures can vary by only as
such as threa degrees between bara and covered soil. The chances of the
soil approaching « lethal temperature appear to be quite small. The highest
teaperature reached is 38.2 *C (1100, Hay sunny), but temperatures are usually
closer to 30"C. Bare soil surface temperatures appear not to be a deterrent
to propagula invasion and establishment.
Bedevelopment appears to be influenced by the rate of desiccation of
tha soil. Channelization and a i&odification of the soil through exposure
nay be amplifying this effect. Potential lethal temperatures and water
�40-1
Figure 10 The daily course of ground surface temperatures on the February average day
o no canoov
• canopv of LAI - 1.5 above
o
o
uJ
E
f
JE? 30
to
a.
o
o:
CO
20H
i
4
8
22
HOUR
i
16
l
20
i
24
�40-i
Ftgure 11 The daily course of ground surface temoeratures on the February sunny day
o no- canopy
« canopy of LAI >1.5 above
0
HOUR
�40 -i
Figure 12 T>,e daUv course of eround surface temperatures on the Mav averaee dav
O
no csnoov
• canopy of LAI -1.5 above
u
e
iy
f»
i
a:
•ui
••a.'
ca
20 H
•
0
1
4
i
8
i
12
HOUR
I
IS
1
20
1
24
�401
Figure 13 The daily course of ground surface temperatures on the May sunny day
o no canopy
• canopy of IAI • 1«5 above
u
30
a,
^
l£j
J-
lil
u
<
u.
^
s
CO
20
I
4
i
8
12
HOUR
20
24
�145
stress conditions in leaves may exist for several hours on a number of days
of the month in February and in Hay. It ia also possible that these same
•tress conditions may be reached in other months of the year, although possibly
to ft lesser extent.
,
The lack of physiological data frou Viet Nam detracts from the reliability of the model predictions. Actual estimates of parameters are expected to b& different from those used in the simulations, but by the use of
parameters from members of the sasaa genus, it is thought that the values used
will be close to the actual ones.
'
The critical variable influencing the system appears to be the microclimate. The success of reestablishmjat hinges on the stress placed on the
propagule by the radiation load, the leaf-air vapor density gradient, and
the rate of aoil desiccation.
-
•
./?.: ;..:' --•: <•, ....'-'i.rj... :." -.. -'rf •
- ,.' • !-.
.
,
-
' , •'• "
f '
, •-
, • t ,
-::.-y•',-!•;,.7 .;..-,•* •-•'• ••>••)
�146
The long terra simulation of red mangroves.
Currently in Viet Nasa tsucli of what used to be mangrove forests is now
barren as a result of defoliation. Furthermore, reforestation appears to
be impaired in some way. The following mathematical simulation is being
used to determine possible long term causes. The two hypotheses being tested
• o (1) the slow immigration of propagules retards reforestation and (2)
r:
the growth of propagules and seedlings is arrested as e result of increased
temperature and salinity resulting fsrca the initial defoliation. The red
Mangrove forest, Rhjlzophora, manglo, L.»•of the Rung Sat Delta was being
aodeled. figure 14 is a simplified flow chart of the model. The description
of the model will follow the order of the state variables in the figure as
numbered with ttxe description of the driving variable preceding.
Modal Description
It Macrocliraata
Tfaa driving variables in the model are solar radiation, temperature,
precipitation and salinity. Mean monthly data were used to approximate
«®an daily values by means of a linear interpolation between two adjacent .
»
Ecnthly means. A standard year 4& used throughout the simulation (see
Table 7.. Mean monthly temperature and total monthly precipitation, were
.)
taken from Van Cucng ( 9 4 . Mean monthly total solar radiation was taken
16)
from summaries (Dept. of Commerce 1968) from the Saigon area. Hean monthly
ambient salinities from a Florida brackish water mangrove swamp were used
�147
Propogules 2
PLEAF»OP,
a
ecomposition
PROCTf = OPr
Nutrients 5
ft
Herbicide
Herbicide
I
ay
to August
Allocate 4
to fruit
production
a state variables
0 transfer conditions
systems Input-output
Figure 14 Model flow chart
dd mangrove
community
to
detritus
�Table 7 Macrocliraate input
Kouth
Temperature CC)
Precipitation (sm)
Total Solar Radiation
Salinity /.
.
(parts per thousand)
.„....' .
1
23.5
6,6
350
14.5
2
;
:
3
4
27.7
28,0
5.8
3.4
20.0
...
26.6
24.6
422
. . .. . -
60.0
456
22.4
438:.
27.9
5
6
7
8
25.9
24.8
25.0
201.0
204.0 199.0
184.0
337
391
369
20.0
10.1
386
0.0
\
10
11
25.5
25.8
23.5
24.0
199.0
201.0
64.0
27.0
• 355
"0.0
0.0
334
0.0
316
0.0
12
316
3.5
00)
�149
to approximate the daily values (Eric Hcald, 1971). The salinity curve
coincided with the solar radiation curve. Assuming a relationship between
aolar radiation and evaporation, the Florida salinities are used as an
approximation to the Rung Sat Delta.
IX. Propagules
The propagulea are initiated through adult dropping and immigration from
•
peripheral areas (Figure 15). The fruits ripen and fall from May to September.
Ninety percent of the fruits produced stay next to the parent tree. Approximately ten percent of the indigenous propagulea are assumed to be invading
new areas. Propagule mortality s.s a function of varying temperature and
salinity. The mathematical funcf.ion describing mortality dua to temperature
is a linear decrease from sixty-seven percent mortality at 36'C to zero
Mortality at 30°C:
'......
••• '
,'
K-- (30 -T.) ( . 7 5
06/)
J>
n
,
.•
'. -. i
:
<L>
where K_ is mortality due to T,, tha «lr temperature. The mortality duo to
ealiaity was approximated after Stern and Voigt ( 9 9 whera mortality
15)
increased from -thirteen percent in sea water to forty-seven percent In tap
water as follows:
;
M g - (1- S/45) (,.'i)
(2)
; '
• . - " . . • ;:.v,' •; • ... i ,- '
where Mg ia the mortality dve to salinity S which is In parts per thousand.
Ml the dead propagulea are transferee! directly to detritus.
Living propagules all geminate and grow leaves, stems, And roots with
a rate or growth an follows:
.-.'
dG/dt « !o6(Gm,« « G) (Salisbury and Ross, 1969)
(3)
�150
mof@rici!s to
roofs and leaves
Figure 15 profcagules submodel flow chart
�151
where dG/dt is the rate of growth, k is a time constant relating to the
length of time taken to reach GmaJt which is the optimum blomass of the
leaves, stems, or roots prior to the transfer to seedlings. G is the
current blomaso of the leaf, stem or root part in question. As a propagule
only stored energy is used for growth. Optimum leaf, stem and root biomassea
were calculated by taking the caloric values for propagules, leaves, stems,
and roots ( . 8 4.13, 4.34, and 4.03 kcal per gram dry weight after Golley,
45,
*
1969), converting to kilocalories per gram wet weight using a 0.4 dry to wet
weight conversion factor, then dividing the propagule energy content by
the weighted plant energy content: assuming; 0.22, 0.63, and 0 1 .for leaf,
.5
stem, and root fractions respectively. This yields an estimate of prcpi^ule
' energy content after distribution according to seedling wet energy contents:
ie. the propagule will grow to 2.4 tines its dormant bloreass before needing
outside energy input. After taking 2.4 tinas the propagule wet weight and
subtracting expected respiration losses, we can estimate the leaf, stem,
and root biomaseea as 22, 63 and 15 percent respectively of the remainder.
Once the optimum leaf, stem and root biosiassea are attained the propagules
•»
ara transferee! to the seedling category.
III.
Seedlings aad Adults
»
;
- . . . . . . - • • • •
Once a propagule has attained the seedling leaf-stem-rcot ratio, the
growth scheme given in Figure 16 is followed. The life pattern in seedlings
is assumed to bo exactly the earae as that of an adult therefore the same
flow chart and subroutine are used with different initiating parameters.
•
First solar energy enters the canopy and fifty percent is absorbed by the leaf
material. Net photosynthesis is calculated after Gaastra ( 9 3 as follows:
16)
�50%
•*s
M-
Retract
leaf
material
Leaves
If 7,2g/piant,
Seedlings
w
CO
A
93
0
a.
Photosnythate
ft
c.
ft
a
i
I
H
ft
Stems
Roots
Allocate
Assimilation
50%
�153
Pn - (100,1it - [CC,L / (1.56r, + r 41 + rU)
A
£ &
Xi
•«.
(4)
where Pn is the net photosynthesis for IAI equal to 1.0, [C02J and
[ O ] are the carbon dioxide concentrations of the air and leaves, r. is
C *„*
,,
Jb
..#
the leaf resistance to water loss, 1.56 is the ratio of the diffusion
coefficients of carbon dioxide and water vapor, ra is the laminar boundary .
layer resistance and r is the mesophyll resistance to carbon dioxide exchange.
The leaf resistance to water loss is calculated using:
rA - ( . - ( . 2 5 (WD x SA) + (C X WD x S )6 / 1 + (16 x SA))
05
004)
A 1) ( .
(Miller and Ehlrlnger, 1972) (5)
where TO is tha water deficit, SA ia solar absorbed, and C is a constant.
The net photosynthesis is then multiplied times the leaf area index then stem
and root respiration is subtracted. The Gaastra equation takes into account
leaf respiration so only sfcesa end rooc respirations are subtracted from the
net photosynthesis. Respiration is calculated using the Q . equation:
.
0 2tf!T *• T }
where R and T are reference respiration rate and temperature, respectivaly.
Dally respiration was estiaated directly from equation (6) where as dally
net photosynthesis was a linear approximation from the instantaneous solar
uoea rate.
-
•
•' " • . • ' ' ' " ' ' . ' ' - ' •
• '"''
'
•
' :- •'
The light entering tha canopy was extinguished exponentially:
.
.
SA. • SAe *
()
7
where F is the leaf area index, and k, is the extinction coefficient
which is calculated as follows:
» . : ; . ' . - •:•:>•••;
*
k. » cos (I)
(Duncan, ct al., 1967)
<8)
�ISA
where I Is Che leaf inclination from horizontal* Dynamic strata we e used to
%
.
correct for reduced photosynthesis with tha extinction of light through the
canopy. It has been noted that tha leaf angle used in equation (8) decreases
from the top to the bottom in an adult canopy (Miller, 1972). Miller (1972)
has also measured the leaf areas for various mangrove canopy strata and given
a typical tree distribution far both leaf inclination and leaf area. Given
the typical leaf area and leaf angle distribution for adult trees one can
distribute a total leaf area index accordingly yielding a corresponding
reduction of light for lower levels in tha canopy. This process limits
the size of the canopy in tha following way. In the model if a stratum has
a negative production, respiration exceeds photosynthesis for the stratum, then
the stratum leaf biomass is reduced accordingly, also the stratum does not
recieva new material for growth. The iowsr levels ere then reduced as the
leaf area index exceeds the value at which all strata sustain sero to positive
production.
This yields an optimum leaf area index and maximum tree size .
which maximizes production.
- •
-
Once daily phbtosyntbasis is calculated it is reduced according to the
temperature function described in the accompanying paper. Zero efficiency
occurs at 25tC with, a linear decrease from 25"C to 15°C and 25°C to 35*0
such that an JL58C or lower or 35°C or higher photosynthesis does not occur.
Assimilation is then the difference between respiration and net photosynthesis. If the daily assimilation is negative, leaf material is lost
at a rate of twice the negative assimilation assuming fifty percent
efficiency in the resorption. Fifty percent of the retracted leaf material
goes to maintainencc of the plant while fifty percent is transfered to
detritus.
If net photosynthesis is positive then it is allocated as follows:
�155
F
i "2<OF1) "CFi
( )
9
where F, is the fraction allocated to the i
fraction of the 1
plant part, OF. is the optimum
plant part and OF. is the current fraction of plant
Material residing in the i
plant part. OF values for leaves, stems, and
roots ate 0.085, 0.610, and 0.310 for adults and 0.22, 0.63, and 0.15 for
seedlings.
*
The seedling to adult transfer occurs at 7.2 grams of leaf material
per.plant. When thl« arbitrary leaf bicmass is reached the seedling is
then considered an adult. This weight standard corresponds to the weight
of four mature leaves.
.
.
IV. Fruit Production
The fruit production schema was designed from qualitative descriptions
of red mangroves on ths Rung Sat Dalta. Fruiting begins in March with peak
production from Hay to July with a steady decrease frost July to August.
Fruit production ceases in August. Thaae observations were incorporated in
the model as a discontinuous function as follows:
March to Hay
Ff • (D/30) x 0.5 MX
May to July
7f - MX
.
July to August
'
,
(10)
.
*"•••'(.
(11)
• . , . - . . • • • •••''.••
'
••
' :
Ff - HX - 0/30
(12)
where F- is the fraction of leaf material available for growth allocated to
fruit production, 0 is the current day of the month and MX is the maximum
fraction of net production allocated to fruit production. From January to
March and from August to Decetnbor F. Is set to zero. The MX value vas
arbitrarily set to fifty percent of leaf material available for growth.
�156
V. Detritus, Nutrients, and Herbicide
•
All dead material is added to detritus which is undergoing a tidal
exportation of 87.4 percent (Golley et al. 1962) and exponential decay:
' '
-kt
'
D - do *
(13)
vhere D is the current weight in grams of detritus, d is the Initial weight
.in grama of detritus, t Is time lapse froia Initiation in days, and k
-3
•'
• ' • • . , .
is 6.7 x 10 which is the decay constant associated with forty-five percent
decomposition in two months (meetings on mangrove ecology, 1 7 )
92.
A fraction of decomposed detritus ie then allocated to nutrients and
herbicide in solution. Thirty-five percent of decomposed detritus is
assumed to be nutrients with 0.05 percent being assumed herbicide if the
plant death IB & result of herbicide introduction. Nutrients and herbicide
in solution Chen undergo exponential dacay as follows:
."•"
H-n/2* '
'• ""'"•'•
' ' V"
M
H - ha *
-
.
":"' ' '';'"'•'•" -JJ4)'
'"'
'" ' •'""'
"".''"'"" *"
(15)
vhere H is the current nutrient concentration, a is the initial nutrient
*
•
.
"
.
•
.
'
concentration, k, is the decay constant relating decay exponentially to
tine, H is the current herbicide concentration, h is tha initial herbicide
concentration, and k_ is the decay constant relating decay exponentially to
time. It is assumed that 87.4 percent of the nutrients and herbicide in
solution is exported with tidal inundation periodically.
X£ the herbicide concentration is above 10'lbs per acre or 11.2 x 10
gr. per hectare defoliation occurs and all the leaf material is tranafered
to detritus.(meetings on mangrove ecology, 1972).
�157
Evaluation of Data Base and Estimation of Parameters
There, are. few.data available regarding propagule and seedling
growth. To determine an estimate of tha leaf-stem-root fractions for
seedlings two submodels were proposed using ( ) the typical adult
1
leaf-stem-root fraction indicated by Golley g&j&b ( 9 2 and (2) A
16)
linear projection of the Golley data to approximate seedling leaf-stem-root
fractions. If the plant part bicnaeaes for leaves, stems, and roots are
reduced to fraction of the total biom&sK and plotted versus the diameter
at breast height clear trends are indicated for leav««s «nd roots.
Projecting
these trends to zero diameter at breast :fe®ight yields 0,22 and 0.15 for laaf
«nd root fractious. This procedure waa don® by hand and the leaf and root
fraction appear to be a curvilinear function of diameter at breast height
•o the indicated values ere crude estimates. With 0.22 for tha leaf
fraction and 0.15 for the root fraction wa have 0.63 for the stem fraction.
Submodel (1) resulted in u quick elimination of seedlings under a leaf area
index of 1.0 and 3.0, and zero Katyration to the adult categories under a
leaf area index of ataro. Submodel (2) indicated four year survival imdor
• leaf area index of 1.0 and maturation fo tha adult category in three years
under « leaf area index of sere.
In determining the root fractions an approximation was used correcting
the Puerto Rlcan data (Golleyj|t al?81962) for subsurface roots. Snedacker
and Lugo ( 9 2 indicated subsurface roots as thirty-six percent of the
17)
prop-root-aobaurface root subtotal. All of the prop-root biom&sses
indicafed by Golley were then divided by 0.63 to include an astiraate of the
addition due to subsurface roots.
•
,
,
*
Correcting tha leaf-atea-root fractions indicated by Golley ££ j . (1962)
i
at 2.8 cm, diameter at breast height we have adult fractions of 0.085, 0.610,
�158
and 0.305 for leaves, stems, and roots respectively. These values were used
to characterize the typical adult plant in the model.
Two fruiting submodels were proposed: (1) a fraction of the assimilation
allocated to leaf production was used for fruit production, and (2) a
fraction of the total assimilation was used for fruit production. With submodel
(2) fruits averaged ten percent at maturation of the total adult biomaas.
Submodel (1) indicated fruits between 1.5 and 3.1 percent at maturation of the
total adult biomass. Snedacker and Lugo ( 9 2 found between 0.0 and 4.1
17)
percent residing fruits in their studies of red mangroves.
To determine seedling density for estimating the leaf bioaass per plant
the above ground dry weight at the *nd of five wmths growth was divided by
1.77 grams which, is the above ground'dry weight of five mouth old seedlings
as indicated by Stem end -Vol&..t ( 9 9 . With an immigration of 3.0 grams of
15)
propagule a year this yields a first year density of 1.1 seedlings per meter
squared. Typical assimilation data, for this density are given in Table 8.
Results
'*
-.
•• . :
>
.
.
.
.
.
.
.
The effects due to temperature are demonstrated in Pigur« 17. Three
twenty year aiiaulatlons were made with (1) normal temperatures, (2) half
degree above normal temperatures and (3) a full degree above normal temperatures. Simulation ( ) end (3) showed eighteen and.forty-eight percent
2
decreases in blomass below the biociasa of simulation ( )
1.
,
. .
The effects due to salinity wcra less dramatic. Three twenty year
*
simulations were made using (1) the normal salinities for brackish water,
(2) one part per thousand abova normal salinities for brackish water and (3)
two parts per thousand above normal salinities for brackish water. There was
less than one percent variation in total biomaaa between the three simulations.
�159
Table 8. Net. photosynthesis, total respiration and plant assimilation In grams
organic matter per meter squared per day are given for various growth
v,
stages with no overhead light extinction for seedlings of density 1.1
and*adults of variable densities.
Months After
Defoliation
Leaf
Biossass
Photoayathesis
Respiration
Assimilation
5 months
1.2
001
.2
004
.0
007
.1
17 ninths
3.6
006
.6
a 012
Q 054
29 months
10.3
017
.8
004
.3
a 152
5 years
19.1
0.334
014
.0
0.230
7 years -
39.6
0.675
0.315
0.359
9 yeara
51.3
0.356
0.554
0.301
11 yeero
78.8
1.220
Q 7 90
040
.3
Year's After
Defoliation
�Figure 17 Total manerove biaoass with temperature
variations
2000-1
<M
E
CO
tn
1000
o
I—
o*
o
�161
Variations of reforestation due to varying immigration are shown
in Figure 18. Three twenty year simulations were made using immigration
rates of ( ) 1.0 grams, (. 2.0 grams and (3) 3.0 grams of propagule per
1
2)
meter squared per year. Simulations ( ) and (2) showed twelve aad^nine
1
percent decreases in biomass below the blomass of simulation ( )
3.
Conclusion
\ .
.
*
The effects due to increased salinity appear to be relatively small.
The effects of temperature play a major role in reforestation. The barren
nature of the Rung Sat Delta due to defoliation and wood gathering has
increased the likelihood of temperatures inhibitory to plant growth.
Inhibitory temperatures and slow immigration are the.major sources of
inhibition in the model and in coabiastlan probably play the major role in
reforestation problems on the Rung Sat Delta.
The most critical deficiency is the lack of data on the growth habits
of propagules and seedlings. The nature of initial rooting and the role of
solar radiation in activating propagules on the mud are unknown. Data are
available on five month old seedlings and adults of unknown ages. There are
data concerning adult photosynthesis, respiration, canopy structure
and root structure but no intermediate points for seedlings and younger
*»
adults which would serve to improve and validate the model.
�Figure 18 Total mansrove biomaas with immigration variations
2000 H
CSI
£
w
3
g
03
1000-1
I
15
YEARS
20
�163
LITERATURE CITED
Com/ay, H. 1963. The Heather Handbook. Conw.iy Publications Inc.,
Atlanta. 255 pp.
Cuong, Humbert Vu Van. 1964. Flore et Vegetation dc la mangrove.
These dc docteur, Universite de Paris.
Dept. of Commerce. 1958. Viet Nam solar radiation data for the
period January, 1964 through October, 1967. Environmental
Data Service, National Climate Center, Asheville, North Carolina.
Duncan, W. G., R. S. Loomis, W, A, Williams, and R. Hanoi. 1967.
A model for simulating photosynthesis in plant communities.
Hilgardea .38.
Gaastra, P. 1963. Climatic control rJ photosynthesis and respiration. In L. T. Evans (ed.) Environmental Control of Plant
Growth, Academic Press, New York.
Golley, F. B. 1969. Caloric values of. wat tropical forest vegetation. Ecology 50 ( ) 517-519.
3:
Golley, F. B. 1971. Effect of Defoliation o:« Mangroves. Report
to the National Res. Council Cossaittea on the use of Herbicides
in Viet Nam. 18 pp. Mimeo.
Golley, F., H. T. Odum, and R. F. Wilson. 1962, The structure and
BQtaboliszn of a Puerto Mean mangrove forest in May. Ecology
43? 9-19.
Eeald, E. 1971. The production of organic detritus in a south
Florida estuary. Univ. of MiAmi, Coral Cables. Sea Grant
Tech. Bull. 6.
Killer, P. C. 1972a. Bioclimate, leaf temperature, and primary production in red mangrove canopies in south florida. Ecology 53:
22-45.
Miller, P. C, 1972b. A test of radiation models in vegetation canopies. Submitted to J. Appl. Meteorol.
Miller, P. C. 1972c. Investigations of physical processes affecting
leaf temperature profiles and primary prod-iction in the red mangrove ecosystem. Progress Report.. AEC Contract AT ( 4 3 - 0 .
0-)87
�MiUert P. C. and J. Ehleringer. 1972. Comparison of leaf resistance!)
to water loss and leaf water relations in three mangrove species
In south Florida. Ecology ( n review).
i
Miller, P. C. and L. Tieszen. 1972. A preliminary model of processes
Affecting primary production in the arctic tundra. Arctic and
Alpine Res. 4i 1-18.
I
Monteith, "J. L.' 1965. Light distribution and photosynthesis in field
crops. Ann. Bot. U.S. 19: 17-37.
• • •
•
Moore, R.- T., P. C. Miller, D. Albright, and L. Tiesften. 1972. Comparative gas exchange characteristics of three mangrove species
during the winter. Photosynthatica (in presa).
Salisbury, F. B, and C. Ross. 1969, Growth and problems of morphogenesis. 407-438 pp. IG Plant Physiology. Wadaworth Company,
California.
Snedacke?, S. C. and A. E. Lugok Center for Aquatic Sciences. The
role of Bangrove ecosystems in the maintenance of environmental
quality and a high productivity of desirable fisheries. Bureau
of Sport Fisheries and Wildlife 1 - 6 0 8 6 & Annual Report FY
41-0-0
71-72.
Stern, W, L. and 6. K. Voight. 1 5 . The affects of salt concen99
tration on growth of red nffisagsre-rea in culture. Bot. Ctasatte
121(15i 36-39.
Tschirloy, F. H. 1969. Befoli@tj.on in Viet Kaa. Science 163s 77976
8.
Waggoner, P. £. and W. S. Reifsayder. 1968. Simulation of the temperature, humidity, «cd evaporation profiles in a leaf canopy.
J. App.l. Moteor. 7s 400-409.
Zinke, P. 1972. Report on a reconnaissance of the ooil fertility
aspects of cheaical defoliants in South Viet Nam. Report to
the Coosmittee on the use of Herbicides in Viet Mam.
�165
6.
Ordering and Disordering in South Vietnam
by Energy Calculation
Mark Brown
Studies (stimulated by a contract between the National Academy of Sciences
end the Department of Environmental Engineering Sciences, University of
Florida, Gaineoville, for "Models of Herbicide and War tn Vietnam".
�166
Central to understanding the relationship of countries and their balance
of Man and Environmenta are the flows of energy that maintain order, the
disorder created In the normal cycle maintaining order, and the effects of
war. This paper considers order and disorder relationships in South Vietnam
as a result of the War from 1960 to 1972.
An investigation of effects of
herbicides wat> undertaken, as a series of projects, by the National Academy
cf Sciences. This piper is an outgrowth of concepts developed while formulating a model of main energy flows in Vietnam.
The Investigation of ths ecological and physiological effects of the
defoliation and crop destruction programs in South Vietnam included an
evaluation of the herbicide agents and their relationship to other means of
disordering and the combined effects of disordering activity on the natural
ecological and man-made technological systems of the country. While it is
apparent that the goals of the defoliation programs were to reduce the ground
cover and limit the ability of the North Vietnam and Viet Cong military structura to use the structure of the natural environment to their advantage, these
goals have left the country of South Vietnam with problems, targe amounts
of South Vietnamese lands were altered and moved from one foita of land use
to others, resulting in measurable changes to the processes of the country.
Understanding the immediate effects of such a program and the long rango effects
and Interactions may require a... overview that also takes into account time
delays, feedback operations, and secondary interactions. One technique for
overviewing Is * drawing of a systems diagram.
�167
•
A Model of Vietnam
Figure 1 is a diagram of the country of South Vietnam at war. It shows
tha compartments and flows of energy and materials throughout the country.
The circles to the left represent forcing functions or the Orderin^ Energie s
available to South Vietnam.
S is all incoming goods, both United States
aid and imported goods from the World Market. £7 is all money sent to South
Vietnam in the form of aid; and 3$ is all the natural energies (sun, tides,
wind, rain, etc.) available to the country. Tha circles to the right represent the DisorderingEnergies, that are forcing functions for the country at
war. So i* all **le energies available to the Viet Cong and North Vietnamese
military structure to make war.
83,84,851 are the three major disordering
energies of the U.S. and South Vietnam military structure.
Tha land categories (city, agriculture, forest and mangrove) are each
separated into their respective components (or storages). The city system
has within it land, people, Rooda, and a storage of money. The natural systems haw two components each: lend and structure. The land storage and
the forcing functJon interact to produce structure.
The components to the right of the nature! systems, those of craters,
base land, bare land, and dead wood, are components that are storing the
disordered land and structure as it is tr if@rred from one land use category
to another by the impact of the disordering energies.
In Fig. 1, the rates of material and energy flows, and the quantities
stored in each of the components of the country have baan calculated for the
year 1965; the beginning of the escalation of the United States involvement
in Indochina War. (Calculations and sources for the calculations are summarized in Appendix A.) Evaluation of the flowa of disordering energies gives
perspective to their effects on the many processes of the country. Consider
the quantities of land and structure removed from each of the land use cate-
�Figure !
.
MODEL of
CHANGING LAND
USE
for country of
SOUTH VIET NAM
1965
�169
gories by bombs and herbicides; in all cases herbicides account for the
greatest disordering, an effect that reverses through the course of the six
year period from 1965 to 1970.
Another method of understanding the effects that the disordering energies
have had on the processes of Che country is to calculate the disrupted portions of the energy budget of South Vietnam. The overall effects on the
energy budget are summarized i.n Tsble 1. Column 1 in Table 1 chows the average
energy budget (ordering energies) per year for the six year period, 1965-1970.
column two shows the cumulative budget for all six years. Columns three, four,
and five show the total amounts of Disordered Energy due to each of tha disordering operations of Bombing, Herbicides, and Rome Plowing as best they can
be calculated. Column six shows the porcentage of the energy budget
that was disrupted for each of tha various subsystems of the country.
During the six year period of tsajor United States involvement in the Indochina War (1965-1970), 3.1% of the total enargy budget of South Vietnam wan
disrupted. If comparisons can be drawn between the man-made world as various
eystems and the natural ecological systems of the biosphere, then a disruption
of this magnitude, by itself, will probably have little effect on the overall
processes of t>« country.
�Table 1. Comparison of Disordered Energy
Average
Energy
Budget
<7)
()
8
Cumulative Disordered
Energy
Energy
Budget
BOMBS
1965-1970
1 " kcal/yr 10*2 kcal kcal 10*2
0
Sanaa Settlements
Agriculture Systems
19 .4
( ) 116.4
1
112 . ( ) 672.00
0 2
()
9
(0
1)
Disordered Disordered
Energy
Energy
HERBICIDES ROME PLOW
kcal 1012
9.1*
8.78
kcal 1012
4.9*
24.33
1110 . ( ) 6660.0
0 3
303.14
179.4
Mangrove Systems
61 . ( ) 366.0
0 4
12.55
Estuarine Systems
0 5
29 . ( ) 174.0
.24
?
349.36
338.18
1.55
9.0
?
12. 9Z
136.1
Forest Systems
0 6
Other Nat. Energies 2647 . ( ) 15882.0
TOTAL
3978.4
23870.4
Z of Energy
Budget
Disordered
,
4.
06
5.2%
7.9%
40.6% . ;
5.3%
.
?
42.15
?
3.1%
* City land disordered by boatbs and herbicides was 8.7Z and 4.2Z respectively. It was then assumed that
an equal percentage of the total energy budget was disrupted..
�171
1. Vhe sum of purchased goods, foreign aid, and fuel. Purchased goods and
foreign aid were 2.6 X 108 $ and 5.1 X. 10° respectively multiplied by 1.4 X 10A
kcal/dollar to convert to equivalent fossil fuel energies required to generate
the samo work, (10.7 X 1C12 kcal). Add to this, fuel (8.66 X 105 metric tons)
( 0 grams/ton)(10 kcnl/gram) - 8.66 X 10*2. 10.7 X 1012 + 8.66 X 10-12 «
16
19.4 X 1012 kcal.
2. The chemical potential energy entering the system as agriculture production was estimated by multiplying the land area in agriculture (7.31 X 106
acres) by the estimated gross photosynthesis (1.6 X 105 kcal/acre/day) and then
by 100 days.
3. The chemical potential energy entering the system as gross photosynthesis
of inland forests was estimated by multiplying the land area (1.9 X 107 acree)
by the estimated gross photosynthesis (1.6 X 2.0 kcal/acre/day) and then by
365 days.
4. The chemical potential energy entering the system as gross photosynthesis
of mangrove systems was estimated by multiplying the area (.69 X 10*> acres) by
the estimated gross photosynthesis (2.4 X 105 kcal/acre/day) and then by 365 days.
5. The chemical potential energy entering the system as gross photosynthesis
of estuarine systems was estimated by multiplying the area (1.0 X 10& acres) by
the estimated gross photosynthesis (8.0 X 10 kcal/m2/day) and then by 365 days.
6. The sum of the natural potential energies of: Rivers (644 X 1012 kcal/
yr), Tides (152 X 10*2 kcal/yr), Rain as Runoff (119 X 1012 kcal/yr). See Odum,
"Effects of Herbicides on Ecosystems."
7. Cumulative energy budget was calculated as the maximum possible, assuming
there was no disordered land. It was calculated by multiplying the average
energy budget times the time span (6 years).
8. Disordered energy by bombs was calculated by multiplying the lend area
disordered each year from 1965 to 1970 by the estimated gross production, and
�172
then by the number of years remaining in the six year period. (See Appendix
B for year by year breakdown.)
9. Disordered energy by herbicides was calculated by multiplying the land
area disordered each year from 1965 to 1970 by the estimated gross production
and then by the number of years remaining in the six year period, except
agriculture sprayed assumed only one year loos. (See Appendix B for year by
year breakdown).
10. Disordered energy by Rome plowing was calculated by multiplying the
land area disordered each year from 1965 to 1970 by the estimated gross production and then by the number of years remaining in the six year period, except
agriculture plowed assumed only one year loss. (See Appendix B for year by
year breakdown).
�Order and Disorder in Vietnam
It is well known that many ecological systems are stress adapted and to
a certain extent even depend on sorae form of stress to speed up processes
and recycle nutrients.
Just as the fire-climax forests and prairies are
stress adapted, and depend on pulses of brush fire to recycle nutrients; the
country of South Vietnam could possibly be considered a stress adapted system.
Conflict, and large-scale warfare have been the rule rather than the exception
since the Geneva Agreements of 1954 and even before with a long and bitter conflict between the Communist led Vietminh and the French armed forces. Frequent
stress, such as grassland, grazing, rather than a pulse stress results in
greater overall production by reducing diversity and releasing disordered
materials for reconstruction and repair. Could the came apply tc a 30-year war
and the country of South Vietnam'
Tha nix year involvement of the United States in the Indochina War resulted
in an escalation of disordering energies which could represent an additional
pulse stress of 3.1%. Far more important than the magnitude of this overall
stress are the percentages of the energy budgets that wete disrupted from each
of the subsystems of South Vietnam. Column 6 in Table 1 lists the percentages
of each subsystem disordered. A comparison of these indicates that while the
country had a 6 year pulse stress of 3.1%, individual stresses account for major
effects, and due to secondary interactions may magnify this overall streas.
The mangrove systems were stressed naarly 41%; a stress that would reduce
the ability of the system to recover in a short period of time. Data gathered
by HAS personnel while surveying ecological effects of herbicides in Vietnam
indicate a lack of recovery, possibly du« to loss of seed source. It has been
suggested recently that mangrove systems are an Important part of the food chain
in estuarint systems. A stress of this magnitude could have severe effects on
estuarlne systems that, in turn, will effect the human settlements by a loss of
�food source.
The forest systems of the country were disordered nearly 8%; a stress that,
will probably have little effect on the individual system, but if time delays
and secondary interactions are taken into account, then those systems depending
on the forest systems as an auxiliary energy source (the human settlements)
will feel the stress far more than th® initial system.
The human settlements of South Vietnam had 13% of their energy budget
disordered during the six year period (1965-1970). Add to this the effects
of increased population due to relocation of refugees, reduced agriculture
production ( . % , reduced estuarinct production, and reduced forest production,
52)
and again the direct stress is magnified requiring many years to recover.
Another way of shoving these same effects for the purposes of comparison
to other flows of energy throughout the country ia the systems diagram. Figure
2 is an energy diagram of Che gross energy budget for the country of South Vietnam showing ell the main energy flows, constructive and destructive, those of
nature, and those of tha cltits. Energy of low quality such as sunlight is
expressed in the chemical potential energy after transformation by photosynthesis.
The flows of high quality energy aisch aa tha urban technological economy are
expressed in equivalent fossil fuel energy required to generate the flame work.
When many of the details o£ email component flows of energy through the
country, such as in Figure 1, are eliminated by retreating to a more macro-scale
view, certain patterns, or consequences of the war become more obvious, and
comparisons can be drawn. For instance, tha ratio of the destructive energies
of war (disordering energies) to the constructive energies of nature, and the
cities is approximately 1 to 17, or the disorder to order ratio Is 6.0%.
Ewel (1971) described flva tropical environments disrupted with a disorder
to order ratio of 5.8% showing initial decreases in primary production, but
long run rejuvenation. Richey ( 9 0 tested a disorder to order ratio of 8.0%
17)
by burning microcosms; again showing initial decreases in production; but
�rbcn
Structure
ncuilure
Disordered
Structure
ail values: I O l 2 k c a ! / 6 years
Figure 2- Energy Budget of South Vietnam, 1965-1970.
�176
Notes on Figure 2.
1. U.S. war effort was calculated by adding the incremental costs' of the
war in Vietnam for the years-1565-1970. The incremental costs are the costs
which represent the "net difference between wartime and peacetime needs."
(U.S.
Congress. House Coiraittee on Appropriations. Dept. of Defense Appropriations
for 1970 pt. VII. Hearings, Washington, U.S. Government Printing Office, 1970.
p. 395).
The total war effort (9181 X 1010 dollars) was then multiplied by 1.4
X 10* kcal/dollar to obtain the energy expenditure.
•
••••
2. Viet Cong and North Vietnamese war effort was estimated by assuming
steady increase fviwi $555 million (Thayer, 1969) to $765 million in 1970 ( . . ,
AP)
Gainesville Sun, Gainesville, Florida. April 2, 1972). The total war
effort ( . X JO9 dollars ';s then multiplied by 1.4 X 10* kcal/dollar to obtain
39
.a
the energy expenditure.
"
...
^
.
3. U.S. Aid was calculated by adding the official aid for the years 19651970.
(Annual Statistical Bulletin, No. 14.) the Official Aid (3.03 X 109
dollars) was then multiplied Ly 1.4 X 10'* kcal/dollar to convert to potential
energy entering the system.
,
4. Natural Energies are all those ttwsrgiea entering the country from the.
chemical potential energies of gross photosynthesis of ecosystems, and the
chemical potential energies of rivers, tides, thermal heating, winds, and rains
as runoff.
5. Fuel inputs are from "Vietnam Statistical Yearbook." For the 6-year
period j.2 X 10^ metric tons, this was multiplied by 10 grams/metric ton and
by 10 kcal/gram to convert to calories of work.
6. Purchased goods was calculated by adding the import arrivals from Annual
Statistical Bulletin No. 14 for the years 1965-1970. The import arrivals ( . 9
15
X 109 U.S. dollars) was then multiplied by 1.4 X 10* kcal/dollar to convert
dollars to the potential energy equivalent. Here It is assumed that 1/10 this
amount Is the energy value to the system, the remaining 9/10 is the cost of
�177
manufacture and transportation. The calculation of energies vac based on raw
chemical potential energy conversion of each of the flows. There are studies
currently undarvay to give certain "qualities" to energy to allow for more
complete accuracy of calculation for modelling purposes. For example the "energy
value" of a raaterial or energy in a system ie not only the measurable quantity
of that flow, but has bean imggested to bo the initial energetic costs cf processing and manufacturing aui well.
�178
recovery, and In ootre instances increases with time. Thus if comparisons
can be drawn between the smaller scale oystems of microcosms and individual
ecosystems and the larger scale system of a country made up of many smaller
subsystems, the impact of a pulsa disorder to order ratio of 6.02 will probably
release material and increase repair mechanisms required for rejuvenation,
thus having A greater gross production with time. However, this does not
indicate a stronger or more stable system for the higher gross production is
achieved at a cost to diversity.
During this same 6 year period the disordering energies were 12 times as
great as the flows of ordering energy due to foreign aid and purchased goods
and fuel. Aid was over half that of purchased goods and fuel indicating a
subsidized economy, an economy dependant upon increasing flows of high quality
energy in a world where these flows are becoming limited.
But more important, the; diegram shows where the most stress was inflicted
by the actions of war. Th& natvral ay 13torn, while having a largo loss in comparison to the urban energies disordered, was stressed 2.7%.
The urban system
(manbuilt-technological economy) had 7.0% of its incoming energies disordered.
Other consequences of the war (secondary interactions) such as the shift in
population from rural areas to the urban centers, the loss of population as casualties of war, and shifts in land use, have magnified this strasa.
These calculations begin to show a more complete picture of the disordering
of South Vietnam and some conjectures can be made. As a consequence of prolonged
conflict and war the country of South Vietnam has become a stress adapted system
decreasing diversity, and maintaining a low aucccssional stat*. If, again,
comparisons can be drawn between man built technological systems and natural
ecosystems, than the country of South Vietnam can b« considered a pulse-climax
nation, much like the fire-clteax forests and prairias, which, require large flows
of energy and materials for reconstruction and rejuvenation after disordering,
and thus maintain low diversity. As long &s the disordering effects of the
�179
conflicts remain, it is reasonable to assume that the country of South
Vietnam will remain an unstable system.
�180
Simulation Model of Vietnam
The disordering of landa and the accompanying transfer from one land use
category to another might not: be a "bad consequence" of the war; but in the long
run, by those who advocate increased agricultural production for the country.
For example, the change from forest to bare land has accomplished the first
step in the process of bringing more land into agricultural production.
This
seems to be the case, as long as there are the necessary energies (U.S. Aid)
available that can be added to the country's own reserves to accomplish this
goal. However, there are ahort term losses that disordering vast amounts of
forest, cropland, and urban systems must necessarily bring.
The if.tions of war hav« dioordcri«« »fSects on not only the physical, natural
and wars-made systems» but on the nodal and economic systems as Veil. As a consequence of the war there has been a saaaaivc switch from a rural to an urban
population. With the help of U.S. Aid this shift in population has caused the
urban centers to expand at an ever increasing rate.
The effects th« disordering energies have had on the country of Sooth Vietnam can only be assessed through time. The use of the systems diagram translated
into the language of the analog computer and simulated gives new insight to 'He
cumulative effects of all disordering energies. Figure 3 is a simplified version
for the purposes of simulation, of the changing land use model in Figure 1. This
diagram shows the action of war accelerating the recycling and reuse of disordered
lands and materials. These are all parts that when fed back with or, accompanying
energy input, are available for and utimulate reconstruction. Evaluation of ths
rates gives a perspective of those changaa that are important and computer simulations are useu to show the cumulative effects on South Vietnam's energy budget
as well as the costs or reordering.
Calculations and sourcts of information for the Rates of Flows and the storages in Figure 3 are summarised in AppendIK C. War Effort (V) and United States
�Fig. 3
War Stress Model, Country
South Viet Nam
of
CITY
EXPORTS
�(A; have functions generated Co more accurately depict the escalation of U.S.
Involvement in Indo-China, The War Effort (W) starts (1950) with minimal war;
the approximate level of conflict prior to U.S. Involvement.
In 1965 the level
increases reaching a maximum in 1967, then decreases to an estimated level of
conflict equal to that prior to 1965. (Sea Appendix C.)
United States Aid (A) remains at zero (0) until I960, then increases at
a rate constant with reported U.S. Aid. In the first simulation (Fig. 4a-f) Aid
was held constant (after 1970), at the 1970 level. In the second simulation
(Fig. 5a-f) Aid was increased «fcer 1970 to a maximum in 1985, then terminated.
And in the third simulation (Fig. 6a-f) Aid was decreased steadily after 1970 and
terminated in i960.
Figures Aa-f, 5a-f, and 6a-f are computer generated gvaphs of the first,
second and third simulations of the model. The graphs indicate a steady state
system from 1950-1965 (with alight decreases in certain storages [L2, S2, L3, S ]
j)
until escalation of the war in 1965, causing decreases in all compartments of the
system except the human settlements.
The Mangrove systems (Fig. 4B) show the expected disruption anticipated by
the calculations in Table 1. However, the structure component ( . continues to
S)
decrease after the pulse disordering of war, probably due to increased wood cutting
for charcoal. There is no recovery && might be expected because provisions for
a seeding program are not Included in the model. In the second and third simulations little change in exhibited. The structure does decrease however, with the
second simulation due to increased demands of the human settlements.
The forest eyatercs (Fig. Ac) of the country exhibit a slight decrease in
the first simulation, somewhat aggravated by the increased demands of the crowing
human settlements. Recovery, as expected, does occur, but the system does not
�183
Figure
4
CONSTANT AID
Max
1930
I960
070
1980
I9SJO
Max-
I960
2000
1970
1980
1930
2000
L | Mangrove Land
—— S| Mangrove Structure
W, War Effort
A U.S. Aid
a.
b.
Matt
Max
1950
ISGO
1970
1930
1990
2000
1990
I960
—— LZ Forest Land
I960
1990
2000
i-3 Agricultural Land
—— Ss Forest Structure
—- S 3 Agricultural Structure
c.
d.
Wax
Maxn
1990
1970
1980
1970
I960
1990
—— P| Rural Population
... P2 City Population
...
e.
2C30
(990
i960
1970
1980
—— L4 City Land
-— S4 City Structure
f.
1990
2000
�184
Figure 5
INCREASING AID
Mes-
MOK
1980
1080
1970
1980
1990
W, War Effort
—— L| Mangrove Land
A
—
U.S. Aid
S, Mangrove Structure
a.
b.
Maxl
I9SO
2000
Man
ISflO
»TO
IS80
1970
2000
ICSO
1980
2000
—-— L2 Forest Land
Ls Agricultural Land
...
$3 Agricultural Structure
$2 Forsst Structure*
e.
d.
Max
I960
liSO
l®30
—- Pi Rural Population
.. P2 city Population
.
e.
£000
1060
1920
1970
—•** L4 City Land
-— 34 City Structure
f.
£000
�185
Figure 6
Max
DECREASING
Max
(950
mo
rT
1970
l«80
1990
2000
ISSO
I960
• W, War Effort
A U.S Aid
1970
AID
1830
1990
L|
Mangrove Land
S|
2000
Mangrove Structure
a.
b.
Max
Max
(930
I860
1970
1200
1930
2000
1950
19*60
1970
IS80
1990
2000
.2 Forest Land
LS
Agricultural Land
i2 Forest Structure
83
Agricultural Structure
d.
c.
Max
1930
Max
I960
»70 " 1930
1890
PI Rural Population
P2 City Populate
2000
I93C '
I860
!970 ' I960
—— I.*
1990 " 2000
City Land
S 4 City Structure
f.
�186
U.S. Aid Ordering
1965
1966
1967
1968
1969
1970
202.3
478.9
271.6
295.5
206,7
369.4
265
406
356
370
477
504
(US $ millions)
500400 H
300 H
200
"ANNUAL STATISTICAL
100 H
BULLETIN NO. 14"
0
6465 66 67 63 69 70
Official Aid
U.S. War Appropriations
1965
1966
1967
1968
1969
1970
100
6,000
18,000
23,000
22,000
17,000
(US $ millions)
25,000'
20,0001500010,000IMPACT OF
5000VIETNAM WAR"
0
64 €5 66 67 68 69 70
Fuel to War Effort (millions of barrels) (partial figures)
1965
1966
1967
1968
73,881
112,995
146,697
173,766*
150-
100-
"REPORT ON
WAR IN VIETNAM"
50i
0
64 65 66 67 68 69 70
Military
1965
1966
1967
1968
Goods (thousands of tons) (partial figures)
3,300*
7,280
11,800*
14,340
1263.
i month figures were given
for these years, so figure was
doubled for year total.
/
/
/
9-
/
/
"REPORT ON
WAR IN VIETNAM"
64 65 68 67 68 69 70
�187
Notes to Figures 4, 5, 6
Maximum values for each component are as follows:
Wj, War Effort - 2.5 billion $
Aj_t U.S. Aid - 1 billion ?
L , Mangrove land - 3.3 X 10 acres
S,, Mangrove structure - 2.1 X lO
kg
t«2i Forest land - 3.3 X 107 acras
S,, Forest structure - 16.1 X 1018 kg
13, Agriculture land - 3.27 X 107 acres
83, Agriculture Structure - 1.1 X 10lc kg
L,, Urban land - 3.3 X 107 acres
S. Urban structure - 6.8 X 1011 kg
P^ Rura.l Population - 11. 0 X 107
P2 Urban Population - 18.3 X 106
�188
reach the level of productivity exhibited at the beginning of the simulation
run. Flows of Aid have little effect on the system, and eve-> when tripled no
perceivable difference was noted. The transfer coefficient for the flow
returning to forest land from bar® land as a result of U.S. Aid (K.; is extremely small accounting for the lack of effect.
The agricultural systems (Fig. Ad) show the greatest change due to the
disruption by war, decreases in the rural population, and increased urban demand.
In the first: simulation production of the system after disruption does not
recover to the initial level.
Increased aid in the second simulation provides
the energy necessary to increase agricultural production to a level slightly
higher than the initial, by transferring more land back into production and
increasing the movement of refugees back to the rural areas.
In the third simu-
lation, by cutting off aid, production remains lower than the level obtained in
Simulation 1, as might be expected.
Consequences of the population shifts (Fig. 4e) are felt throughout the
system and are very important flows regarding the overall stability of the
country. In the first simulation the movement of the rural population to the
cities puts additional burdens on the entire system. Manipulation of this flew
caused extreme changes in moat compartments. If the rate of movement to the
human settlements was decreased all components exhibited faster recovery rates,
and the loss of agriculture production was not aa great. If the rate of movement was increased the opposite occurred. This "system sensitivity" to the
movement of the populations begins to indicate the extent to which the country's
stability io aggravated by the secondary effects of the refugee problem. In
the second nimulation, movement back to the rural areas is facilitated by an
increased flow of agricultural land back int" production. In the third simulation, diminishing aid has little effect on the return of the rural population.
The human settlements (Fig. 4f), while showing smaller visible changes, are
�189
interesting in view of the time delay involved In the build up of city structure
(S ) following the increased urban expansion ( ^ . By the year 1970, increases
L)
are apparent in city land. However, due to shortages of materials and energies,
and pressure from an increased population, a time lag of ten ( 0 years is re1)
quired before the materials and energies are available for growth of city structure.
Recovery to the initial level does occur by the year 2000. This does not meet the
demands of the larger population.
Increasing aid in simulation 2 meets these
demands easily. The increase in city structure in this case begins to show a
run-way growth, possibly an undesirable consequence. In the third simulation
decreased aid prolongs the time delay and reduces the final structure value.
Overall Perspective
Consequences of the war in Vietnam are difficult to evaluate directly. The
immediate effects of the disordering energies 1-ave caused a 3.1% disruption of
the 6 year cumulative energy budget (1965-1970) of the country. The herbicide
program accounts for nearly half this disruption: an interesting consequence,
indicating the high amplifier value of the relatively low energetic cost of herbi, cides.
Simulation of the Wa»- Stress Model reveals additional stresses and indictees
that depending on the new energies added, by the year 2000, the country of South
Vietnam may still be showing the consequences of a 6 year war in tha 1960'e. It
is Important to note here that the recovery of the system depends on continued
(and possibly increased) flows of United States Aid (a situation which may be
unrealistic in light of increased energy shortages being felt throughout the U.S.)
Delays in ending the present level of conflict may cause delays and reductions in the recovery rate of order In the country.
A« long as needed, materials and
energies ar.e diverted from the job of reconstruction to that of fighting brush
wars with the Viet Cong And North Vietnamese, rogrowth of the country way be delayed.
Stability in any system is related to the diversity of normal occupations and com-
�190
ponento; and as suggested earlier, continued conflict may result in maintaining
a low diversity and thus a low suceeseional state. On the other hand, the system
may be developing special adaptations to War Stress Energies so that they are
not so destructive to the overall processes.
•
,
Other models simulated for th® country of South Vietnam at war suggest a
regrowth and in some instances inczesseA productivity; and parallels have been
drawn between South Vietnam and the countries of Germany and Japan after the
second World War. However, the reordering and recovery of Germany and Japan were
accomplished with great expenditure of outside "ordering energy" during a time
of increasing fosail fuel availability and utilization. The same rapid reordering
of South Vietnam may be unrealistic in view of increased demand and decreased
availability of fossil fuel energies. The W«ss Stress Molei indicates that without
increased a:ld the reordering may take many years more than intuitively apparent.
�m
APPENDIX A
Gene r a 1 Notes on
The conversion from $ (American) to kcal was calculated as roughly 1A.OJO
kcal/dollar. (This figure was calculated in the same manner as Odum, 1971.)
The total fossil fuel budget and hydro electric production was divided by the
GNP of the country.
The most complete figures were for the year 1966.
The
figures for fossil fuels were as follows:
Fossil Fuel Type
Metric Tons Imported
kcal/g
kcal x 1010
Petroleum
25,647
12
30.72
166
11
.8
1
Gasoline
203,920
12
244.68
Kerosene
256,337
10
256.34
Gas oil
67,810
10
67.81
Fuel oil
562,595
10
562.60
Aviation gas
Natural gas
Petroleum coke
6,080
820
12.5
7.60
7
.51
TOTAL 1170.50 X 1010 kcal/year
The figures of metric torn imported ure from "Vietnam Statistical Yearbook
1 7 " Hydro electric production was calculated from a map showing location,
90.
type and capacity of hyrdo electric generating plants found in "Vietnam Subject
Index Maps" minimum value for each plant was used (see table below). The total
kcal/yr energy budget was 2750.0 X 1010. This was divided by the GNP of the
country for the year 1966, 2.0 X 109 dollars, ("Impact of the Vietnam War").
The figure obtained was 13,660.6 kcal/dollar.
,
�192
3 power plants 9 10,000 - 50,000 kw.
3 <? 30,000 - 90,000 kw
2 power plants @ 50,000 - above kw
210,000 kw - 1.84 X 1010
2 @ 60,000 • 120,000 kw
210,000 kw
kwh/yr ( . 0 X 102 kcal/kwh) - 15.80 X 1012 kcal/yr
86
TOTAL 2750 x 1010 Jccal/vear
Q! Land area in the cities - 2.47 X 10 acres is based on 100 Km2 as stated
by Meselson £& si- ( 9 0 . This figure is for 1970, however, it includes
17)
only major urbcn areas, so It is felt that it is a good reflection of all
urban areas including villages + hamlets in 1965 - these small urban systems
are not classically held aa urban areas but generall as rural; hc;ever,
because of the "undeveloped" status of the country and the role of the
village 4- hamlet as major elements in the hierarchy of the governmental
structure; they are included in urban areas. This figure represents .0582
of the land area of the country.
.
0.2 Goods in_Country - This storage represents the combination of imports and
goods produced within the country minus exports. Imports and exports were
easy figures ot obtain from a number of poublicatlons including "annual
statistical bulletin" and "Vietnam Statistical Yearbook, 1970" and industrial production were obtained from "Annual Statistical Bulletin No. 11".
This data does rot include enterprises whose 1962 output was less than
2,000,000 $VN in value,, Thus, much of Vietnam's industrial production la
excluded e.g. salt mining, quarrying, furniture making, printing, and handicraft production.
For 1965, the goods within the country was calculated
as 4.17 X 10* metric tons.
. . ,,
nVi.,
, . , .,,,-.» ,,:.;i.-,. j.-..v.; ,.<„> ',?,,•:• •.-,:..-.}
.,;
Q3 Capital in the City - Capital in the city Is used here to mean the money
supply that is available throughout any year. This figure was computed from
a table "Money Supply" in billions of plasters from the Annual Statistical
�'93
Bulletin No. 11 by dividing by the exchange rate of 118 plasters to th«?
American dollar. Two figures are given, the year end value and the amorr.t
available at the beginning of the year. For 1965 the year end value was
$393.2 million and the amount available at the beginning of the year was
$232.2 million.
-
'
' . , • . . . ; ; . .••:•.-•-•. -,_••..-.-' ,v -.••;- - - ; ,.
Q^ Land area .in agriculture - The land area in agriculture is all land in
Vietnam under cultivation Vietnam Statistical Yearbook j 9 0 Table 14—
,7.
Agricultural crops: planted area and production, 1960-1969. The planted
area for each major crop was totaled and the agricultural land area that
had been defoliated was added to this figure as was the land area bombed.
The total land area during 1965 that was in agriculture production was
7.308 X 106 acres.
:
- : '•
'
- . - ! • . . . !- • • • . ! •
:•••.-
-.
.,-
,. ••.. .
:.
:••'- ..V.; ). , . ....
0.5 Agriculture Structure - As used here agriculture structure means the yield
in kgm of the land area in agriculture.
The year end total yield was ob-
tained from Vietnam Statistleal Yearbook 1970 as was the land area. The
total yield and planted areas were 705.8 X 107 kgm and 7.238 X 106 acres
respectively. By dividing yield by planted area the yield per acre was obtained
(975.1 kgm/acre)*. This then was multiplied by the planted area (total before herbicides, spray, and bombing) to obtain maximum yield value of 7126.0
X 106 kgm.
Qfi Land Area in Military Bases - This value has been requested from the Department of the Defense but to date has not been received. For lack of any
better figure this value was estimated by assuming that for each member of
* This yield/acre Is approximately 1/6 that calculated for Florida which
has a yield 5,985 kgm/acre for all crops, however, Vietnam's growing season
is shorter due to monsoon weather, and they do not have a fossil fuel subsidized agricultural system to the extent of that of the U.S.
.
�194
the combined U.S. and S.V.N. armed forces a minimum of 1.5 acres* are
required to provide housing, necessary services, and storage for them and
their support equipment.
Q? Land area in Forests - Meselson et aj. ( 9 0 estimate forest area to be
17)
100,OoO km2. Included under the designation "forest" are all lands with
trees whose crowns cover more than twenty percent of the area. This estimate is based on low resolution aerial photography and on U.S. Army terrain
difficulty maps. The forestry services for the French colonial government
estimated the total area of economically valuable hard wood forests at
50,000 km2 leaving out forests that were badly degraded, very young, or
located on partially inacceosible mountain terrain. A value of 75,000 km2
was estimated from a vegetation map published by the government of Vietnam.
This value was chosen as a rough approximation of the forest area at the
beginning of 1965, because the greatest expenditure of hevbidies in Vietnam
has been on fairly mature tropical hardwood forest (Meselson, j£t al., 1 7 )
90.
In acres the total forest area for 1965 is 18.5 X 1 °
0.
Qg Upland Fornst Structure - Rodin (1967) stated standing crop for subtropical
hard wood forest to be 4.1 X 10^ g/m2 and that for rain forest 5.0 X 10 .
Since a large majority of the forests of Vietnam are of the moist forest
type and the next most frequent type is secondary forests, a biomass of
*It is assumed that a military base has the same basic system functions
and flows as the urban system (with some specialized functions in terms of
equipment storage, and control mechanisms.) All calculations using urban systems in Southwest Florida indicate for each urban Inhabitant .85 acres are
required to house and provide them with necessary services. Due to the higher
energy flows of the military system aa compared to the urban system and an
accompanying increase In structure, It can be assumed that larger amounts of
land will be necessary to accommodate the system components. Thus, an increase
of 75X in land area over than required to house and maintain services for military
personnel was estimated.
�195
3.5 X 10* g/m was used.
The tropical moist forest covers approximately 70-75% of the forest a^ea
while the secondary forest make up the remaining 25-30% with small eroas of
semi-deciduous and dlpterocarp dry forests.
(Estimates from General Forest
Map, Government of South Vietnam.)
The total biomass or standing crop for 1965 was calculated by multiplylrg
the biomaas per sq. meter by the area of forests ( 8 5 X 106 X 4047 - 2.62 X
1.
lOU/m^O.S X 10* g/m2 X 2.62 X 10n/m2) - 9.17 X 1018 kg of biomass.
2
0-9 Dead wood (DeadL_fore_9_t_ structure) - Prior to 1965, 438 km of forest land had
been sprayed (Herbicide Assessment Commission of the American Association for
the Advancement of Science, Background material relevant to presentations
at the 1370 annual meeting of the AAAS, Chicago, I1L, (Dec. 29, 1970) p. 14.)
"Some estimates indicate that one out of every eight trees is killed by a
ringle spraying and that 50 tj 80 percent are killed in areas where more than
one spraying has occured." (same reference). Therefore, a low estimate of
20% killed in those areas sprayed has been made. This estimate takes into
account the 10% to 12.5% killed after the first spray and allows for an
additional 10% due to scattered second sprayings. The amount of dead wood
q
for 1965 was calculated to be 3.06 X 10 kg, end was figured in the following
manner:
( 3 k»2)(106 m/km2)(3.5 X 104 g/m2)(10~3 kg/g)(.20) - 3.06 X 109 kg.
48
°-10 Bare Land - Is those areas that have had the standing crop
markedly reduced;
it does not necessarily mean top soil that is exposed, although in some cases
it is, but merely those areas throughout SVN that have had the standing crop
removed and are in various stages of succession.
In the three years prior
to 1965 458 km2 of forests and 46 km2 of agricultural lands had been sprayed
(impact of Viet Nam War, 19/1). Of the forests sprayed 20 Km2 of the 458 km2
�196
was mangrove.* Calculating the amount of bare land that had accumulated
by 1965 was done by assuming first: that 90% of the mangrove land sprayed
was still bare based on statements by Tschirley (1969) that mangroves are
particularly susceptible to defoliants and that one application at the
normal rate employed in Vietnam is sufficient to kill.most of the trees.
And possibly because of lost seed source there has been little or no
reestablishment of the forest; second, that 17% of the upland forests
sprayed prior to 1965 are otill bare land calculated in the following manner:
it was assumed that of the area sprayed a 20% kill was achieved with one
application of defoliants in the upland forests. Of this 20% at the end of
one year 2.8% has recovered or bare lend is now 19.44%. At the end of 2
years 8.8% hae recovered or 18.24% bare land; at the end of 3 years 13.4%
of the 20% has recovered or 17.32% in still bare land. Third, that agriculture land sprayed is 90% defoliated for that year, assuming that some land
might be replanted within the year and be replanted the following year with
a 50% overlap.
In other words 50% of that land sprayed in 1964 is still bare
at the end of 1965 and 1/2 of that land will be replanted. The remaining
1/2 will not be replanted due to the abandonment of villages and hamlets
because of the resettlement of the people who were in conflict areas. Fourth,
that forest and agricultural structure destroyed by bombing is calculated
in the same manner. However, there is no data available for the years prior
to 1965. Thus, it was assumed there was none.
.... ;. .. , - .
*This area was measured of official DOD spray run maps at a scale of
1:1,000,000. At this scale it is difficult to determine exact areas, however,
these maps are computer drawn and give an accurate Indication of where the spraying occurred. 3 different widths of Individual spray were observed from these
maps; these were assumed to be 25, 150, and 225 meters wide.
�197
The value of bare land Is as follows:
forest sprayed in 1962
20 km2
(13.4%)
2.7 km2
1963
100 km2
(82%
1.4)
18.2 km2
1964
346 km2
(942
1.4)
61.6 km2
Mangrove sprayed prior to 1965
20 loa2
(0)
9%
18.0 km2
Agriculture sprayed in 1964
42 km2
(0)
5%
21
615 km2
(0)
2%
Mangrove sprayed in 1965
17 tan2
(0)
9%
15.3 km2
Agriculture sprayed in 1965
267 km2
(0)
9%
240.3 km2
Forest sprayed in 1965
TOTAL
km2
123 km2
500.1 km2
\,, Seeded land in mangroves - The total area of mangroves in South Vietnam
has been estimated as 2,800 km2 ( 6 1 X 10° acres)(Meselson ££ &U 1970) and
.9
Tschirley, 1 6 ) 20 km2 had been sprayed prior to 1965 giving an area of
99.
2,780 km2 ( 6 7 X 106 acres.)
.8
Mangrove forest structure - This structure index includes only woody stem
blomass and has been estimated &s 5,000 g/tn2 (Golley £g ajL., 1962) and between
4,000 g/ra2 and 6,000 g/m2 by Banijubuta^a ( 9 7 . The value of 5,000 g/ra2
15)
was used, thus, for 1965 (2,800 km2)(106m2/km2)(5000 g/m2) - 14,000 X 106 kg.
Dead wood (mangrove) - There was 20 km (20 X 106m) sprayed prior to 1965 and
a 90% kill has been estimated , thus, ( 0 0 X 106/m2)(.90)(5000 g/m2) • 90.0
2.
10" kg as stated by Tschirley ( 9 9 . There seems to be very little apparent
16)
recovery or reestablishment after one spraying*, However, if there is, the 90%
kill is a conservative estimate and would account for any reestablishment.
Wood cutters - The number of people engaged in wood cutting is impossible to
count. Every refugee is a potential wood cutter cecause it provides a readily
�198
available income source.
QIC Viet Cong^ M.^ietnamese troops in country - Very difficult to obtain, finally found a reference in "Aviation V/esk and Space Technology", Jan. 3, 1966.
"Present Viet Cong (strength: (19fG)
80-90,000 regu.lt.ir t -oops
100,000 guerillas
40,000 political activists"
This is an Increase of 85,000 over May 1965 estimates of 38,000 - 46,000
regulars and 100,000 irregulars by Pentagon. " Thus, a figure of 140,000
men was used for 1965; 40,000 regulars and 100,000 irregulars.
0-16 •Land area in bomb_crater8_ - Very difficult figure to obtain; there are no
estimates or data available as yet on the size of craters produced per pound
of TNI or for different size bombs, much leas how many of different size bombs
ha >. been dropped, "...there are two variables that make estimates almost
Impossible, type of fuseing and type of terrain (soil) that bomb is dropped
on. (There are) H&ny types of fuseing devices and each will produce different
results, and if fused to explode on contact with soil, and explodes on contact
with trees Instead, a different result is obtained."
(Personal interview
commander, Univ. of Fla. AFROTC). We therefore have relied on two sources
for estimates on the size of craters. Aviation Week and Space Technology,
Nov. 29, 1965, p. 18 - "When delayed fusing is used craters on the ground are
25-30 feet deep and 50 feet wide at the top with a blow down of 150 feet in
diameter in heavy undergrowth in Iron Triangle area with soft, loamy soil.
Westing (1972) states from personal observation that the craters were "20 to
40 feet across and 5 to 20 feet deep." He uses an average diameter of 30 feet
and depth of 15 feet. We have therefore relied on the following figures:
craters 30 feet in diameter a ' 20 feet deep with a blow down of 100 feet in
n'
diameter.
�199
To estimate the number of craters, it was assumed that 75% of all air
munitions, expended were 500 pound botnbn capable of producing a crater as
described above.
•
'' •'
The air munitions expended in 1965 was 315,000 tons (see "Impact of
the Vietnam War), 75Z of this figure is 236,250 tons ( , 0 Ibs/ton) 200
945,000 bombs capable of producing a 706.5 aq. feet crater and a bare land
area of 7,100 »q. ft., thus the area of craters ( 0 . sq. ft.)(9.45 X 105)765
667,^2,500 sq. ft. of craters (2.3 X 10~5 acree/sq. ft.) - 15,358 acres of
craters.
Z§28i® ~ Th® "Annual Statistical Bulletin" gives the total population for
South Vietnam in 1965 as 15,921,000. However, it states "...all population
figures for Vietnam should be regarded as estimates or gross approximations.
The reliability of data for cities is significantly better than for rural
areas. Internal security requirement!? prescribe that each head of household
must register himself and all those residing with him at a local police station and keep this registration up to date. It is these records which local
authorities draw upon when reporting population data to the National Institute
of Statistics. It is believed that the 1960 figures represent a fairly accurate estimate of population. With the deterioration of security, registration data became incomplete and the NIS has deemed it advisable, beginning in
1961-1967 figures represent extrapolations of 2.5X per year on the 1960 figures.
�200
Flow 1.
Incoming Energies to city.
A value of $252.8 million (US) was estimated for 1965 by consulting Table
9 in "Annual Statistical Bulletin No. 14" import arrivals by Major Commodity.
Those commodities that were clearly consumer, goods were added along with petroleum products, those chemicals not used in agriculture, textile industry goods,
machinery and vehicles that were clearly not agriculture oriented, pulp and
paper producto and 66% of the commodity labeled "other" (the remaining 34% was
"ivided between agriculture and urban development energies.)
Those commodities
that were clearly for the city were assigned to either agriculture or urban
development or both; by. assuming 4% to agriculture and 30% to urban development.
Based on finding e percentage that the known quantities of each was of the total,
and the heading others was divided in the following this dollar value, $257.8
million U.S., was then multiplied by the. current conversion factor of l<t,OCO kcal/$
(see general notes) to obtain 3.54 X 1012 kcal/97. This is the energetic value
of imports to the city for 1965.
Flow 2. Energies to Agriculture.
See Flow 1 for explanation.
This value, $18.0 million U.S. for 1965 was
multiplied by current conversion factor If 14,000 kcal/dollar giving 2.52 X 1011
kcal/yr.
_.
. .. : .
: . . - , • ..... . • • . , ,
. , ,.
•
Flow 3. Energies for Urban Development.
See explanation for Flow 1 for calculation of value. $117-8 million U.S.
( 4 0 0 kcal/dollar) - 1.65 X 1012kcal/yr for 1965.
1,0
Flow 4. Bombs Expended.
As described in the explanation for Q16 land area in bombs craters, to estimate the number of bombs it was assumed that 75% of all air munitions expended
were 500 pound bombs.
The air munitions expended in 1965 was 315,000 tons (Input of Vietnam War)
�201
(.75) • 236,000 tons. In reality this percentage represents only 37.5% of the
total munitions (land, sea, air) expended, therefore, a very conservative estimate.
Flow 5. Energy of Rome plows to scrape lend.
In 1965 this value is 0 (zero). Rome plowing was started in Vietnam in
1968.
i
'
Flow 6. Herbicides sprayed on agricultural land.
This figure was calculated by multiplying the area sprayed by the spraying
rate of 3 gallons per acre*. For 1965 the cropland sprayed was 65,949 acree*.
This multiplied by 3 gal per acre gives: 197,847 gallons of herbicides.
Flow 7. Herbicides sprayed on upland forests.
Calculated by multiplying the area of forest sprayed (found in "Impact of
the Vietnam War') as total forest areas sprayed. This figure represents all
forests Including mangrove; thus, mangrove sprayed were subtracted from total
forest areas by the application rate of 3 gal/acre. For 1965, 151,831 acres
of forest had been sprayed which would inquire 455,493 gallons of herbicide.
Flow 8. Herbicides sprayed on mangroves. .
Calculated by multiplying the land area of mangroves that were sprayed by
the application rate of 3 gal/acre. Thus, for 1965, 3,779 acres were sprayed
using 11,337 gallons of herbicide.
Flow 9. V. C. and N. Vietnamese in active military engagements.
Assuming that there were 140,000 V.C. and KVN troops in South Vietaam in
1965**and that these were broken into the following percentage groups as follows
^Herbicide assessment coannisaior. for the AAAS. Background material relevant
to Presentations at the 1970 annual meeting of the AAAS, Chicago, 111., Dec. 29,
1970. p. 14.
**Aviatlon Week and Space Technology, January 3/
1966.
�202
44% guerillas, 33.3% political activists, and 17.7% regular troops.* And
assuming that regular troops and guerillas are both active in military engagements then 67.7% of the 140,000 troops or t'f.,380 troops are in active military
engagements.
Flow 10. City Land Bombed.
A difficult estimate to make - this figure was derived by assuming that
all bombing done was evenly distributed throughout the country and then calculating the % of the total land area of the country that is in city land. This
was found to be .058% and multiplying this times cratered area
of 15,358
acres gives 890.7 acres of city land bombed. The reason for ualng cratered
land instead of the cleared land as in agriculture and forest lam' bombed
(see Flows 12,13) is simply because of the structural differences. City structure
is exceedingly more difficult to move so it was assumed that only the actual
cratered area was cleared. Again this estimate is exceptionally conservative
on two counts. First, it seems entirely possible that more than .058% of all
bombs dropped on South Vietnam were in citieu and, second, assuming that the only
area of destruction for each bomb was that of the cratered area is very naive at
best; this figure could range as high as 10 times this amount. However, working
with only publishel information «tirl not having access to certain classified information it is felt that conservative estimate is better than one that might
be subject of much debate.
Flow 11. People killed.
"The Senate Refugee Subcommittee estimated that there have been 1,050,000
civilian casualties in Vietnam between early 1965 and early 1971, including
about 325,000 killed." (Impact of the Vietnam War). An estimate of 50,000
*Based oa reported estimates of 100,000 guerillas, 80-90,000 regular troops,
and 40,000 political activists for the year 1966 by Pentagon.
�20j
was assumed by equating war deaths to the relative scale of war year by year,
1965-1970.
Flow 12. Agriculture Land Boirbed.
Again assuming that bombing was evenly distributed throughout the country,
and calculating the % of the land area that is agricultural land (17.23%) and
multiplying this times the total cleared area of 169,000 acres* gives 31,100
acres of agriculture bombed and cleared. This area will be returned to agricultural production within the year, however, so it was felt a more accurate
assessment of damage to agriculture land would be in the amount of land that
was left in craters and therefore unusable for agriculture.
This was found
by multiplying the total cratered area, 15,358** acres by 17.23% given an area
of 2,672 acres in craters.
Flow 13. Upland Forest Land Bombed.
Again assuming that bombing was evenly distributed throughout the country
and calculating the % of land area that is upland forest (58.8%) and multiplying
this times the total cleared <rea (biowdt*wn) caused by bombs, 169,000 acres (.179
acres*./bomb X 555,700 bombs gives 99,732 acres bombed and in bare land for the
year. The amount of land in craters was found by multiplying 58.8% times the
area of total craters 15,358 acres^ giving 9,030 acre® in craters.
Flow 14. Craters in Natural Succession.
This is a very difficult number to Judge - the actual crater in most cases
does not disappear from the landscape
but to some extent will remain a permanent
™*Based as a~flow down of 100 ft. diameter (Aviation Week ana Space Tech, 11/29/65)
**Basca a crater size of 3 ft. in diameter (Westing, 1972) and (Aviation Wk.
and Space Tech, Nov. 29, 1965.)
fcBased on a blowdown of 100 ft. in diameter from (Aviation Wk. & Space Tech,
Nov. 29, 1965.)
$|Basecl on a crater size of 30 ft. in diameter, (Westing 1972) (Aviation Wk &
Space Technology, No. 29, 1965.)
�204
feature (Orians 1 7 ) However, there Is noticeable filling from soil wash
90.
down, and in some cases aquatic systems (where the crater remains wet year
around), are present after approximately one year (Pfeiffer, 1971). Where
these craters are in agricultural areas they become practically unusable except
for irrigation purposes; there also have been some reports that craters have
been used for fish ponds in forest regions.
The return to its former stPte
is a slow process indeed, starting with some grasses djmperatfl) and eventually
supporting r.amc woody brush, vines and bamboo. It is therefore assumed that
the successional rate of craters is approximately .01% for lack of any real
data. This means that .001% per year of existing craters are retained to this
natural productivity or .001 X 15,358 acres of craters - 15.36 acres in 1965-66
were returned to their natural state, or some other productive state useful to
nan.
Flow 15. Agriculture Land itoae Plowed.
This value is zero ( ) Rome plowing was started in early 1968.
0;
However,
In later users this was calculated in the following manner.
Flow 16. Forest Land Rome Plowed.
Again this value for 1965 is Zero ( ) started in 1968, however, in later
0;
years, this value was calculated in the following manner.
Flow 17. Forest Land Herbicided.
In 1965 155,610 acres of forest land were sprayed ("Impact of Viet Nam
War"), this value includes mangrove land sprayed, thua, from official department
of Defense Spray Flight overlays it was determined that 3,779 acres of mangrove
was sprayed leaving a total of 151,831 acres of upland forest sprayed.
Flow 18. Agriculture Land! Herbicided.
Agriculture land area by year that has been sprayed: 90% was assumed to
be defoliated and unusable for the entire year for several reasons. First,
�205
because farmers may have abandoned field; second, defoliation occurring late
in the frowing season, and third, to compensate for any error due to second
applications in certain areas. Thus, for 1965 - 6 6 X 10* acres)(90%) - 5.94
(.0
A
X 10
acres.
Flow 19. Mangrove Land Herbicided.
This figure was measured off of official Department of Defense Spray Flight
overlays, (see Qio-Bareland for explanation.) Area was 3,779 acres.
Flow 20. Bareland in Natural Succession.
Of the total bareland In storage in any one year, the flow back into forest
land by natural succession is calculated in the following mannerJof the forest
land defoliated that year 0.0% returns to forest, of the forest land defoliated
the year before (2 yrs previous) 2.8% returns to forest of that defoliated 3 yrs
previous 8.8% returns to forest, of that defoliated 4 yrs previous 13.4% returns
and that 5 yrs pervious 17% returns, of that 6 yrs previous 72.8% returns; it
was also assumed that 10% of agriculture land sprayed started into succession
because of abandonment. The bare land in natural succession for 1965 was as
follows.
1962 Forest Spray total 20 lea2 ( 0 killed) - 4 km* X 13.4% - .54 km2
2%
1963 Forest Spray total 100 km2 (20% killed) - 20 km2 X 8.8% - 1.76 km2
1964 Forest Spray total 338 km2 ( 20% killed) - 67.6 km2 X 2.8% - 1.89 km2
1965 Forest Spray total 630 km2 ( 0 killed) - 126 km2 X 0% - o
2%
1965 Agriculture spray 267 km2 (20% killed) « 240.3 km2 X10%- 24.0 km2
Flow 21. Bare Mangrove Land Returning to Seeded.
It was assumed that .05% of the total in any one year of bare mangrove land
*\
was returning to seeded. Tims, for 1965 there was 51.3 knr of mangrove land bare
and in that year .05% of .026 km2 ( . 4 acres) returned to seeded.
63
�206
Flow 22. Bare Land Returning to Agriculture.
Here it is assumed that 85% of agricultural land killed remains fallow for
one year only, then it is returned to planted land, and that 5% of bare forest
land is reclained as agriculture.
10,374 acres sprayed in 1964 (£15%) - 8,817.9
113,126 acres sprayed in 1965 <'5%) -J^SSi?
1,7."
4442
Flows 23, 25, 26, and 27. "Land" converted to Urban Land.
It has been estimated by A.I.D. that the urban populations of South Viet
Nam have grown from 15 to 30 percent, and that the populations of Saigon and
Oanang together swelled by about 1 million persons In 5 years.* It is assumed
that urban population hae grown by 30 percent during the 6 year period (1965-70)
at a constant race of 5% per year. It is further assumed that urban structure
growth during this tirae Is proportional to population growth. Therefore, if the
4
urban land area was 2.47 X 10 acres, then 5% growth per year will add 1,235 acres
per year to Soath Vietnam urban areas.
Flow 28. Agriculture Structure Bombed.
As calculated for Flow 12, agriculture alnd boaibed, 31,100 acres were cleared
by bombing in 1965. The structure par acre was calculated as 975.1 kgm/acre.
Thus, the structure destroyed is calculated aa the number of acres cleared multiplied by the structure per acre.
For 1965: ( 1 1 0 acres)(975.1 kg/acre) - 3.03 X 107 kg.
3,0
Flow 29. Forest Structure Bombed.
t
2
Calculated in the same wanner aa Flow 28, using 3.5 X 10* g/ra (see explanation for Qg) as the structure, and 99,732 acres as the area cleared (see explanation for Flow 13).
1
For 1965 ( . X 104 g/s»2)(99,732 acres)(4047 m2/acre) - 1.41 X 10*0 kg.
35
• :
I
�207
Flow 30. Agriculture Structure Rome Plowed.
Plowed area multiplied by structure/acre (975.1 kg/acre). For 1965 -0Rome plowing was started in 1968.
Flow 31. Forest Structure Rome Plowed.
4 2
2
Area cleared multiplied by structure/acre ( . X 10 g/ra)(4047 ns /acre)
35
- 1.42 X 105 kg/acre.
For 1965 -0- Rome plowing started in 1968.
Flow 32. Forest Structure Lost Due to Defoliation.
Area sprayed (151,831 acres)(aee Flow 17) multiplied by 20% kill based on
explanation for 0.9. Based on an initial standing crop of 3.5 X 10 g/a2, the
structure lost can be calculated by multiplying the area killed by standing crop.
For 1965 - ( 5 , 3 ) 2 % ( 0 7 ( . X 101 kg/a2) « 4.31 X 109 kg.
1181(0)44)35
Flow 33. Agriculture Structure Defoliated.
The area sprayed times 90% (sec explanation for QJQ) multiplied by standing
crops of 917 kg/acre.
For 1963 - 65,949 ( 9 ) 9 7 X 102) - 5.93 X 107 kg.
.0(.1
Flow 34. Mangrove Structure Defoliated.
Area of mangroves sprayed multiplied by 90% (representing the kill rate)
and this multiplied by the figure for otanding crop.
For 1965 (3779 acreo)(4047 ja2/aern)(90%)(5.0 X 101fcg/ra2)- 6.9 X 108 kg.
Flow 35. Energies of woodcutters to cut wood.
This value is derived 'from the man value for total energy expenditures of
5.908 kcal pet minute given by Bartung and Easts ( 9 8 . Assuming that a wood16)
cutter's work day is 10 hours, his expandlture is then 5.908 kcal/min X 360 rain. 2160 kcal/day.
�208
Flow 36. Forest Structure Cut by Wood Cutters.
Data not available
Flow 37. Dead Forest Wood Cut by Wood Cutters.
Data not available
Flow 38. Mapgrove Structure Cut by Wood Cuttsrs.
Data not available
Flow 39. Dead Mangrove Wood cut by Wood Cutters.
Data not available
Flow 40. Goods bought by Wood Cutters.
Data not available
Flow 41. Goods Exported from South Vietnam.
From the "Vietnam Statistical Yearbook," p. 192.
Weight of imports and
exports by country - the total for 1965 waa 1.77 X 105ffiatrlctons. This value
is derived from tha sale of licenses, so it may of off as much aa 10% either way.
�209
Flow 42. Wood for Charcoal and Lumber to tha City.
Data not available
Flor 43. Natural Energise to Natural Systems.
The sum of the natural potential energies of: Rivers (644 X 1012 kcal/yr), tides
(152 X 1012 kcal/yr), rain as runoff (119 X 1012), thermal heating (1680 X 1012 kcal/yr).
wind absorption (52 X 1 ) 2 kcal/yr), and the chemical potential energy as gross
(1
photosynthesis ecological systems (1312 X 1012 kcal/yr)'. Total for 1965 is 3959 X iO12
kcal/vr«
Flow 44. Money to South Vietnam from Outolda Sources.
Obtained from "Annual Statistical Bulletin Ho. 14," p. 11. Table III Balance of Pyeiseats - 1962-1970 under official aid (sub-heading E). Total for
1965 $264.8 million. This value includes official grants, U.S. Govt. holdings
of disasters and official loans.
Flow 45. Money in exchange for outside energies.
Obtained from "Annual Statistical Bulletin Ho. 14," p. 9. Table I Foreign Trade Siatoary 1958 - 1970, under GVH financed imports for 1965, $85.4 million.
Flow 46. Money to Wood Cutters for Wood.
•Data not available
Flow 47. Money from Woodcutters to City in Exchange for Goods.
Data not available
�210
Flow 48. Money in Exchange for Exported Goods.
Obtained from "Annual Statistical Bulletin No. 14," p. 11. Table III
Balance of Payments - 1962-1970 under subheading A. Exports - 1965, $40.5 million.
Flow 49. NVN Sources.
Data not available.
Flow 50. Abandoned and Agriculture Land.
This value was calculated by knowing the land area that was supposed to
be in Agriculture for the following year and the amounts that flowed out during
the present year. In each case the land areas that were lost due to herbicides,
bombing and Rome plowing did not account for enough loss when compared to total
land planted in the following year (Vietnam Statistical Yearbook). Thus, some
land was lost to agriculture production due to movement of people off the land.
For 1965 - 5.73 X 10s acres.
�211
APPENDIX B
Calculation of Disordered Lands by Year
1.
In the 6 years Crow 1965 to 1970, 5,556,100 tons of air munitions
and 128,500 tons of sea munitions were expended (Impact of the Viet Nam
War, 1971). For the purposes of the Model and lack of sufficient data it
was assumed that 75% of the air munitions, only, were capable of producing craters equivalent to that of a 500 pound bomb (30* in diameter) with
a blow down (bleared area) of 100' in disaster (Pfeiffer, 1 7 ) This la
91.
probably en over estisiate of the number of 500 pound bombs dropped. However, whsn compared with all crater producing mraltions, the calculated
cratered asree la coeservatiTO at best. Xftih these calculations, then,
16,660,000 five hundred poyrtd boa&B vex® dropped on South V.iet Kara in these
6 years. This compares to 21 Mlllora estimated by Westing and Pfeiffer
(92.
17)
It was assumed that the bombing «s spread evenly throughout the
country; kaowiiig the ralative % of the total area of the country In each
of the fow major land use categories (city land .0582; agricultural land
17.23%; forost land 58.6%; mngrov® land 1.6%), the percentages of bombs
dropped in each of these can b@ calculated. The number of crater producing bosiba dropped in each land use category was then multiplied by the
cleared area produced by on® bomb (.181 acres). The following table shows
year by year totsln for boubs dropped and cleared area.
�YEAR
TOTAL BOMBS CITY LAM) AGRICULTURE
(Cleared
LAND (Cleared
Acrcs)xlOz
Acres)xlp4
FOREST LAND
(Cleared
Acres)
MAKGROVE LAND
(Acres)
1965
.96 X 106
1.2 X 102
2.9
10.0
.28
1966
1.5 X 1 6
0
2.4 X 102
4.8
16.5
.45
1967
2.8 X 106
3.2 X 102
8.8
30.0
.83
1968
6
4.3 X 10
4.7 X 102
13.4
46.0
1.26
1969
4.2 X 1 6
0
4.5 X 102
13.0
44.0
1.22
1970
2.9 X 106
3.3 X'102
9.1
31.0
.6
8
In the six years from 1965 through 1970 a total of 5,092,228 acres of
forest and 1,035,882 acres of cropland have been sprayed. Of the 5.1
million acres of forest sprayed 486,140 acres were mangroves*. The acres
of defoliated land for each lend us® category were calculated in the following manner:
•'
' •'
'• ''• ' • • • • ' • ' . • • ' • • '
••'•'• •'••/•:' .1 --^>;-..J
First, Agriculture land sprayed was asawaad to bo 90% iefoliated for
that year (aaoisiirag that some land might be replanted in that year) and the
following year the land was repeated. Thus, only one year's yield is lost.
Second, fotast land ar^a oprayed waa assumed to be 20% defoliated based on
statements from Meselson &$ ,^1• (1970) that "coma estimates Indicate that
ona out of evsry eight'OK ten tre&o i» killed by a single spraying and that
50 to 80 percent are killed in areas w&ers more than one spraying has occurred.
Therefore, a coneervative estimate of 20% killed waa assumed. Third, 90%
of Mangrove land eprayed w&s defoliated based on statements by Tschlrloy
*This area was JKeaaurod on official Dept. of Defense herbiciua spraytun maps, scale of 1:1,000,000; year by year totals for Mangrove land sprayed
are as follows: 1965 - 4700 acres; 1966 - 96,330 incraa; 1967 - 197,600 acres,
1968 - 68,666 acrea; 1969 - 90,155 acres; 1970 - 11,609 acres.
�213
(1969) that Mangroves are particularly susceptible to defoliants and that, one
application at the normal rate employed in Viet Nam is
ifficient to kill
most of the trees, and possibly because of loss of seed source there has
been little or no reestablishwant of the forest. The following table shows
the year by year total land herbicided and consequently removed from prod
uction from each of the land use categories.
YEAR TOTAL A1EA
HERBICIDED
10* acres
CITY LAHD AGRICULTURAL FOREST LAND MANGROVE LAND
AFFECTED LAJJD OUT OF
OUT OF
OUT OF
10* acres
10* acrea
10* acres
10* acres
A &MFWV &.fc.V*V
A *.W*fV
W A JbV**
1965
22.2
.*
6.5
3.0
.42
1966
84.3
1.5
10.2
13.0
9.6
1967
170.8
2.8
22.1
26.0
19.8
1968
133.1
2.6
6.4
24.0
6.9
1969
128.7
2.4
6.6
22.6
9.0
1970
25.3
.6
3.3
4.2
1.2
3. Rome Plowing Operation.
With available information 350,900 acres of forest land were estimated
as being cleared froa 1968 to 1970 by the Roma Plow Operation. Westing and
p
feif£er (1971 and 1972) have calculated tha area of plowed land at approxi-
mately 750,000 acres. They further estimate that of this'126,000 acres (were)
of prime timberlands accessible to lumbar operations, and 2,500 acres <jf
producing rubber trees." These figures do not Include prime timber land
that is not accessible to lumber mills but contributes to the total energy
budget of South Viet Mass. It was assumed Chat 350,000 acres of forests and 9 , 0
000
acres of agricultural land war* cleared by tha Rome Plow Operation. The land
areas cleared each year were assumed to b« equal, because it was assumed the
operation proceeded at a constant rate.
�214
YEAR
AGRICULTURE
LAND
FOREST
LAND
1968
3.00
11-66
1969
3.00
11.66
1970
3.00
11.66
�215
Appendix C
Imports
1965
1966
1967
1968
I9S9
1970
(thousands of metric tons)
2,159
2,423
2,269
2,387
3,469
3,358
3200-1
2800
"VIETNAM
STATISTICAL
YEARBOOK
1970"
2000
64 65 66 67 63 69 70
Fuel to South Vietnam (thous. metric tons) (partial data)
1966
1967
1966
IS69
1970
1.005 2.
0.862 2.
1.082 I .
1.128
1.210 I.**
1.2~
0.8
i."VIETNAM STATISTICAL YEARBOOK 1970"
0.4 H 2."Vi£TOAM STATISTICAL YEARBOOK
1967- 1968"
0
64 65 66 67 63 69 70
Money Spent for Goods © Fuel by Vietnam
(inport arrivals) (millions U.S. $)
t
1865
1966
I9S7
1970
387.7
607.2
744.0
707.5
837.7
715.1
800-
600 »
400 ~
200
"ANNUAL STATISTICAL
BULLETIN NO, 14"
64 65 66 67 63 69 70
Structure
Destroyed by War (thousands of acres)
1965
ISS6
1967
2.12
7.34
12.12
1969
1970
12.87
8.89
4.54
•X- Only eix won?h figures v»«« given
for these years, so figure was
doubled for year total.
12 n
8-
64 65 66 67 68 69 70
�216
Sources
1. "Annual Statistical Bulletins," Office of Joint Economic Affairs, U.S. AID,
Vietnam. Vols. 11, 12, 13, 14.
2. A. P. Wire Service. G_aine»vj|l.lle^_Sun. Gainesville, Florida. April 2, 1972.
3. Aviation Week and Space Technology. November 29, 1965.
4. Aviation Week and Space Technology. Jan. 3, 1966.
5t
Backgr ound j^erigljjglgvaritJEo_Prgjsgntgt^
thT^L^S/lleffilcidV'AasosauienT'Coanrasion of the American Association
for the Advancement of Scler.ce. Meeelson, l'esting, Constable, Revised.
1/4/71.
6. Congressional Record. Senate, January 28, 1972.
7. "Impact of the Vietnam War." Cosnaittee print by Foreign Affairs Division,
Congressional Research Service, Library of Congress, U. S. Government
Printing Office, Washington, 1971.
8. "Report on the War in Vietnam," CoiMsiad«r in Chief Pacific (as of 30 June,
1 6 ) SuperIntendeat of Docut»ats, U. S. Govt. Printing Office, Wash.,
98.
D.C.
9. Science. "Defoliation la Vietnam'.1 Tsehirley, Fred H., 21, Feb., 1969. p.
T79-786.
10. U.S. Congress. House. CoKittee on Appropriations. Dept. of Defense
Appropriations for 1370 pt. VII. Hearings, Washington, D. C. U. S.
Government Printing Office. 1970. p. 395.
11. "Vietnam Subject Index Hups". Research files of the Engineer Agency for
Resources, Inventories, and Vieenara Research and Evaluation Information
Center. Bureau for Vietnam. January 1970.
12.Vietnam Statistical Yearbook 1970. National Institute of Statistics. Republic
of Vietnam, Presidency of the Republic, Directorate General of Planning.
13. Banijubatana, Duslt. Kangrove Forest in Thailand. Proc. Ninth Pac&ic.
14. Golley, Fra/xk, Odum, and Wilson. "The Structure and Metabolism of a Puerto
Rican Red Mangrove Forest in May." Reprinted frora Ecology. Vol. 43,
No. 1, Winter, 1962.
15. Haitung, M. and G. H. Rieta. 1968. Capacidad fiaicu y rendiminiento de
obreros foratal a en diferentes condicic«msd cliisatics del tropico.
Institute foraatal latono America De Incestigacion y Capaeitacion.
Boletin No. 26:3-31.
16. Kellman, M. C. 1970. Secondary plant succession in tropical montane Mundanao.
Australia National University, Canberra. 174 p.
�217
17. Odurn, E. P., Ecology. Holt, Rinehart and Winston, N. Y. 1963.
18. Oduta, H. T. £ l ° S S L p * £ 2 l ^ £ S Z '
H^5S!JlSJ!iSi£.
John wi e
l y and Sons. N.Y. 1971.
19. Orians, Gordon H. and E. W. Pfeiffer. "Ecological Effects of the War in
Vietnam? Science. 168, 5931:544-554, 1 May 1970.
20. Pfeiffer, E. W. and A. Westing. "Land War. Three Reports." JtovjLrpnment,
Vol. 13, No. 9. Nov. 1971. p. 2-15.
21. Roditi, L. E. and N, I. Bazilevic. 1967. Production and MineraljCycHiig in
TerrestTial yegetatlpti. Oliver and Boyd, Edinburgh, p. 288.
22. Sn.daker, S. C. 1970. Ecological Studies on Tropical Moist Forest Succession
:Ln Eastern Lowland Guatemala. Ph. D. Thesis, Univeralty of Florida. 131 p.
23. Tergaa, L, E. 1965. Correlation of nutrient availability in soil and uptake
by native vegetation in hutoid topics. M.S. Thesis. Univ. of Fla., 64 p.
24. Th-aycr, George, TJt£_WarmBu3J.agg_3. Simon and Schuster. New York. 1969.
25. Westing, Arthur K and S. H. ?f*siff*r. "The Cratcri'ig of Indochina."
Scientific Aaiericnti. Vol. 226 #5. May 1972. p. 21
26. Ewel, John J. 1970. Experisaeats in Aftesting Succession with Cutting and
Herbicides in Five Trojjical Environments. Ph.D. diasartatiou. University
of North Carolina, Chapel Kill. Unpublished.
27. Richey, Jeffcry E. 197C. The Rola of Disordering Energy in Microcosms.
Masters of Science Thesis. University of Worth Carolina, Chapel HH1.
Unpublished.
�218
7. Simplified Simulation Model of Vietnam
and the Impact of Herbicides
J. Zucchetto
In Fig. 1 is a simplified version of the more complex model of Vietnam
given in Section 6,Flg. 1 has agriculture, non-human ecosystems, and urban
settlements that depend on outside sources of natural energies, purchase of
fuels, purchase of goods and services inputs, inflow of money with U.S. aid,
inflow of war equipment and disruption of war equipment by communist energies.
The model has the feedback of disrupted structures to a storage of disordered
parts (e.g., land destroyed by bombs and herbicides) that react with
available energies to produce net structure. Table 1 has a translation of
the equations in Fig. 2 which mathematically describe the system configuration
i n Fig. 1 .
:
.
-
.
.
.
From the data that were assembled for the larger descriptive model,
storages and flow rates were estimated and thase were used for the pathway
coefficients as given in Tables 1 and 2. The scaled equations are given
in Table 3 along with the scaling factors in Table 4.
�Figure 1.
�220
- K1Q1 -K31Q1H -K2
M
- Kt/Q, + A - K,rM - K,,M + W
14 J
A•
16
Fig. 2.
�Table 1
Description
Tank Levels, Flows & Calculations
Source of
Information
Ecosystem lands (Upland Forest and
Mangrove)
19.19 x 106 Acres
D.O.D. and Vietnam
Statistic Year Book
Disordered Parts (Forest, Agriculture
and City)
Agricultural Land
.
-•••-.
; 25 x 104 Acres
7.31 x 104 Acres
Urban Land . . . .• •• •. ..; •.-.:. - -
2.47 x 104 Acres
M
Capital in City
$281 Million
H
Herbicide Use
644 x 103 Gallons/Yr.
C
Cosssanist Energies
$555 Million/Yr.
Bate of Growth of Urban Land
1235 Acres/Yr.
Bare Forest Land Returning to
Agriculture
5600 Acres/Yr.
Assume SOS of Agricultural Land
Replanted
4
4.5 x 10 Acres/Yr.
Ecosystem Land Destroyed
7.95 x 103 Acres/Yr.
W
U.S. War Appropriations
$200 Million/Yr.
A
U. S. Aid
$250 Million/Yr.
Purchased Input
$50.3 Million/Yr.
Structure Destroyed
40 x 103 Acres/Yr.
Money in due to Sales
$40.5 Million/Yr.
(See Footnotes)
�Table 1 (Cent.)
Beseription
(K__ 4- S,g)M
Teak levels. Flows & Calculations
Messy to Psac&ase Goosls ssd
$130.5
$80.5 MiUioa/tr.
Sera famd Bstunaing to
14,500 Acres/?r.
Es&aral laoa •*• Itefesa
1235 Acr®s/fr.
4.5 z 10
Eat® of Sstara ef Slsordersd le^S to
1.25 S 104
1.5 z 10 Mras/fr.
Bestroetiea
5.94 £ IS4 Acres
21 z 194 Acres/year
Qestructiea
890 Acres /¥?.
iato :
S335 Aer@e/7r.
Bsjreciatioa
.02 Q3/ft.
Bepreeictioa
.02
Source of
D.O.D. and Vietnaa
Statistical Yearbook
�223
Footnotes for Table 1
Figures are approximately 1965-66 values.
Assume that the natural energies balance the losses to maintain a steady-state
in the natural system. Thus,
S - K Q where it is assumed that K..Q. * 0.02 Q - 2% of O^/year
Q.: Ecosystem lands - Upland forests - 18.5 x 10 acres
Mangrove
- 0.691 x 10^ acres
19.19 x 106 acres
0.2: Disordered parts - Bombed
Agriculture!
Forest:
City:
31,000 acres
9,030 acres in craters
890 acres
4.092 x 10* acres
Hcrbicided
Forest:
150,000 acres
_
Agriculture: 5i9
4
21 x 10 acres
TOTAL: Q2 « 25 x 10* acres
Q~: Agricultural land * 7.31 x 10 acres
Q4: Urban land * 2.47 x 10 acres
M:
Capital in city * $281 million
Herbicide use - Agricultural land:
Upland forest:
Mangroves :
3
198 x 10 gallons
455 x 10;: gallons
11 x 10 gallons
644 x 103 gallons
C: Communist energies - 140,000 men or $555 million
Flows J.U Sjr8t_em:
Rate of growth of urban land: Kii
Bare forest land returning to agriculture: K Q . O M - 5600 acres/yr.
�224
Footnotes for Tabla i (Continued)
Assume 30% of agricultural land replanted. Tints,
K8Q3CW - 0.5 [ . x 104 + 5.94 x 104J * 4.5 x 10A acraa/ysr.
31
Ecosystem lauds destroyed:
KjQjCU « 0 0 [ 9 0 + 1 0 x 103] - 7 9 x 103 acres/yr.
. 5 (.3
5)
.5
War appropriations from U.S. :
W - $200 ollllon
U. S. aid:
A * $250 taillion
Purchased input mounts to:
K4M « $50.3 Killioa
Araoimt of structure destroyed:
KjOT [Qj^ + Q_ + Q^J « 40 s 10 me
Amount of monsay flowing in due to
K
14Q3 3 $40*5
fiilllon
The BJEoisat of money flowing out tu pu£cte.s» ge«fifl ead f«9it
( 1 •»• K,6)M a $130.5 lailllon
K5
K^M « $ 0 5 million
8.
Bare lend returning to agriculture i
M M 14 000
»
Amount of natural land chsr»sinS into urbwa lands
K ^ « 1235 acres/yr.
^ M
Amount of natural land coiwerted into agricultuiral land:
Rural destruction:
'• • - "• ••.•.'•••-••. ,•'••
KoQ.CW « 4.5 x 10 acrea/yr,
83
Rate of return of disordered land to natural land:
K0Q, « 1.25 x 10 acree/yr.
�Footnotes for Table 1 (Cont.)
Ecosystem destruction due to herbicide:
K.jQ H * 1.5 x 105 acres/yr.
Agricultural land destroyed by herbicide:
K Q H » 5.94 x 10* acres/yr.
Total herbicide destruction:
K^HCO^ + Q2 + QA) « 21 x 104 acres/yr.
Urban bomb destruction;
1'otal bomb destruction:
K5CW (Qx + Q3 + Q4) « 40 x 103 acrcs/yr.
Total ecosystem transformation into rural and urban:
KQQM
~
1235 f560
' ° *6835
Assume approximately 2% recycle into Q2 frora QI§ Q3 and Q^: i.e. Kj_ ~ K. » KIZ
0.02
�226 -28
Table 2
Coefficient values:
KQ a 0.05
K2 * 0.355 x 10~3
K3 =« 0.373 x 10~8
K4 *
0.179
K5 « 0.136 » 10~7
K, » 0.104 x 10"10
V
K? <* 0.0403 x 10~10
Ko « 5.55 x 10~8
R
= 0,0092 x Id"10
32.5 x 10~8
5.54 x 10~6
K15 •»
0.179
K,, * 0.286
16
-2
21 * °*79 X 10
K,« « 0.812 x 10~2
K
�Table 3.
Q
l
-^g-
-
Scaled Equations
.384 [S] + .5 [Q21 - .134 (10) [QjHCHW] - 30 ^ [0^] - .234 [Q^fH] - .15 (100) [O^H
Q
2
—
, - .14 [M] + .5 [CHW] (.3 [Q.] + .0098 IQ,] + .0098 [Q.J) + .5 (.142(100) [Qj + .475 [Q,}0[H]
.33 x 10b
1
3
4
1
3
- .938(100)[M][Q2HQ1] + .18(10)[QjJ + .06(10)[Q3] + .06[Q4]
-*
, . 3 3 x 106
?4
.33 x 105
.365(100) [MHQ.HQ,] - .2(100)[Q-][C][V] - 30 Ss EQJ - .244 [Q,J[H]
1 2 .
3
3
3
" . •11<100°HQiHQ2HM] - 30 K12 [Q4] - . 117(1000) [Q4HC][W]
M
,,
.-3 »
.33 x 10
.166 [Q,] + .15(10)[A] - .86(10) [M] - .86(10)[M] + .18(100)[W]
3
Maaiatum Values:
Qjj, Q
6
30 x 10
- 107
Q^ - 10
Mm
7
- 104
Ca -
tea
-
2 x 10
i
6 x 103
Am = 500
Hm « 1
�230
Table 4
Scaling Factors
30x10
10
J3_
107
10
107
2 x 103
6 x 103
12 x 1013
360 x 1012
�231
In the first run (Fig 5) the oystem was not pulsed with a 5-year input
of herbicides. As can be seen from Fig. 5 the various state variables in the
model eventually achieve a. steady state value, the urban sector taking the
longest to achieve steady state. Notice in Figs. 6 and 7 that the effects of
a 5-year herbicide pulse or a double intensity 10-year herbicide pulse produce
perturbations in the system variables during the first 10-15 years, a time •
during which the rates of change arc different than in Fig. 5. The system
has enough inherent stability to damp out the perturbations and to eventually
proceed to similar steady state values irregardless of whether there was a
herbicide pulse. The interesting question arises as to the limits of hcrbicldal
disordering and destruction beyoud which the system would not recover and a
completely new steady-state situation would result. Of course, the stability
and recovery of the syststa are linked to the input of natural energy (solar to
photosynthetic growth) and fossil-fual and resource energy.
Without these
order-directing pathways the systosa, under intense destructive energies, would
end in disorder with a much slower recovery rate.
Fig. 8 presents results under the assumption that there is no flow, K Q _ »
from Q. (disordered parts) to 0~ (natural ecosystem). This situation might
arise if & political decision is made to develop the devastated natural areas.
The system recovers to the saute steady-state values as before except for
ecosyntem lands which end up at a lower value (app. 16% lower). It is interesting
to notice in all the graphs that urban development follows a kind of pseudo-logistic
curve even though there is only a linear depreciation outflow and a constant
yearly rate of energy input (U.S. aid). The question arises as to what kind of
growth will arise if there is a square term depreciation outflow from Q,,
�232
uT^^I *tr*ti?. w .z"£tr.£t
- -. .
!'
»!
_ . , * & „ ,*..
£ ; . . . . ...
^rtrr rtrtrrr rrjr=i
Figure 5. No herbicide; 15-year war pulse.
�233
'.i^ii". "'i*kir""."'"i™..r»*"";; .TTZ* }""."* t.v.r
.
.
.
'•ir'i-lHrtShllT-Jf::?!-:?
Figure 6. Five-year herbicide pwlaej 15-year
war pulse.
�234
Figure 7*
10-year double intensity pulse of herbicide; 15-year war pulse.
�235
CT^5^|S£^S|Trt:teS*Z^I
. * , r , . f .. S « . ! i i » * « .«W.M<,4
~»yt^S-l-.C^ « « * , i *
; r . ^ ^ \ & i |^ a . 4 v ' * r i j * ^
.B f « * i W t 1 i c w j v i f t u % *
i™*J» ' r « ^i"i J"SJsl:tKl '^Ctti.ISUV^. *»££.C
^s
Figure 8. Five-year herbicide pulssj 15-year war pulse, no natural recovery.
�236
i.e., that the costs of maintaining a complex system at some level increase as
the square of the interactions among the parts. Fig. 11 illustrates the
2
response with a KQ/4 outflow from the Q, storage.
Since the development and recovery of the system is so dependent on
U.S. aid, i.e., on fuels and resources, it is interesting to look at the
response of the system under different levels of subsidy.
In Figs. 9 and 10
are the results for urban and agricultural growth for three different levels
of U.S. aid. As can be seen there is not a linear correspondence between
U.S. aid and growth. In fact, there seems to be a process of diminishing
returns taking place in that the percentage, increase in growth is decreasing with
equal increments of U.S. aid. This effect was definitely seen for the
agricultural growth in that there was virtually no change between 10 times and
30 times the base level of U.S. aid.
Both Figs. 9 and 10 assume that there is
no natural recovery f roia Q- to Q..
Perspective in Comparison of Herbicide Impact
with Other Disruptions
Examination of the simulation curves suggest magnitudes of Impact of the
herbicide spraying period on the total energy flow of the Vietnam system.
As
shown in Fig. 6 the percentage of energy lonts as a fraction of the area under
the disordered parts curve until steady-state is reached, is approximately
5-6%.
The impact of herbicides exerts a short range effect, damping out
within a period of 5 years, as long as foreign aid is stimulating reordering.
�237
i£l=£H£3££^
teu.;>ttKri!rj:atls'f. iKrnr iz£-j.
ter, ;w^^tt~Jx^rfa:; a.ufci;:. j5*&.~
Jr4tS|H?^H- •S-BjS&J W^-v.xlZZij?.-.
fctei^.Sr4ir*aSSMLas^3^at*ar
..
£-£-* "^ii*
' tr^ "T*1^* f j r*^~'
. i
i
K^il^cTr^Tku^^iiixnltStHrbV
r!i;|s3lc-;sH;Tr:tl;iJrr;ta-fe.fa
vLtJtft:,* !4~w[«^7^>?D'£«^X>.&t?«»4'f^*^Ff
f^,ff-f.t. iJr t.l J»«J'i-*"T'^r-'f"-K'w)i • ' -fj- 1 - 1
I jflrt-irt —»* ..—Lr i- -**je...*;.:.i—1.}_...-.,.j. .J-.
* } . - * _ . + - . , . ,
RE-:;? r:cKt-4icfc»Jjfct!|asjKW
• ••<>l I T%5>
Flgure 9. Urban growth for 3 different levels of U.S. aid.
\
�238
-
z;~i::.:.::;:;ii^i:;::;4:-:;{'-^_, ^riiMrr ^ u u :
;:;i^:;::;4:-:;{'-^_,
1
U4 . - . . . . • , . . « : . » ^ v » . < > • — •«.
f « . > . . . } « » . t « * . » » g • * « «
i;=cCT-irf=n«Kia^r»s=fc:
Figure 10. Agricultural growth for different levels of U.S. aid.
�239
IS^SlSl-^iS^Hlll-iiSS-fiiv!^
^££^MM^:=£l
"
""
«
Figure 11. Five-year herbicide p«la®; 15-ya*r war pulae, Qr outflow from Q«.
�240
8.
A SIMPLIFIED SIMULATION OF THE IMPACT OF H&IBICIDE AND
WAR ON PRODUCTIVITY IN VIETNAM
C. SWALLOWS
The destruction caused by war has a functional relationship with those materials which have not been affected
nor destroyed. In energy terms, the stress of war upon
structure creates disordering energies which Interact with
ordering eneraies to assist tha reestebllshment of order.
For example, natural bior.508ra<3ffltion processes generate
nutrients from the organic matter of fallen trees which
will assist la the fertilisation of tha soil for the benefit of future trees and other plant life.
Tha disordering energy In ©ff<?ot catalyzes the ordered energies directed to fora n» structure. This formation
of new structure is a function of th® rate of oatalyzation
which In turn Is a function of the quantity of the disorder
generated and the ordered energy available for the catalytic process.
."'-, ' •
• . ' • . . . . . • •
:
•"' •"-••'
A basic modal of the Vietnam conflict is shown in
Fir. 1. It depicts basic Interactions among the various
components of war, structure, disorder, and ordered energy.
The application of stress upon the structure will
obviously decrease the quantity of th© structure, but
what effects does the stress have upon recovery tlae and
the steady-state levels?
�Disordered
Materials
C. Swdlors 3
H. T. Odum
Figure 1.
�242
Figure 2. Analog Model
�243
In the agrarian system of Vietnam, the productivity of
forest land and agricultural land has been a primary basis
for that society. What was the quantitative role of herbicide In forest and agricultural productivity? Hoi* long
were lands rendered unproductive? How fast were repair
mechanisms released? How rapidly ware bared lands and
released nutrients accelerating successions and regrowth?
In this section two models are evaluated and simulated
to suggest regrowth patterns for the forests and agricultural uplands of VIetnas.
Productivity Model One
The model shown In fig. 1.
Is a macroscopic view
of the Vietnam conflict which depicts the order-dlsox>der
symbiotic process. In order to simplify the complex Interactions within productivity, the available agricultural and
forest acreage was lumped Into a single storage
without
consideration of spatial relationships. Tne forcing
functions which contributed to the growth and stability
were natural energy and Included some fossil fual subsidies
to the rural econoay. Those forcing; functions are shown
Interacting with the disordering onergy to reestablish
disordered land to productive Land. Exports provide income and the aodal assumes constant price; earnings go
for fuel. Financial subsidies from the United States are
�shown further subsidizing natural energy.
The warring factions act as two large energy sources
which match each other In the aodel as to the power they
send Into the war.
Differential Equationsi
E . K^V - K?E
t
D « K3WA
M « K , ' •!
..V
.'
A » A
:•,.! f -.--", V sprf'r '•,•'':•.',•-•- ::'.•.'•':••" .''.v; ' --i . ' i , : '•;•• .--. • i .7 .--"i >.- v [ iT;.;-,
Numlbers used for scaling ar© given on the energy flows
shotm in Ftg« 1 ' : • as obtained froa th® following Table 1.
These numbers indicate the qea&feltisa which teve flowed
from the sources' tb"tho' storages ' or froia th© etovas®@ to
another storage."1"'^ s>i'lt'"". •'•-'•. » •'•'• ! i •' •. • ••• ••••';••; •' ' ••<•••-•-• ••.'••>>1"- •^•>"';.>
Noto that Tables
4.
2 : and 3
are footnotes of Table
Those tables indibate the sealing procedure followed
for thla model. Table 4
process.
'••
shows th® raeulta of the eoallng
"
•.'.. .
•
..• • • -..•'•/
•
�245
Table 1
Flow
Type of Flow
Quantity
1
U.S. aid to Vietnam
5 x 1012kcal
'Annual Statistical
Bulletin #14'
2
Money spent for fuel by Vietnam
8.5 x 1012kcal
'Annual Statistical
Bulletin #14'
3
Fuel to Vietnam
1.62 x 10IOkcal
Vietnam Statistical
Yearbook
4
Herbicide destruction of land
21 x 10 acres
Impact of Vietnam War
5
Exports
2 x 108Kg
Vietnam Statisticil
Yearbook
23 x 1013kcal
Impact of Vietnam War
Impact of Vietnam War
6 & 7 U.S. war appropriations and effort
Source
8
Herbicide application
2.4 x 1013kcal
9
Comjisunist war effort
8 x 1012kcal
Natural energy
2.45 x 1015kcal
10
**
*Nufflbers were derived from data paper by Mark Brown (?ar;; 6)
**For flow 10:
Insolation:
2
(1*000 koal/ra /day) (^000 m 2 /aore)(6 x 10* acres) (365 daya/year)
- 3.5 x 1015 kcal/year
Gross productln of disturbed cover is approximately 1# of
insolation. Therefore, 3.5 x 10*^ Steal/year.
For one acre of vegetstioa orderi
(10,000 kcal/ia2)('K>00 a2/aere) *, b x 107 fecal/acre
Turnover i
a
» 0.9 z 10 acra/year
k x 10? kcal/acra
therefore, the turnover rate Is approximately
once per year.
�246
Table 2
Scaling
_
13
k
1
0
We -
l ' (23xl013)(8xl012)"5xl°
1013
K
2 -(10 13 )(8xl0 12 )
_
-
0.12xlO- 12
12
K3A - 5 x 1012
K
3 - 23 x 1013 ' °'022
K. " 2 x 108 - 0.2
4
--9W
K.V - 2 x 10
4
K W
5 A
'
K6E - 10
Kfi
10
» jg,
1
10
K?E - 10
8
23X1013 -
10
V
K. - —-~ 4
12
/
(6 x 10*) (0.5 x 10* ) -
R9 M - 100
D
-1A
3.3 x 10
3
,
K10V -
1.2 x 10
.
J
K10
1.2 x 10"
- 6 x 10
_8
-
6 x 10
6x10 *
-
10
12
K V - 2 K 10
v
t . :• •.--..'
ln
JLU
«'- 0.2
2. x 10
�Table 3
Pot
Setting
**"vr«u
11
0.8 (10)
°
(8 x 1012)(1013)
1o
io
(10 J) (lO*-5)
A
1 15
Q
- 0.23
13
0.023 (10)
36
0.1 (10)
15
0.5 (10)
16
0.12 (10)
21
0.22 (10)
33
0.002
31
0.4
35
0.01
34
0.1 (10)
24
0.04 (10)
«
IO6
IO6
l
N
17 io6 -
K
J&J^~151S1&
io13
i
K2
K
3
i0.022)_ 10
IO13
15
"
K4
K,.
(4 x IO"10) (IO15)
1Q6
(1) (1C8)
io10
\
7
8
-
2 2
'
0.002
- 0.4
- °-01
iJJgi - 1
IO
8
(4
K
5
(1.2 x 10~13)(1028)
- 1.2
1Q15
10.2KJ.06)
1Q8
K
-
x
-11
I5
10 D(10 )
IO5
" °
�'248
Table 3 (Cont.)
Pot
Kg
(0.33 x lO"13) (1018)
1Q5
K1Q
(2 x 1Q"8)(1013)
1Q6
K.,
13
(DUO 6 )
-r —
6
- 0.2
- 1
2 UP13) _
1Q13
-
0.3
Setting
26
0.3
23
0.2
25
0.1 (10)
2
22
0.2 (10)
o.002
32
0.002
12
0.386
K
v
K
.Initial Condition
�249
Table 4
Pot
Setting
11
0 0 (0
. 8 1)
12
0.386
K
13
0.023 ( 0
1)
A
Address
. C
ll
Upper Limit
14
15
0.5 ( 0
1)
16
0.12 ( 0
1)
K2
21
0.22 ( 0
1)
K3
22
0.2 ( 0
1)
Kj,
23
°2
'
•••;.;•.
• • KX
K
, . • - •
10
24
00 (0
.4 1)
Kg
25
0.1 ( 0
1)
K13
26
0.3
K9
31
0.4
32
002
.0
-" K v
33
0.002
KA
- '• '
-
36
•. -
K.
5
0 0 (0
. 1 1)
34
35
• .. •
:'
•
'
'
K,
'. ' -
-. .,
••• •
' 'V
. . . ' , '
..•••.-.
• • . . • : •
,
'
.. .-.
00
.1
Kg
0.01 ( 0
1)
H
. • • • • . - . • • . . ' •
. . . . . .
�250
The graphs resulting from simulations are shown in
Figures 3, 4, and 5.
Since the starting condition «as calculated with a
steady-state diagram, Pig. 3
shows a constant, steady-
state quantity of acreage avail0ble for production without
•herbicide and war.
The steady-state quantity is approxi-
mately 0,1* x 10 acres and ths financial status of the
country remains low.
Pig.
*
depicts the effoata of herbicide defolia-
tion upon the components when the American war effort
steadily increases. The stoadf-state value for productivity
is approximately 0.2 x 10* aeroa which is one-half the
steady-sfcafca value observed i» Fig, 3.
However, the
capital in tha country has inersased due to the financial
aid given by tha United Stats®. There la acre saoney per
capita relative to less production. Therefore, a higher
standard of living accrues as result of the war if such
available monies are distributed «©ng the citizens.
Pig. 5
shows the transition to a new steady-
state with a constant level of war effort. Herbicide
applications reach steady state levels rapidly due to the
constant American war effort. Note that the response
time for herbicide is about 1,2 years whereas the transition period for productivity Irs about thre® years. This
lag denotes the length of time in which the herbicide
damage reaches ataady-atate with ragrowth.
�251
I
!>
t*
0
*
?
\$
X
.2.1 ;</*'*—U//j5"
I H rt11-
M-a«»»
{,.,,.4_
A
3. Ho War.
�251a
-I- * " • *
.•'
I.;*;'*
»"•
i- a.- •/(»*
;
««s
o.i>""
"I X / ' '
*"
4
H"! H-H-HHH- [!:-!-
Figure 4. Gradually accelerating
1.54 » 10X3 kcul.
'War effort with an upper limit of
�252
41W-
Ir
4-7 •"."
.. *>,.'* !
4-5.,.-
-•
-}-«.4««*
1
,
"•
. .<>.*«'» --,
*•
* i' *
•
I
/Jt
/
'•i'Vrx...,
" . " I • ." i, V
l .
4-H-4HH-H-T I |-.j-iH-rj-i-H
Figure 5.
Coaatant Arasri^aE War Effort of 1.54 x 1C13 fecal.
�253
Productivity Model Two
As shown in the sourcs graphc in section £., the
application of herbicide In Vietnes followed a five year
pulse. Such a pulse was simulated on a slightly modified
model shown In Fig.
8
through 11,
6.
The graphs, shown in Figures
predict the steady-state levels of the
various interacting components in productivity model two.
Fl«. 8
shows the nafcu:ral gteady-etate levels of
productivity when there is no herbicide application. The
values are the sase as those in Fi?.
Figures
9*,
3*
10 fend 10A. show the effect of
the five year herbicide pulea upon tfietnaa's financial
status and productivity over different tied period3.
Figures
10. and
10£. also show the resulting quantities
of disordered land within tho system. Eventually, disorder
will gradually return to zero "but the surge of disorder
and tha resulting new ordor-dleordei' balance say return
the productivity to its forsasr steady-state level as the
herbicide pulse fades.
Note that th® effects of herbicide
application upon tha basic p?odustl-?ity disappear within
two years in this acdal. Coapare this two year leg with
the 1.8 year lag observed in productivity aodal one. The
recovery tise is relatively fast considering tha amount
of land moaentarlly rendered unproductive.
�A Minimodel of Disorder-Order Symbiosis Upon
Structure As Stressed 8y A Viet Mam-Type War
Exports
Entrgy flows, kcd/yr
Money flows, kcal/yr
(11.00 = I04 keal)
C. Sseltcsjs end
K. T. Odum
�255
Figure 7. Analog Model.
�i
-u
Ut
o
.
*
1
I
•••1 1
•d
•<
\»
.
i _£*«"•
i
• -•
4
^
•
£
2
S
• • •
' < £ . ' . - ' •
.
N
,
^
.
.
- .'IS.-
X
• •• :
i ' **
l" '
-JiJ>'"a'
'
.•
:
•
. - - . - • ' .
;
•• ' • ' . •
" ••;•"-•-•"
.
.
"•"!""'•
. 5
-lv'»
*.' *••'•
.
_t
• •
.
' . ;
]•, ;; - |
'
;
.
'.
:'
-
'
•
-:;••.: ,
..-
'
I
r
*•
:
'
„
-'i*'1""
J
..-.;.,«
!.*«>«*
u±>""
~
_^
! ,y.a'*
-^
^
— o
1
T
.
-p
•'••'I" • '
i
i
~
•-
;. -•
-
!
•
i
.''••
L* '
1
o
-
'
•
•
.
'
.
.
.
" —
-
i
.
:
v-_*•»«*
-£..
:
,«,**'.
^
.Us*'*. ; ~ l_
_U:.»* ',,.-'
'
^
J_
'
•
' ••
—P*,,-' 1'.
'
1
——
;'
;
-':
-V
i"
-",
', - i"'' ' "•'
•
.
':
I'"
i"
'
:
• ' . • ' . ' '
-•
^^cMc Y
'., .l_u^-n.«n.-"rj 4tL 't U! '"'Z^! "T^--"Pgf;i!h!it»Bg!i^
^ ^ ^ S
^ ^ ^
S ^ ^ ^ ^ ^ J
^ ^ ^ ^ ^ t
S ^
^
1 l 1 i t ! 1 ! *, i 1 1 i 1 1. ! ! i ! 1 - ! ! i i 1
'' ' '
V.
,
'
2B
Figura 8. Ho Vox.
1
0
in
Ot
�K
5
•i)
s
o
Ui
o
a
f"-
IK/**
- .* «/•'
i1
?g.
I.*
—a
-~r
Z-a.
'J
.
^
i
-.
*«"•
*•
! ».?*,
T
•-H-H-H-
-H-Hn-H-fi—
zr
Figure 9. Five-year herbicide pulse.
�K
5
ils.!
Q
a
j
4
£
« *
• •
i,,
«.?**
t^H-
I I i I ! I I t-H 1 1 I ! i I 1 1
TIME
_YeA«%
Figure 10. Five-year herbicide pulse and the result-ag disorder.
10
Ol
�259
In Pig.
11. the hsrblolde pulsa width had been
Increased frota five to ten years to determine the effects
upon productivity, financial status, and disorder. The
effect upon disorder Is the only noticeable dissimilarity
between Figures
10 and
11. Intuitively, disorder
behaves as expected since It Is created by stress and
thus the longer the stress tha greater the disorder.
Th« recovery tlsa© time for productivity reramlns the same
although tha period In which It IB stressed had been
doubled,
',
�I
a
*
Q
a
4
T! «
i
1
•
!i
5
o
}-j-*"f--j—t-f—{-'
K ri
ts>
"vl^r 1 ! j •I-'I-H — "•• Yf /•.-••
20
T •»
Figure 11. Tea-year herbicide pulse.
10
s
�261
Pi f f erent ial .Equal t one.
W
Pulse Input
H
V
N -
D
The scaling in model two is sasontiGlly th«
aoal ins ^hich was done in modal OKQ essoept for the
oosffloients K «5«1 K. . K~~ reE<@in@S the
K3W « 5 x 1012 Koal
10
for th« pot aattlngi
^
_
_
_— j /- * *
.
•» 0.5 « 0.050(10}
10
Koal
Kg
« 2.7 x lo
"U
for the pot settingi
KQ«
0.27-0.027(10)
�262
Conclusions!
These simplified simulation models suggest that herbicide application greatly decreases the productivity In Vietnam but for a relatively short period of tiso. The resulting
disordered lands Interact with the natural energies and the
subsidizing energies to form a relatively fast recovery tlae
of two years. The recovery time Is related to the natural
turnover rate of once psr year. The amount of agxleultural
and forest land rendered unproductive In the model during
the period of herbicide application and the following recovery tiEie reduced the productivity by 8.25$ during the
five years of harbioid® application and the two years of
Howeverf the financial aessistanee given by the United
States generally increased In the? 0©s© yaara as was the
herbicide applied to agricultural and forest lands. The
financial aid subsidised the export; inoosa. This would
Imply more capital per capita although the productivity of
the country la low.
Financially, the conflict In Vietnam
stimulated the economy during thase years and the energies
purchased aay have added to energy subsidies available to
rural productivity as thle sod el provides.
Observations in Vietnam Indicate some validity of the
models. The recovery time of two years obsarved In productivity model two is substantiated forests which were
�263
bombed several years ago that have grown so dense that
the bomb craters cannot be seen from the air.
Also,
agricultural lands which have been sprayed with herbicide
or bombed several yeara a#c are now producing crops.
The increased Influx of imports during this period of
herbicide application substantiates the stimulation of
the economy of the country.
For example, a very popular
Import product was motorcycles.
�9. Effect of Aerial Application of Herbicides
On a Mangrove Community in Southwest Florida
Maurice G. Sell, Jr.
Introduction
As asequel to the large scale rpraying of herbicide in the Republic
of Vietnam, Dr. Howard Teas of the University of Miami initiated a project
to study the effects of aerial application of herbicide on a mangrove community
in southwest Florida. He was assisted in the actual spraying by Jerry Kelly,
one of his graduate students. Three sites were sprayed with Agent White
on December 15, 1973, and three additional sites were sprayed on January
19, 1973. A study team from the University of Florida consisting of
T. Ahlstrom, J. Browder, and M. Sell also participated in this program by
obtaining measurements of parameters such as tree diameter, identification
of tree species and whether they are alive or dead, fallen green and yellow
leaves, number of live and dead seedlings, and number of snails.
By virtue of this spraying experiment a chronological account might
then be made of the events that occur following spraying. How long does it
take for the leaves to actually fall? What levels of herbicide are needed
before defoliation is 100%? What species ehow the ability to rebound after
spraying? What changes occur in those mangroves not completely killed but
obviously stressed? By what means do the mangroves recolonise a sprayed area?
Once the leaves have fallen due to spraying, how long does it take a tree to
die If indeed it ever doss? Hopefully^ these and other questions will be
answered by this experiment.
Methods
Some parameters studied at the Marco Island, Florida site included
number of fallen green leaves, number of fallen yellow leaves, number of
�265
crabholes, number of coffee shell snails, Melaapus coff_e_us. number of red
mangrove and black mangrove seedlinga that were alive and also number that
were dead. The above parameters were counted in five plots that each
2
measured 20 meters by 40 meters or 800 m in area. The five plots included
a plot in which all the trees were harvested, a, control plot and three plots
R
that had been sprayed with Tordon 101 . Fig.
1 is a map of the sprayed
sites in southwest Florida. This is a herbicide quite similar to one of
those used in South Vietnasa. Herbicide dosages for the spray plots were
1 1/2 gallons per acre (estimated), 3 gallons per acre (estimated), and 2.2
gallons per acre (measured). In each plot counts of the parameters were made
2
in each of 10 areas. These areas ware 0.4 m at the 5-week Interval and
2
0.77 m at the 20-week and 33-weak intervals. Spraying of these plots was
done on December 13, 1972 with a helicopter. Sampling dates were in
January, May, and August, 1973, representing periods of 5, 20, and 33 weeks
after the initial spraying. Samples areas in each plot were chosen at random
to obtain representative counts for each parameter in a plot. Sample areas
were different at each aaraple period 00 the data did have some scatter.
Growing tips of young red ssangrove trees were also studied in each of the
sprayed plots. Trees were anywhere frosa two to six feet in height, and the
smaller ones were also required to have branched. These trees were then
observed closely to determine if the growing tips were alive or seemed to
have beet killed by the herbicide. Counts were then made of trees with at
least one growing tip and also of trees that did not appear to have any live
growing tips. In many Instances the growing tip may have been killed
initially and new growth was emerging beneath the old tip ora aide shoot.
This was considered a live growing tip.
The three sprayed plots mentioned earlier were studied in this manner at
Intervals of 20 and 33 weeks after spraying. Three other plots were sprayed
five weeks after the initial spraying at dosages of 4.25 gallons per acre
(measured), 6 gallons per acre (estimated) and 2.4 gallons per acre (measured).
For these plots the growing tips were counted at intervals of 15 and 28 weeks
after spraying.
In each of the sites sprayed December 15, 1972, (10 meters x 20 meters)
an area equal to 25% of the area of each site was mapped and the diameter of
each tree was measured. Live and dead trees were also discerned. This mapping
and measuring was also done for one of the control sites but for a larger
area (20 meters x 20 meters). Mapping was dona with an allodade and a stadii
�265a
Legend to figure 1
C-l
C-2
SP-1
SP-2
SP-3
SF-4
SP-5
SP-6
Control area
Control area
Spray plot 1
Spray plot 2
Spray plot: 3
Spray plot 4
Spray plot 5
Spray plot 6
(B; gallons per acre estimated)
(3 gallons per acre estimated)
( 2.2 gallons per acre measured)
(4.23 gallons per acre measured)
(6 gallons p«r acra estimated)
(2.4 galloas per acre measured)
�SF-S
C-i
CLEAR CUT
AREA
C-2
SP-4
MARCO
ISLAND
Figure 1. Ksp of Sprayed Areas and Control Areas.
SP-5
�267
rod (used to get distance and direction).
Results
Density of Green jLeayea
The number of green leavea waa not determined in the clear cut plot at
five weeks after cutting and no green leaves were observed at 20 and 33 weeks.
2
The control plot had 0.5, 0.6, and 0 green leavea per m at 5, 20 and 33
weeks. The plot sprayed with an estimated dosage of 1 1/2 gallons po^ acre
2
had 31.4, 0..1 and 0.1 green leaves per ra at 5, 20 and 33 weeks. The plot
sprayed with an estimated dosage of 3 gallons per acre had 29.0, 0.8 and 0.1
2
green leaves per m at 5, 20 and 33 weeks. The plot sprayed with an actual
2
dosage of 2.2 gallons per acre had 7S.8 green leaves per m at 5 weeks and
no green leaves were observed at 20 attd 33 weeks.
o
The number of yellow leaves per m was not determined in the clear cut
plot at 5 weeks after cutting. The cleatcut plot had 0.4 and 0 yellow leaves
2
per m after 20 and 33 weeks. The control plot had 20.2, 1.2 and 2.7 yellow
2
leaves per m at 5, 20 and 33 weeks. The plot sprayed with an estimated dosage
2
of 1 1/2 galinns per acre had 104, 0.3 and 1.8 yellow leaves per m at 5, 20
and 33 wecsks. The plot sprayed with an eatlmated dosage of 3 gallons per acre
2
had 141, 0.5, and 0.1 yellow leaves per is at 5, 20 and 33 weeks. The plot
sprayed with an actual dosage of 2.2 gallons per acre had 304, 0.4 and 1.0
2
yellow leaves per m at 5, 20 and 33 we
weeks. The results for both green leaves
and yellow leaves are given in Table 1.
Den8j,ty of Crabholgg
2
The number of crabholes per m was not obtained at the sampling period
5 weeks after spraying for any of the plots. The clear cut plot had 14.9
2
f
crabholes per m at 20 and 33 weeks. The control plot had 14.2 and 15.5
2
crabholes per B at 20 end 33 weeks, respectively. The plot sprayed with an
2
estimated dosage of 1 1/2 gallons per acre had 6.8 and 13.1 crabholes per m
at 20 and 33 weeks. The plot sprayed with an estimated dosage of 3 gallons
2
per acre had 13.2 and 10.7 crabholes per m at 20 and 33 weeks. The plot
sprayed with an actual dosage of 2.2 gallons per acre had 12.5 and 14.0
�268
TA5L£ 1
«.
-y of ^resn leaves ani yellov: leaves
per m2 following aerial application of lordon 101rf
Number of green
*
Weeks after
«js
20
Clearcut plot
Number of yellow
legves jjersr
2,0
jn
0
0
—
0.4
0
0.6
0
20.2
1.2
2.7
Spray plots
l]r gallons per
acre(estimated)
31.l* 0.1
0.1
104
0.3
1.8
3 gallons per
acre(estimated)
2?.0 '0.8
0.1
0.5
0.1
2.2 gallons per
acre (measured)
75.8
04
.
10
.
Control plot
'-. 0.5
* Densities in each plot are based on an average of 13 sampling ?.veas
of 0.4 m each at 5 weeks and of «r@as of 0.77 sr each at 20 rr-1 33
weeks.
�269
2
crabholes per m at 20 and 33 weeks. These results are given in Table 2.
Denpity._of snails
The number of live snails were not counted at the 5-week Interval
in the clear cut plot but at 20 and 33 weeks the clear cut had 5.1 and 13.8
2
live snails per m , respectively. The control plot had 38.1, 66.0, and
2
38.4 snails per m at 5, 20, and 33 weeks, respectively. The plot sprayed with
an estimated dosage of .1 1/2 gallons per acre had 74.7, 68.2, and 54.8 snails
2
per m at 5, 20 and 33 weeks, respectively. The plot sprayed with an
2
estimated dosage of 3 gallons per acre had 45.5, 56.6 and 3.2 snails per m
at 5, 20, and 33 weeks. The plot sprayed with an actual dosage of 2.2
2
gallons per acre had 77.7, 15.7 and 15.5 snails per m at 5, 20, and 33 weeks.
2
The clear cut plot had 0.6 and 0.8 red mangrove seedlings per m at 20
2
and 33 weeks. The number of black mangrove seedlings was 3.3 and 2.3 m
at 20 and 33 weeks, respectively. The control plot had no red mangrove
seedlings at 5 and 20 weeks but had 0.2 per ta at 33 weeks. The number of
black mangrove seedlings in the clearcut plot was 0.8, 0.6 and 0.3 at 5, 20
and 33 weeks. The plot sprayed with an estimated dosage of 1 1/2 gallons
per acre had 2.0, 0.2 and 0.5 red mangrove seedlings and 3.7, 2.1 and 2.2 black
mangrove seedlings at 5, 20 and 33 weeks, respectively. The plot sprayed
with an estimated dosage of 3 gallons per acre had 2.0, 0.4, and 1.7 red
2
2
mangrove seedlings per m end 7.3, 4.9 and 2.9 black mangrove seedlings per m
at 5, 20 and 33 weeks, respectively. The plot sprayed with an actual dosage
2
of 2.2 gallons per acre had 2.8, 2.5 and 0.5 red mangrove seedlings per m
2
and 4.4, 1.8 and 3.2 black mangrove seedlings per ra at 5, 20 and 33 weeks.
Penalty.;_of_Dead. .jjjeedlinga
No dead seedlings were observed at any t.tme in the clear cut plot and
also the control plot. The plot sprayed with an estimated 1 1/2 gallons per
o
acre had 0.6, 0, and 0.4 red mangrove seedlings per m and 2.0, 0.5, and
2
0.5 black mangrove seedlings per m at 5, 20 and 33 weeks. The plot sprayed
with an estimated 3 gallons per acre had 0.3, 1.1, and 0.5 red mangrove
2
seedlings per m at 5, 20 and 33 weeks. The plot sprayed with an actual
dosage of 2.2 gallons per acre had 0, 1.8, and 0.3 red mangrove seedlings
�270
Density* OP crabholss ani of the coffee shell
snail W§lajj5us ccT_feus fallowing asrial
application of Torlon 131"
•Jiumbar of c.-abholes
Number of snails
PJL^-X--.---™-^..
Weeks -after
spraying
JL
22.
'&
PQy.-.rc .-.
-i
2S
..
JQ
V
Clsarcut olot
—
Control plot
—
W.9 1^.?
5«1 13.8
1^.2
1.
55
3 . 6 . 38.^
81 60
Spray plots
l^i gallons per
acre(estimate!)
6.8
13.1
71*.? 6 . 5^.8
83
3 ajallons per
acre(estiraatei)
. — 13.2
10.7
.
^5-5 56.6
2.2 gallons per
acrelraeasurei)
--- 1 .
2 5 1.
^0
3.2
7 . 1 . 15«5
77 57
*• Densities in each plot are baaed on f.i average of 10 sampling
areas of O.U- m each at 5 weeks ancl of areas of 0.77 m each
at 20 and 33 weeks.
�TABLE 3
Live ani dead seedling densities* following
aerial application of Tordon 101"
Live seedlin
Live sesdling density
-Shizophora mangla
Avicennia niti-da
densit
Weeks after spraying
spraying
-I
1.
2
0.6
.1
2
-I
20
.1
2
0.8
—
3-3
-2.3
Control plot
0.2
0.8
0.6
0.5
3.?
2.1
2.2
1?
.
7.3
^.9
0.5
b.k
1.8
20
22
.1
20
33.
0
0
0.5
0.3
Spray plots
1 gallons per
|
acre (estimated) 2.0 0.2
-i
Clearcut plot
3 gallons per
acre (estimated) 2.0
0
'0
0.6
0
0.1+
2.0
0.5
2.9
0.3
1.1
0.5
2.8
I.?
3.2
0
1.3
0.3
^7
.
0
2.2 gallons per
acre(maasured)
2.8
2,5
* Densities In each plot are based on an.average of 10 sampling areas of 0.^ m"
each at 5 weeks and of areas of 0.77 m each at 20 and 33 weeks.
Numbers are based on a square meter
�272
2
2
per ra and 4.7, 0, and 0 black mangrove seedlings per m at 5, 20 and 33 weeks.
Study of Red JtonKrpye Growing Tips
The plot sprayed with an estimated dosage of 1 1/2 gallons per acre had
50 young red mangrove trees with at least one live growing tip out of 84 trees
that were counted. The rest of the 84 trees had no live growing tips. ihe
count was made at 33 weeks. Tha plot sprayed with an estimated 3 gallons per
acre had 45 trees with at least one live growing tip out of 109 trees that
were counted at 20 weeks and 56 out of 74 counted had live growing tips at
33 weeks. The plot sprayed with an actual dosage of 2.2 gallons per acre had
43 trees with at least one live growing tip put of 107 counted at 20 weeks and
92 out of 158 counted had live growing tips at 33 weeks. The plot sprayed with
c.n actual dosage of 4.25 gallons per acre had 144 trees with at least one live
growing tip cut of 236 trees that were counted at 15 week& and 134 out of 177
had live growing tips at 28 weeks. The plot sprayed with an estimated dosage
of 6 gallons per acre had 59 trees with at least one growing tip alive out of
195 counted at 15 weeks. The plot sprayed with an actual dosage of 2.4 gallons
per acre had 53 trees with at least one live growing tip out of 224 trees
counted at 15 weeks. No counts were made far these last two plots at 28 weeks.
Figs.
2 to 5 are maps of each of the first spray sites and a control
site showing the mapped areas and the identification of the tree species along
with the diameter of each tree. The data on the maps are summarized in Table
5.
Discussion
Table 1 shows that the effect of the herbicide application is to cause
early abscission of leaves while they are still green. The highest number
of green and yellow leaves lying on a square meter of forest floor occurred in
thcs plot sprayed with an actual dosage that averaged 2.2 gallons per acre over
the canopy. One reason for this may be that the actual dosages received by the
other two plots may have been much less than the levels desired. Another
possibility is that the other two plots have a greater number of black mangroves
than red mangroves. The plot with an estimated dosage of 1 1/2 gallons per
acre was 76% black mangrove (Fig.
3) and the plot with an estimated dosage
o». 3 gallons per acre was 60% black mangrove (Fig,
4 . The plot with 2.2
)
�273
TABLa
Weeks after
k
Sffect of aerial application of Torion 101rf
on tho growing tips of i&&£StiBbSX& seoilinjs
v
Number of seedlings Number of seedlings
riatlo of
With at least one
with no live- growing live to
liXfi^Xa&J&JJJB
tips
lead
_
12
Spray plots
1$ gallons per
acret estimated) ^ —
50
3 gallons per
acre(estiraated)
^5
'4>3
3**
-6^
56
2.2 gallons par
acrelraeasuroi)
—
18
O.?0 3.11
66
0 6 1.39
.?
92
U.25 gallons per
acre ( measure i) 14^
13«i-
6k •
92
1*3
6 gallons per
acu-o( estimated) 59
—--
136
—-• '
2.^ gallons per
acrelmeajurei ) 53
——
1?1
—
1.56
3.12
' 0.1*3
—-
, 0.31
——
�273a
Legend to Figures 2,3,4,5
O
I-ive
9
Dead
Q
Live Aylgenni a^ nit idla
"
Live La
Dead
"
"
�/
/
9,
ii
a
e
@
2.5
1.9
8
m
<
©
e G P,
3.7 5.3 £8
Q
n
24
°5
g
^»
2
-'
s./ ^
&'%
<Rft
|
6.2
M —_
dw *•*
s 2
E2
f
3
O
3
«
3
B
I.I
p
&
|
o
r
Fl.
7.7
'
®
3
S3
p
a
o, ^
&
i
'fa
*&A
@
m
4.5
3.S
o'
°2®
3O
"
4J
00
CJs
Figure 2. Kap of spray plot Mo. 1, ehw/ing tree locations and dlaneters.
O
4.2
*•
•
j
1
4.
fcj
Dp
O
1
&
43
0
*™
/
«
o
o °3 '*
1
J
Of
5^
o
a,
!
fc
£.4
f
2>s
9
2 2
S
f
9*9
f
5.7
t
'
3.2
f.
/
/
/
'i Ks /
"
7.5
^ B.s^
[a _
n
I
t&l
I
_
&
9
m
2.3 **
2.3
2.5
0
2.7
3 0
>.7 43
7.2
© 2<S
P.
*•*
S.3
2
n
m
S! S R P"o
2.5pr.-i
Q
UJ
S
®7
@
t~2
*3
a
M
0
�t*
CO
2
u>
•b
o
09
•o
•o
i-«
o
I
V
019
8
o
ft
HO
a>
rr
f»
�2'/6
02
a
02
w *
o«
oS
o-
oS
oS
CA
oS
CO
a:
uu
LU
o
8
CVi
ol
s*i
o"
©« i
o*
0-
3
05
a
OS-
Figure 4. Hap of spray plot Mo. 3 showing tree locations a»,d diomaters.
�!
in
Do
I
7l4
O
<
C.S.
Ml
1.2
O
ap
U
p*S
§
•0
H-
47
oi.7
CO
g
1
S.2
fcf*
UJ
2
(.4
o
n
. IB
o
rr
ri
tf
7.4
.
o
4.4
7
a
Q
n
3.2
ffl
M
a
9
DO
45
-
4.5
5.1
s
q.
QU3Q g
S3
r
�278
Table 5
Composition of Mangrove Forest at Herbicide Experiment Site
on Marco Island Prior to Spraying
Measurement
Control Plot
1
1
Spray Plots
2
3
Number Rhizophora wangle
Live
Dead
(diameter < 1")
~
0
19
13
9
41
13
45
9
150
50
41
31
63
43
14
3
0
0
0
0
1
3
5
4
31.7
42.5
64
20
Number Avicennia nit Ida
Live
Dead
(diameter ^ 1")
~~
Number Laguncularia racemosa
Live
Dead
(diameter ^ 1")
""
Percent dead to total standing
trees
�279
gallons per acre waa only 22% black mangrove (Fig.
5). In this study the
first trees to be completely defoliated were the white mangroves
(ISSHSEHiSSiS. J5££!S5.?®,) • ^e^ aangrovss were alco very susceptible to
herbicide but loss of leaves took longer. The least susceptible were the
black mangroves which helps to explain the lower leaf counts of the plots
with the estimated dosages.
By the time 20 weeks had elapsed the number of fallen green and yellow
leaves on the ground had decreased to levels equal to or slightly lower than
the control plot levels. The 2.2 gallons per acre plot was defoliated to such
an extent that no green leaves were observed on the ground at 20 or 33 weeks
after spraying. The low values for all of the plots at 20 weeks indicate
that defoliation had progressed as far as it was going to by that time.
One of the fauna occurring la significant numbers in every plot was the
coffee-shell snail, Helangua coffeus. This animal occurs on the forest floor,
on the prop roots, the pneumatophoree and the mangrove trees and is a grazer
of detritus and algae in the mangrove community. Although a count was not
made before clear cutting, the counts made after the fact were very low
compared to the control plot. This indicates that the snail has left the clear
cut area for some reason. The same phenomenon was observed in the plots
sprayed with an actual dosage of 2.2 gallons per acre and an estimated dosage of
3 gallons per acre. 1'he plot sprayed with an estimated 1 1/2 gallons per
acre has also shown a decline in the number of snails with time after
spraying but not as noticeable as the other two plots. The reason for this
decline in snail numbers may be due to the presence of increasing amounts of
solar radiation reaching the forest floor. This would have the effect of
heating the water and the soil to temperatures that are too high for the snail
to tolerate. The question that arises here is whether the snails leave or do
they die.
Another animal that is commonly found in mangroves is the fiddler crab which
is represented by many species in the genus Uca. Fiddler crabs dig burrows and
so to obtain a rough estimate of the numbers of fiddler crabs the number of
2
. crabholes per n was counted in each plot. Table 2 shows that there is very
little difference in the number of crabholes as the time after spraying Increases.
The validity of using this technique as an indicator of crabs present is
questionable. Obviously, tha presence of a hole is not a positive indicator
that the crab la still there. However, based on the available data it does
not appear that elimination of the canopy significantly effects the fiddler
crab population in the sprayed and clear cut plots.
�280
Tabli> 3 shows that the overall effect of spraying was to decrease tlie
number of live seedlingu as the time after spraying increased. Another cause
of seedling death was probably from the many Investigators walking In Uio
plots. Although the number of live red and black mangrove seedlings decreased,
the number of dead red and black mangrove seedlings did not correspondingly
increase very much. The discrepancy here raay be due to the sampling
technique. Different areas were sampled at each sampling period after spraying
and there may be some unintentional bias entering in here. Dead red mangrove
seedlings do appear to increase in two of the three sprayed plots and remain
reasonably constant in the other plot.
Because no definite conclusion can be made as to why live seedlings are
decreasing and dead black mangrove seedlings are not correspondingly increasing
but are instPC-d decreasing, another means of. measurement was devised to find out
if the herbicide was influencing seedlings. The number of seedlings with at
least one live growing tip were compared to those with no live growing tips.
Table 4 shows a column indicating the ratio of seedlings with at least one
growing tip to those with no growing tips. In every spray plot where two time
periods have been observed this ratio has increased. The significance of this
is that those seedlings with no growing tips are beginning to recover from the
spraying. The dosage in the understory where these seedlings are found was
found to be about 0.5 gallons per acre when measured. The effect of the
herbicide in many instances was to kill the growing tips but not to defoliate
the older leaves. Apparently this has enabled the young mangrove trees to
recover. An effect of the herbicide is noticeable by the occurrence of the
new growth coming out a side shoot rather than its normal position which was
killed by the herbicide.
�281
10.
Section in Part A Based on Fla-NAS Contract
The following la the section prepared for Part A of the report to Congress and
Committee approved July, 12, 1973. It summarizes some findings of the contract.
VIII. EFFECTS OF HERBICIDES ON ECOSYSTEMS
The NAS Committee was asked to: "Inveatigate the ecological and physiological effects of the defoliation and crop destruction programs in SVN."
Results and conclusions of greater or lesser degree of confidence, dependent on a
variety of factors, flow from such a study. One caution in interpreting such
a study is to avoid the common tendency to assume that all changes are effects
only of the impact of the agents (herbicides) being studied. Such an interpretation would be inappropriate in this case since it it known that many changes
were taking place independent of herbicide sprays in the period since 1962.
Another common error is failing to consider secondary Interactions, feedback
actions and time delays. To recogsd.se and evaluate such complexities while
visualizing the relationships of man and nature in overview, systems diagrams
are helpful. For example, a simplified overview of Vietnam's energy basis is
drawn in Figure 1. This diagram ehows the action of var and herbicide accelerating recyclic reuse of disordered lands, building materials from damaged towns,
displaced populations, aad nutrient cheraical elements. These are all parts
out of which new order is generated when they are fed back to stimulate regrowth, interacting with energy sources available for reconstruction.
Quan-
titative evaluation of the rates gives perspectives on what is important, and
computer calculations are used to show cumulative effects.
The defoliation and crop destruction programs in SVN had undeniable
ecological, physiological, social and economic impacts. Similar effects from
different causes are present in many areas of the world including Vietnam.
In Vietnam, as a result of the war, there were massive social and economic
changes associated with the transformation of the economy and movement of
�Reuse of Land, Nutrients,
Displaced Populations, Matls.
Sales
M
Outside
G<?ods8
Services
urchcse
Fuels
Purchased
From
Outside
Q,
Farms
Q,
Vegetation^
Sun,
Wind,
Rivers,
Tides
VIET NAM
Communist
Sources 8
Resources
Figure 1. Overall view of. pathways of energy and noney in Viet Nam. Circles are energy sources with causal
action froa outside. Tank sysbois are storages within Viet Nan. Pointed blocks marked X are
sultiplier control actions of one energy source on another. Money flows are dashed and flow in
opposite direction to the energies, goods and services they purchase. A set of mathematical
equations goes with this diagram.
K5
oo
�283
peoples; there were vast areas exposed to destructive forces of hombing and
shelling. The impacts of defoliation and crop destruction must be considered
and interpreted within this context. The relative magnitudes of component
sources of impacts must be considered in order to maintain an overall perspective.
Large scale systems of man and nature such PS inland forest, mangrove
forest, agricultural countryside, and urban areas undergo continuous processes
of construction, self maintenance, and reconstruction that tend to increase
or replace the amount of organized structure in the forr; of, for example, human
settlement, trees, soil, or wildlife. At the same time thera are natural
tendencies for structures to deteriorate with time.
There are also special
disruptive processes such as earthquakes, hurricanes, and war, including,for
example, the defoliation and crop destruction programs.
Viewing Vietnam's processes as & whole assists in gaining insight into the
relative magnitude of any one disruptive process. One way of doing this is
to combine understanding of relationships in simplified systems diagrams like
that in Fig. 1. Simplified aummarizations are sometimes called models.
Dia-
gramming and quantitative evaluating of the pathways of causative action are also
a roeans of recognizing and prer-entirg mathematical relationships, which can then
be combined in computer calculations to make predictions as to the effect of
assumptions used in simplifying the diagrams and the data used in writing the
mathematical equations.
Along with human intuition and judgment the "systems
modelling methods" have been demonstrated as a useful tool for objective forecasting of the relations of parts of the environment to show consaquences in
time of their interactions. In our study several models and computer simulations
were made including the conditions of temperature affecting mangroves in bare
mud microhabitat (See Part B), the flows of nitrogen and phosphorus affecting
the reforestation in the Rung Sat estuary (Fig. 2), the effect of seedling
�284
Wood
Cutting
8.5
jn
Quantities
in
8
g/m /yr
g/m
2
To S®a
To Deeper Mud
Phosphorus
Wood
utting
-I Rlver I 6
!
/assasas
14-7
To
*To Sea
Deeper Mud
Figure 2. Summary of nutrient cycles in mangroves forests of the Rung Sat.
�285
supply and wood cutting on mangrove reforestation (Fig. 3), and the impact of
herbicide on the overall energy budget of Vietnam as a whole.
Herbicide and Other Effects on the Mangrove Ecosystem
Particular attention was given to the mangrove forest because the magnitude of disruption by the defoliation program was obviously greater than
for other vegetative types, and because the most affected mangrove area (the
Rung Sat) was available for field study to obtain basic information used in
the systems model.
Before herbicide spraying (1958) about 51 percent of the Rung Sat was
mangrove forest.
The rest was water (22/0 > bare soil, brush, and agriculture.
The fish and shrimp .food chains in tha waters ware receiving organic
matter from three sources: (1) three inflowing rivers, (2) the mangroves, and
(3) photosynthesis of phytoplankton. The vigorous eight foot tide was exchanging the estuarine waters with the South China Sea every few days. Oxygen
levels in the water were apparently between 5 and 6 ppm, which is slightly
below saturation as expected where there is much consumption of organic matter
inflowing from rivers and swamp. Acidity was in the range of pH 6-7 in low
salinity zones, grading to the usual 8.2 in the open sea. There was a fishery
using non-mechanized means by people in the mangrove areas. Waters were slightly turbid as characteristic of a river delta region.
Data available before spraying were used to make some inferences on the
estuary and some inferences were made by a comparison of the waters in defoliated
and non-defoliated sections of the Rung Sat.
After spraying, and as examined in 1972, defoliation and other changes due
to war such as increased river traffic, dredging, and more use of motorized
fishing vessels had affected the aquatic ecosystem in several ways.
Increased
turbidity of water due to organic detritus from decomposing mangrove and greater
�286
siltation contributed to decreased phytoplankton and zooplankton, thereby lowering oxygen levels co between 3 and 4 pptn. There was no significant change in
pH during this period.
The total fish catch per unit effort of fishing vessel
declined confirming information from interviews that stocks were
down. Since motorized fishing has been introduced we do not know what part of
the decline in fish catch per unit effort was due to overfishing, to loss of
mangrove habitat, increased water turbidity, or other factors.
Because some of the foods for aquatic life in the estuary are being sustained by decomposition of the residual sprayed mangroves a continuing decline
in this fraction of the estuary's nutritional status is anticipated.
If there
is a delay in recolouization of the mangrove area, there may be a delay in
restoring the mangrove component to the fishery food chains.
However, the
fraction of detritus that comes from the river is not expected to change much,
and phytoplankton contributions may increase again as turbidity decreases.
One major impediment to recovery of sprayed mangrove forests is the availability of young trees. Some mangroves, e.g. Khlzoghora reproduce by means of
large seedlings which do not drop from t > parent tree until they are 8 inches
long or store, others by nut-like fruits, e.g. Ayici»nnia. In all types of mangrove the seedlings or nuts float and are dispersed by tidal water. In Rhigophora
because the seedlings are large, relatively few can be produced by a tree in a
year. In managed Rhizophora mangrove forest recommended practice for artificial
regeneration is to start two seedlings per square meter.
See Table 1. In the
Rung Sat, few trees remain that are capable of supplying the quantity of seedlings
or fruits required for early regrowth. Cutting for firewood is now concentrated
in the small area of remaining mangrove so trees are kept scrubby with few large
seed-yielding trees left. Only trees on the edges of water courses release a
significant number of fruits or seedlings into water for distribution to bare
areas. There is also a large mortality of fruits and seedlings between the
time of release atid establishment of a sapling tree.
�287
Table If
Seedlings Numbers for Reforestation of Rhizopjiora
Data on Seedlings
Recommended planting for reforestation
Now sprouting in central Rung Sat by 1972
Seedlings per Acre
8,000
65
Number produced on an acre of larger, well™
nourished treesc
28,000
Number surviving within a scrubby, cut-ovar
forest in Vietnam*3
1.0
440
Number reaching open water from seed source
areas6
450
Number colonizing bare areas by
calculation*
12
Computer Simulations (See Fig. 3)g
Number of seedlings starts from outside
that tnuct survive each year to achieve full
canopy in SO years
15
Number of seedlings starts from outside
that must survive each yea** tw ucm.eve
full canopy in 15 years
75
�288
Footnotes to Table 1
a
Moquillon (1944), Noakes (1955).
b
Counts of seedling in 50 ground photographs taken in 1972.
c
Counts from Puerto Rico, Florida and Vietnam.
d
Counts at Vung Tau, March 1972.
e
Seedlings produced on the edge of tidal canals where ratio of canal
2
margin to swamp area is abort 2 m/100/ra and 83 seedlings overhanging
2
per meter of canal per year; seedling area 100 Km (Rookery Bay, Florida),
f
One-quarter reaching bare areas and 10 percent of these surviving.
g
Assumes seedlings are introduced from oat:side each year, and that the
stated
number of seedlings survives at least to the end of the first
year, therefore to be subject to nonaal mortality. Regeneration will be
to an extent determined by land uses.
�289
In the central Rung S.it, the number of seedlings becoming established is
only a
tiny fraction of that required for rapid reforestation. Table 1 has
some pertinent numbers on seedling sources and needs. A model of relationships
of some main factors is given in Fig. 3a. Computer calculation of the seed
production and distribution, seedling mortality, tree harvest and other
factors shows that if seedlings are not ^upplied and if wood cutting of seed
bearing trees continues the recovery time nay be as long as 120 years. See
Fig. 3b.
100 years could be saved by neria] broadcast of 1000 seedlings per acre,
for 150,000
acres, or 150,000,000 seedlings. This would require the annual
seed yield of 5,000 acres of wangrovea broadcast over the bare areas of the Rung
Sat. These calculation!; are based on aerial planting studies that suggest 10
percent survival of seedlings.
If survival la less, more seedlings are required.
If planted by ground labor, fewer eeadlings would be required.
There was greater seedling survival in shaded spots than in areas exposed to
full sunlight and drying, where mud temperatures reach 104° F. and briny conditions and compaction have developed as a result of defoliaiton on higher grounds.
One question that arises in any reforestation problem is the availability
of plant ni>trituts, especially phosphorus and nitrogen.
Defoliation was often
followed by woodcutters who completely removed the woody parts of the mangrove
trees, so that nutrients in the wood were removed from the system. Soil studies
indicate this is a small fraction of available nitrogen, but for phosphorus it
can be a larger fraction.
However, the amount of phosphorus stored in mud and
coining into the Rung Sat from the riverflow each year appears to be more than
ample to supply the quantity required for reforestation. Note quantities of
�Seasonal Stimulus to Seedlings
Seedlings
on Trees
Area of
Seeded
Lend
A Metabolic Costs
Photosynthesis
Sssdimgs
in Water
Q4
Herbicide
Action
H
Mortality
rea of
e Land
Q, - k, 5 Q 2 H
Seedlings
Lost to
Sea
- k, 6 Q,0 4
62 = A - Q,
where A = total land area
of the Rung Sat
» R = I - k,Q 2 ! R
•
£5 • k 3 Q 2 ! R - k 6 Q 5 - k 7 Q 5 - cQ 9
Figure 3a
1
0
NO
o
�Addition of 75 Seedlings
Per Acre Per Year Surviving*
100at
&
u
&
50-
No
a.
Seedlings Added
(Natural
Reforestation)
r
100
i^
50
Years
After
150
Defoliation
* 1 seedling out of !0 planted will survive
3b. Computer prediction of reforestation of Rung Sat mangroves with and without planting by man.
(Simulation diagram is in the section of Part B on modeling of Rung Sat mangroves.) Woodcutters
harvest 3% of forest each year. Productivity of the forest is 16 tons per acre per year
(1360 gnss per m^ per year) .
to
vo
�292
phosphorus and nitrogen in leaves and wood in Fig. 2 as compared with that in
mud and flowing in from the river each year. The measurement made in our sampling
in sprayed areas showed adequate phosphorus held in soils.
Thus,
nutrients do not appear to be nearly so limiting as is seedling availability.
An Overall Energy Evaluation of Herbicide Impact
Viewing Vietnam's processes as a whole assists one in gaining insight into
the relative magnitude of the main disruptive processes which are included as
pathways of material and energy flow in Fig. 1. One way of doing this is to
tabulate all of the main energy flows, constructive and destructive, those of
nature
jch as the sun, und those of the cities such as fossil fuels. Energy
of 1' / quality such as sunlight is expressed in equivalents of chemical potential
t.-:rgy after the sunlight is transformed by photosynthesis. Expression of high
quality energy such as work of human labor and urban technological economy is
expressed in equivalents of fossil fuel required to generate this work.
The energy cost accounting method was used to estimate,overall Impact of
military use of herbicides in South Vietnam. Energy effects produced by herbicides
directly and indirectly were compared with Che total energy budget of all SVN.
The best data available to us for calculation of an energy budget are given in
Tables 2 and 3. These data were used to construct a diagram of energy flow
•
.-,•<••
(Fig. 1) which shows the direct and indirect effects as they were used in calculations.
... •
'
Figure 1 shows that the main inflows to the country are purchased fuels,
military import of fuels, energy in rivers and tides, groso photosynthetic
production in agriculture as stimulated fey human activities using purchased
Inputs, and the very large photosynthetic production in natural vegetation,
Including upland forests, mangroves, and the coastal waters.
•
�293
Table 2
Annual Energy Budget of Vietnam in 1965 and the Impact of Herbicide
1012
Kilocalories
Per Year
Item
Effect of Herbicide
Million
Interrupted
Dollars
Percent
Per Year
1Energy Per Year
JQ" kcal/yr
Change
Equivalent*
Human Settletoent (fuels)8
101
7,230
2
-2
Agriculture
128
9,140
2.5
-2
1460
104,200
5.8
-0.4
5.8
-0.2
Inland Forestc
Area Sprayed Once (1.2%)
Area Sprayed 2 Times
or Mere ( . % e
07)
Mangroves
61
4,360
49
.
-8
Estuarine Ecosystem Production
29
2,072
1.8
-6.6
Energy in Rivera *
644
46,000
0
0
Tidal Energy
152
10,860
0
0
Chemical Energy in Runoff
t,
Thermal Heating
119
8,510
0
0
1680
120,800
0
0
52
3,720
0
0
4426
316,000
1
Wind Absorption
Total
22.8
-0.5
�294
Footnotes for Table 2
*
14,000 kilocalories of chemical potential energy was estimated to be
processed as work per dollar circulated.
+
Total spray acreages for five years of spraying were divided by 5 to
obtain annual value,® of herbicide disruption,
a
Sum of purchased and military fuel imports. Purchased fuel imports were
o
estimated as 10 metric tons and converted to calorics of work by multiplying by 10 grams per ton and 10 kcal per gram. Military fuel imports
were estimated as 10 barrels per year and multiplied by 10 kcal per
barrel. Fuel use was estimated as disrupted 1.9% in proportion to 1.9%
of the land area sprayed affecting human activities for the year,
b
Chemical potential energy entering the system each year as agricultural
production was estimated by multiplying agricultural land (8 x 10 acres)
by 4 x 103 to convert to square rasters and by 40 kcal/m2/day of
estimated gross photosynthesis and by 100 days estimated as the time crops
were in leaf each yo.ar. Two percent was estimated of thla area
disrupted per year during spray years.
c
Chemical potential energy entering the system each year as gross photosynthesis of inland forest lands was estimated by multiplying area of
vegetated lands (2.5 x 107) areas by 4 x 10 3 m2/acre to convert to square
meters and estimated averages, and then by hot synthetic rate including
dry season (40 kcal/m2/day) and then by 365 days of green cover to obtain
1460 x 1012 kiloealories per year,
d
Herbicide disruption per year on single sprayed areas was estimated as
defoliation of half of the leaves for half of the year on the 1.4% of forested
land sprayed once per year.
�295
e
Disruption on area sprayed twice or more was estimated as fifty percent
of .7% of the forested area sprayed more than once per year.
f
Chemical potential energy contributed each year by mangrove photosynthsis
was estimated as the number of acres ( . x 10") multiplied co convert to
07
square meters (4 x 10-* m2/acre), multiplied by photosynthetic rate
(60 kcal/ra /day) and multiplied by 365 days per year to obtain 61 x 1C12
kcal/year.
Herbicide interruption was estimated to be half of the area of mangroves.
g
Chemical potential energy from estuarine photosynthesis was estimated as the
product of the area ( 0 acres), converted to square meters (A x 10 m2/acre),
16
the estimated photosynthetic rate (20 kcal/ra /day using values from Calveston
Bay which has similar turbidity) and the number of days per year (365).
Interruption due to herbicide waa estimated as that part of the estuary
within the herbicided area (about 33%).
h
Energy in rivers was estimated as the potential energy against gravity in
the annual rainfall (2m x 1.72 x 1031 square m in RVN) which is the
volume times average height of RVN ( 0 m) times density of freshwater
80
( 0 kg/rP) tisvae the acceleration of gravity ( . in/see2) and multiplied
1
98
by 2.39 x 10
1
to convert from joules to kilocalcries.
Tidal energy was estimated as the potential energy of coastal water elevated
and then absorbed in frictional work. Energy was estimated as product of
water volume [estimated area of 1.45 x 10* ia2 times the height of the tidal
range each day (6m including two tides per day)], the number of days per
year ( 6 ) the average height of lifting water against gravity (2m), the
35,
o
•*
9
density of water ( . 2 x 10 kg/ra ), the acceleration of gravity ( . in/see")
10
98
and conversion from joules to kilocalories ( . 9 x 10 ).
23
j
The chemical potential energy in 1/3 of rain reaching sea in rivers reacting
�296
with salts was estimated using expression for energy in cne nsole of water
multiplied by the nolca of water flowing per year (water weight divided
by the molecular weight, 18). Water was estimated as 2m times area
9
(1.72 x 1011 or) times 1/3. Change in water concentration in Joining
the sea is that of a chemical from fresh to sea water C^ * .965 and
Ci « 1, R is gas constantO.98), and temperature is 300°K and AFO » 0.
k
Wind energy generated by temperature gradients generated by sun's heating
and that due to downward diffusion of wind into the air space that may
be counted is part of the country. If the heat gradient (Ar) generated
between land and air is maintained at 2°C the potential encrg> available
to atmospheric heat energies la the product of the Car not ratio and the
Kelvin temperature (300°) and the total heat flux generated in absorbing
the sun's energy ( , 0 kcal/sr/day times area 1.72 x 1011 m2) times
400
365 days.
1
The energy from wind eddies that are externally generated was estimated
as the kinetic energy at 300ra tii.'es the eddy diffusion coefficient
(104 cm2/sec) transferring momentum downward where it is absorbed in
stirring the lower layers. The kinetic energy of a cubic centimeter is the
product of half of the mass (air density 10~3g/cnr) times the square of
the velocity ( 4 cm/sec) and trie gradient is obtained by dividing by
44
height of the layer (30,000 cm). For the whole country, miltiply by
7
area (1.72 x 1015 cur). To convert ergs to kilocalories multiply by
kil
2.39 x 10"11 and for a year 3.15 x 107 f»c/yr.
�297
Table 3
Cumulative Disruption Estimated 1965 Through 1985a
Disruption
Per Year
(See Table 2)
1
10 2 kcal/yr
Item
Assutsed Length
of Tiaw
of Disruption
Years
Curnularive
Energy
Disruption
1012 kcal
Human Settlement
10
1
10
Agriculture1*
12.5
1
Effect of Cumulative
Disruption on
Total Energy
Economy"1^ Percent
u.u-j
12.5
Inland Forest
Sprayed Once
Sprayed Twice or More**
2
'
2
'
0.61
245
0.69
5
9.66
218
20f
4.5
Eatuarine Production®
a. 02
0.5
10
2
Mangroves
O.OJ
22.5
0.06
Totalh
515
Footnotes to Table
1.44
3
a
Estimated as the energy disrupted tisaao the number of years disrupted.
b
Disruption was estimated aa that in Table 1 (1.9% of the area for one year)
times 5 such years.
c
Disruption wan estimated as half of the production in Table 2 of area
sprayed once (1.2%) times half of a year,
d
Disruption estimated as 3/4 of the production in Table ? of area sprayed
twice ( . % timea 10 yesrs.
07)
e
Disruption waa estimated as half of the production rate in Table 2 of the
area sprayed ( 0 ) for 20 years.
5%
�298
f
Assumes a seeding program to supply seedlings to bare areas.
g
Disruption based on half of the production in Table i for the area
sprayed (1/3) for five years during period of decay and dispersion of
turbidity,
h
Total energy budget in Table ^(1780 x 1012 kcal/yr) times 20 years
equals 35,600 x 1012 kcal.
�299
For that part of the system that has money exchange for value received
one may list both money and energy budgets per year. These are pathways in
Figure 5 that have a solid line (energy) and a dashed line ($) running in opposite direction aa payment for the work done.
(Work is useful energy application.)
For these parts of the economy, it is possible to calculate a ratio of moaey
to energy flow which in SVN was about 14,000 kilocalories per U. S. dollar. Thus,
if data for some part of the economy are in dollars one may estimate roughly the
kilocalories of work done all through the economy in support of that work.
One may use the enerfty to dollar ratio in a reverse way to show money equivalent to the energy provided by nature in tides, ecosystems, photosynthesis, and
other work for which there is no exchange of money.
In Table 2 the second column
has some dollar equivalents calculated with the energy/money ratio to give an
appreciation of the amount of work provided by nature, which we often regard as
"free." Agriculture gets part of its energy from the work of nature free of
money charges so that its total dollar equivalent is larger than the money that
exchanges in agricultural sales.
In the third column of Table 2, the impact of herbicide on the energy
economy is given for one year as best we can estimate it from available data.
Column A has the percent change due to herbicide. The total change estimated
for herbicidal effect is U.3 percent of the total energy budget for each of
the years 1965-1971.
These calculations do not indicate whether a change in good or bad. For
example
some who advocate that mangrove lands be used for rice believe that
mangrove clearing ia good, whereas others regard the mangrove interruption as
a loss. It depends on what land use is Intended in the future.
There is also
the energy value of ships to and from Saigon not sunk because of clearing the
mangroves.
,
. •- •
•^
The herbicide disruption was estimated in Table 2 for one year. The
total effect depends on the time required for recovery. If energies are
�300
available for reconstruction restoration may be rapid. The creation of disrupted lands stimulates the recovery of these lands since they are susceptible
to reorganization by new energy flow. In the mangroves special factors of seed
shortage delay recovery. In Table 3 the time for restoration of the canopy is
used to estimate the cumulative effect from time of spraying until recovery of
photosynthetic activity. For inland forest and agriculture defoliated after
one spraying this has been assumed to ba ona season or less since only part
of the canopy was defoliated and most trees have enough reserves to reroliato
once. For mangroves restoration of canopy takes much longer.
The duration of mangrove interruption depends on delays in a decision of
whether to add seedlings or put the land to another use. The interruption
that is attributable to herbicides is calculated to the present. Future delays in making a decision may result in a delay in attaining full productivity of
the Rung Sat, but productivity losses due to delays in making a decision cannot
be necessarily attributed to the herbicide.
The model in Figure 1 was simulated on computer to obtain curves of overall value in energy units during the parlod of recovery, a time when other
energies were also varying due to the war.
Figure A shows one of the computer
graphs suggesting the overall shape of interactions with and without herbicide.
For the assumptions Made about the factors controlling growth and for the data
used the graph shows future patterns in Vietnam with end without the herbicide
effort.
In the last column of Table 2 the tiiae of energy interruptions was combined with amount of energy Interruption per year to obtain an estimate of the
overall cumulative effect to 1980 on tha energy budget of SVM. This was shown to
be 0.6 percent. An analysis of the entire system shows that the largest energy
input of the defoliation program has been the destruction of mangroves. If
during the same period the energy increase due to U.S. aid were estimated at
500 million dollars per year the effect in increasing energy value would be
�AREA
(!0SQsrss)
Q,
Q2
30-I 10
MOMEY
(|!04
miiU
Q]
No
fQH
5
Herbicide; 15 Year
Year
Herbicide
War
Input; 15 Year War
Q4 Human
Ssiflsments
QI Vegetation
5H
.1
5- 0 5
•
^^
. —H" Q 3 Agriculture
Q
M
0
1965
2000
2025
2050
Parts, Disordered Lands
Money
2075
YEAR
Fig. 4. Simulation results of nodel depicted in Fig. 1 for the cases of no herbicide and
5-year herbicide pulse.
�
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
010
Folder
The folder containing the original item.
0091
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Creator
An entity primarily responsible for making the resource
Odum, Howard T.
Maurice Sell
Mark Brown
James Zucchetto
Charles Swallows
Joan Browder
T. Ahlstrom
L. Peterson
Description
An account of the resource
<strong>Corporate Author: </strong>Environmental Engineering Sciences, University of Florida, Gainesville, Florida; and Department of Biology, Center for Regional Environmental Problems, California State University, San Diego, California
Date
A point or period of time associated with an event in the lifecycle of the resource
1974-02-01
Title
A name given to the resource
The Effects of Herbicides in South Vietnam: Part B, Working Papers, February 1974: Models of Herbicide, Mangroves, and War in Vietnam
Subject
The topic of the resource
herbicide application
ecological impact
Ranch Hand
military impact
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/8e3b6862babe506cdb17e86408a1ddf8.pdf
e4e353606bfd939c66930a6ea5a959a3
PDF Text
Text
Item ID Number
AUthllP
CorUOI'BtB Author
00095
Agerton, Bobby M.
^'r Force Armament Laboratory, Ervironics Office
(DLV), Eglin AFB, Florida
Roport/Artido TltlB A Study of Agronomic Plants Grown on Herbicide-Contaminated Soils: Final Report:
May 1974-August 1974
Journal/Book Title
Year
1975
Month/Day
Januar
v
Color
NumbEiroflmaDes
21
Doscrlpton Notes
Project soee
Friday, December 08, 2000
Page 95 of 106
�AFATL-TR-75-8
A STUDY OF AGRONOMIC PLANTS
GROWN ON HERBICIDE-CONTAMINATED SOILS
ENVIRONICS OFFICE
JANUARY 1975
FINAL REPORT:
MAY 1974 - AUGUST 1974
Approved for public release; distribution unlimited.
AIR FORCE ARMAMENT L A B O R A T O R Y
AIR FORCE SYSTEMS COMMAND* UNITED STATES AIR FORCE
EGLIN AIR FORCE BASE, FLORIDA
�UNCLASSIFIED
SECURITY CLASSIFICATION OF THIS PAGE (When Date Entered)
READ INSTRUCTIONS
BEFORE COMPLETING FORM
REPORT DOCUMENTATION PAGE
1. REPORT NUMBER
2. GOVT ACCESSION NO
3. RECIPIENT'S C A T A L O G NUMBER
AFATL-TR-75-8
4. TITLE fond Subtitle)
5. TYPE OF REPORT ft PERIOD COVEREID
A STUDY OF AGRONOMIC PLANTS GROWN ON
HERBICIDE-CONTAMINATED SOILS
Final Report
May 1974 - August 1974
6. P E R F O R M I N G ORG. REPORT N U M B E R
7. AUTHOR^;
Bobby M. Agerton
Richard C. Crews
B. CONTRACT OR G R A N T NUMBERfsJ
9- PERFORMING O R G A N I Z A T I O N NAME AND ADDRESS
10. PROGRAM ELEMENT, PROJECT, TASK
A R E A 6 WORK UNIT NUMBERS
Environics Office (DLV)
Air Force Armament Laboratory
Eglin Air Force Base, Florida 32542
Project 5066
1 I. CONTROLLING OFFICE NAME AND ADDRESS
12. REPORT DATE
Air Force Armament Laboratory
Armament Development and Test Center
Eglin Air Force Base, Florida 32542
13. NUMBER OF PAGES
T«. MONITORING AGENCY NAME ft ADDRESS^/ dltteront Irnm Controlling Office)
15. SECURITY CLASS, (of this report)
January 1975
20
Unclassified
15a. DECLASSIFICATION 'DOWNGRADING
SCHEDULE
16. DISTRIBUTION STATEMENT (ol this Report)
Approved for public release; distribution unlimited.
I'. DISTRIBUTION STATEMENT (ol the abstract entered in Block 20, if different trom Report)
(I. SUPPLEMENTARY NOTES
Available in DDC
9. KEY WORDS (Continue on reverse side It necessary ana Identity by block numbar)
-lerbicide long-term environmental/ecological effects
TCDD (2,3,7,8-tetrachlorodibenzo-p-dioxin)
)efoliant Testing
2,4,5-T
2,4-D
Herbicide Residues
5. A B S T R A C T (Continue on reverse side If necessary and Identify by block number)
From 1962 to 1970, massive quantities of herbicides were sprayed on test areas at Eglin AFB
Fteservation, Florida, to evaluate developmental aerial spray systems. Questions were recently
•aised about the potential ecological and environmental effects on the test areas. Therefore, a
study was conducted to determine if soil that nad received massive quantities of herbicide would
support seed germination, vegetative growth, and fruit production of seven selected agronomic
crops. The study showed that the level o-F heraicides which remained in the soil was not high
enough to prevent germination, plant growth, or fruit production.
|%n FORM
"U 1 JAN 73
EDITION OF 1 NOV 65 IS OBSOLETE
UNCLASSIFIED
SECURITY CLASSIFICATION OF THIS PAGE (When Data Entered)
�i ASSIFIFH
SECURITY CLASSIFICATION OF THIS PAGEfHTien Data Enta-ed)
UNCLASSIFIED
SECURITY CLASSIFICATION OF THIS P AGEC^/ion p a(a Knitted)
�PREFACE
This technical report discusses a portion of the work performed at the Air Force
Armament Laboratory, Armament Development and Test Center, under Exploratory
Development Project 5066 during the period May 1974 through August 1974.
«
The sources and manufacturers of materials and equipment used in this study are
identified for reference only and do not constitute endorsement of the companies or products
by the United States Air Force.
This technical report has been reviewed and is approved for publication.
FOR THE COMMANDER
E A. FARMER
Chief, Environics Office
1
(The reverse of this page is blank)
��TABLE OF CONTENTS
Section
I
II
Page
INTRODUCTION
5
MATERIALS AND METHODS
6
III
RESULTS
10
IV
DISCUSSION AND CONCLUSIONS
19
3
(The reverse of this page is blank)
��SECTION I
INTRODUCTION
Test Area (TA) C-52A, Eglin AFB Reservation, Florida, was used to evaluate developmental
aerial spray systems from 1962 to 1970. During this period massive quantities of herbicides
were sprayed in order to study various spray parameters. This repetitive application of large
quantities of herbicides has raised questions about the potential long-term ecological and
environmental effects on the test site and surrounding areas of TA C-52A.
Four herbicides accounted for most of the materials used. These are White (10.2 percent
triisopropanolamine salt of picloram, 39.6 percent triisoprcpanamine salt of 2,4-D, and 50.2
percent inert ingredients), Blue (22.6 percent sodium cacoclylate, 3.9 percent dimethylarsin'c
acid, 73.5 percent Inert ingredients, and 5.0 percent surfactant). Purple (50 percent n-butyl
ester of 2,4-D, 30 percent n-butyl ester of 2,4,5-T and 20 percent isobutyl ester of 2,4,5-T),
and Orange (50-50 mixture of 80 percent n-butyl ester of 2,4-D and 2,4,5-T). It was subsequently determined that two of the herbicides, Purple and Orange, contained the impurity
called TCDD (2,3,7,8-tetrachlorodibenzo-p-dioxin) which is highly toxic and a teratogen, causing
fetal deformities (Reference 1).
The actual herbicide deposition levels on the test area are not known and can only be
estimated using the Spray-aircraft flight paths, application rates, and the meteorological conditions under which test spraying was done. Subsequent to the actual testing, some of the
herbicide residue has undoubtedly been translocated by wind and water movement.
It was reported in Reference 2 that the test area was ecologically recovering and that the
active herbicide ingredients were down to the parts-per-billion range.
The purpose of the effort reported here was to determine if the soil that had received
massive quantities of herbicide had recovered sufficiently to support seed germination, vegetative
growth, and fruit production of selected agronomic crops.
Reference:
1. Sparschu, G. L, et al:"Teratogenicity of 2,3,7,8-tetrachlorochibenzo-p-dioxin in the Rat."
Food Cosmet Toxicol 9 (3) 405 (1971).
2. Young, A. L.: Ecological Studies on a Herbicide Equipment Test Area (TA C-52A). Eglin
AFB Reservation. Florida, AFATL-TR-74-12, Air Force Armament Laboratory, January 1974.
�SECTION II
MATERIALS AND METHODS
An area on the sourth end of TA C-52A was selected as the site for an experimental vegetative plot (Figures 1 and 2). This area was estimated to have received approximately 2,000
pounds per acre of active herbicide ingredients (mostly 2,4-D and 2,4,5-T) and was devoid of
vegetation. The soil of this area was well drained, acid soil of the Lakeland Association. The
area surrounding the plot had a sparse population of broomsedge (Andropoaon virginicus).
switchgrass (Panicum virgatum). wooly panicum (Panicum lanuginosum). and low growing
grasses and herbs.
A spot on the northeast section of TA D-51, (3 miles west of TA C-52A) (Figure 1 through
3), where no herbicide had been applied, was selected as a control site. This area was selected
because of its similarity to the experimental plot with respect to terrain, soil type, rainfall,
and wind conditions.
Since TA C-52A had been used as a bombing and gunnery range prior to its use as a
herbicide test area, the experimental plot had to be checked and cleared of hazardous material
by Explosive Ordnance Disposal (EOD) personnel. As mentioned above, there was no vegetation
on the experimental plot, however the control plot at TA D-51 had to be cleared of a few
scattered grasses. A 3 by 7 meter section was fenced with 1/4-inch mesh hardware cloth at
each of the locations. A canopy of cheesecloth was placed over each plot to provide partial
shade during seed germination and seedling establishment. A sheet of rubberized material was
stretched around the windward sections of the fence to protect young plants from wind damage
and to reduce moisture stress.
The soil on both plots was orepared by tilling to a depth of approximately 30 centimeters.
The experimental plot was prepared on 6 May 1974 and the control plot on 9 May 1974.
Soil from each plot was taken to the laboratory where the pH was found to be 4.0 for the
experimental plot and 4.6 for the control. It was determined that the soil at both plots was too
acidic for the plants to be used in this study and that it should be elevated to a pH more conducive to growth of the selected plants. On 9 May 1974, 5.8 kilograms of lime and 1.4 kilograms of commercial fertilizer (13-13-13) were applied to both plots prior to planting. After
12 days, the pH readings of the soils in the experimental and control plots were 5.6 and 5.8,
respect vely. An additional 453 grams of fertilizer were applied to each plot at monthly
intervals thereafter.
On 13 May 1974, seven rows 3 meters in length were prepared on each plot. On the same
day one row each of Bahia grass (Paspalum notatum variety Pensacola), millet (Panicum
miliaceum variety Browntop), radishes (Raphanus satuvus variety Scarlet), and beans (Phaseolus
vulgaris variety Tennessee Bunch) was planted. Tomato seeds (Lycopersicon esculentum variety
Spring Giants) had been germinated in a greenhouse and allowed to grow for 3 weeks prior to
planting. On 14 May 1974, one row of peanuts (Arachis hypogaea variety Starr) and on
15 May 1974, one row of cotton (Gossvpium hirsutum variety Dixie King III) were planted.
One hundred and ninety liters of water were applied to each plot twice weekly. This water
volume was calculated to be equivalent to 1.91 centimeters of rainfall weekly. Examination
of the soil indicated that this amount of water was sufficient to saturate the soil and provide
�EXPERIM
CONTROL PLOT
Figure 1. Eglin AFB Reservation Showing Locations of Control and Experimental Plots
�Figure 2. Experimental Plot Located on TA C-52A
Figure 3. Control Plot Located on TA D-51
�enough moisture for the plants during early stages of development. Natural rainfall was
supplemented as needed to provide this amount of water as a minimum until the plants
reached a point in development where the demand exceeded the amount being applied, and
then the amount of water was doubled. Rainfall data recorded during this investigation are
shown in Table 1.
TABLE 1. RAINFALL DATA ON CONTROL AND EXPERIMENTAL PLOTS
[Each value is the total amount since the previous date]
DATE
CONTROL (cm)
EXPERIMENTAL (cm)
20 May
1.02
1.27
24 May
1..52
3.81
28 May
0.51
0.25
3 Jun
2.54
1.52
6 Jun
1.02
0.76
17 Jun
0.51
0.00
5 Jul
1.27
2.03
. 6 Jul
3.81
0.76
7 Jul
1.78
0.51
12 Jul
1.02
0.25
20 Jul
3.30
1.27
23 Jul
3.81
1.27
26 Jul
1.52
4.06
31 Jul
6.35
6.86
5 Aug
5.08
3.30
9 Aug
1.78
0.76
11 Aug
0.00
1.78
16 Aug
1.52
4.06
20 Aug
0.00
1.27
Plant-height measurements were taken 31 May, 7 June, 18 June, 9 July, 19 July, and
13 August. Height was considered to be from ground level to tip of uppermost leaf. Twenty
plant heights were measured along rows where more than 20 plants were present; the plants
to be measured were selected randomly except that no more than two measurements per foot
were taken. If 20 plants or less were present, then all plants were measured except on 3 May
when only 10 were measured. Diameter and weight of radish roots were determined on
18 June when they were considered to be mature. The weight of beans produced was determined
as they matured and were harvested, and a cumulative total was run for each plot. No production data were available on tomatoes or peanuts because of insect and worm damage on tomatoes
and vandalism of peanuts. No data were gathered on Bahia grass seed production because these
plants had not matured at the scheduled terminc'tion of the study. The data on experimental
and control plants were statistically compared using the analysis of variance test at the 95, 99,
and 99.5 percent confidence levels.
�SECTION III
RESULTS
A reasonable percentage of the seeds of all species planted for this study germinated.
Quantitative data were not recorded, but no gross differences were detectable in the germination time or percentages between the control and experimental plots. The germination of
cotton seed on both plots was less than that expected, but subsequent tests of seeds from
the same lot under the controlled environmental conditioning of a greenhouse resulted in only
80 percent germination. Seedlings of all species appeared healthy (Figures 4 through 15).
Without exception, the plants on the control plot grew larger, produced more and larger
fruits, and yielded higher weights than those from the experimental plot (Tables 2 and 3).
The differences observed were all statistically significant except those of the bean fruit weight.
Growth measurements of several species showed a reversal on the 19 July measurements, but
this apparently was due to temporary conditions. The first two measurements taken of millet
showed the control to be slightly smaller. This cifference was not statistically significant and
the initial growth rate differential was reversed during the remainder of the time. Control
plants overtook the experimental plants in all grow~h and reproduction aspects before the test
period was ended.
10
�Figure 4. Control Browntop Millet
Figure 5. Experimental Browntop Millet
11
�Figure 6. Control Peanuts
yf ^ •
^™
Figure 7. Experimental Peanuts
12
. •*!(,
'',
1
�<w
>
Jf
'""A.. .
Figure 8. Conirol Beans
Figure 9. tlxperimental Beans
13
�Figure 10. Control Cotton
,€
Figure 11. Experimental Cotton
14
�Figure 12. Control Radishes
Figure 13. Experimental Radishes
15
�Figure 14. Control Tomatoes
Figure 15. Experimental Tomatoes
16
�TABLE 2. PLANT HEIGHT IN CENTIMETERS
30 May
Control
vs
Experimental
4.9 + 2.4(10)
Bahia Grass
I
Millet
Cotton
Peanuts
Radishes
Beans
v s
4.0 + 1.2(10)
9.1 + 5.3(10)
vs
9.9+3.0(10)
6.7+2.5(11)
vs
4.5 + 3.2(7)
6.6+ 2.0(10)
vs
4.2+ 1.1(10)
ns
ns
-l
6.2 + 3.8(10
vs
3.0+ 1.5(10)
, 15.3 + 3.0(10)
VS
Tomatoes
n s
A
' 9 . 5 + 1.6(10)
20.5 + 3.9(6)
vs
ns
20.2 + 2.6(5)
'
7 June
Control
vs
Experimental
12.3 + 2.3(20)
vsi
7.7 + 3.9(20)
25.7 + 10.0(20)
vs
ns
28.2 + 11.1(18)
11.1 + 5.4(11)
vs
ns
6.4 + 3.4(7)
120+3.5(20)
vs
A
/.6 + 1.3(20)
13.0 + 3.6(20)
vs
-i
7.4 + 1.9(20)
27.1 + 3.8(20)
vs
-i
16.3 + 3.0(20)
33.0 + 7.5(6)
vs
ns
27.4 + 3.3(5)
DATES OF MEASUREMENTS
18 June
9 July
Control
Control
vs
vs
Experimental
Experimental
25.1 + 3.6(20)
18.2 + 3.9(20)
vs
A
13.0 + 2.2(20)
44.9 + 10.6(20)
vs
ns
39.8 + 6.4(20)
18.5+9.4(11)
vs
8.0 + 3.9(7)
19.7 + 5.3(20)
VS
a
9.3+ 1.4(20)
32.5 + 3.7(18)
vs
i
19.0 + 3.4(20)
36.1 + 5.1(20)
vs
^
19.6 + 3.1(20)
52.1 + 5.5(6)
vs
-i
37.6+ 1.1(5)
LEGEND
ns = not statistically significant
* = P < 0.05
t = P < 0.01
-i - P < 0.005
P is the probability that the statistically significant difference is due to change.
Numbers are represented as mean ±_ standard deviation
VS
19 July
Control
vs
Experimental
28.7 +4.1(20)
vs
i
23.6 + 4.5(20)
No new growth
A
19.6 + 4.5(20)
60.4 + 9.6(20)
vs
i
50.6 + 6.8(20)
41.2+ 18.1(11)
VS
40.0+21.2(11)
vs
t
14.2 + 5.3(5)
39.8 + 5.5(20)
1
11.9+5.1(5)
37.2 + 5.3(20)
VS
i
19.1 + 2.9(20)
40.9 + 5.0(20)
vs
-i
24.5 + 2.3(20)
80.4+ 10.1(6)
vs
64.8 + 12.7(6)
VS
'
18.1 + 3.9(20)
No new growth
No new growth
A
13 July
Control
vs
Experimental
41.5+4.8(20)
VS
A
28.0 + 5.9(20)
46.9+ 24.1(11)
VS
.
1
17.0 + 5.6(5)
43.5 + 4.7(15)
vs
-1
26.4 + 4.7(20)
�TABLE 3. ADDITIONAL MEASUREMENTS OF RADISHES AND BEANS
Vegetative Structure
Weight (g)
Radishes
Control
vs
Experimental
Beans
Control
vs
Experimental
00
17.5 + 5.3(17
vs
7.1 + 4.1(20)
30.1 + 23.9(20)
vs
15.2 + 6.1(20)
Millet
Control
vs
Experimental
Fruit Weight
(g)
Root Length
i
(cm)
10.0 + 2.6(17)
vs
t
7.9 + 1.6(20)
A
5.4 + 2.0(20)
vs
4.8 + 1.9(20)
ns
0.19 + 0.05(5)@
vs
0.18 + 0.04(5)@
LEGEND
ns = not statistically significant
* = P < 0.05
t = P < 0.01
A = P < 0.005
@ = Each of the five weights contained 100 seeds.
P is the probability that the statistically significant difference is due to change.
Numbers are represented as mean +. standard deviation.
Number in parenthesis is number of plants measured.
Root Diameter
(cm)
20.4 +4.9(17)
vs
15.1 + 5.1(20)
^
�SECTION IV
DISCUSSION AND CONCLUSIONS
This experiment was designed to determine if seeds could germinate, develop into mature
plants, and produce fruit in a barren area that had received heavy applications of herbicides
over a long period of time. It was determined by this work that the level of herbicide
remaining in the area is not high enough to prevent seed germination or growth of sensitive
agronomic plants. The prime factor limiting the seed germination and growth observed during
this experiment was the physical and physiological stresses related to wind and drought on
the plants. The experimental test area was much more open than the control area and strong
winds and moisture stress were more prevalent. Despite measures taken to alleviate the effects
of the wind and artifically supplementing rainfall, the experimental plants frequently were
excessively dry, and the protective windscreen was blown down on several occasions. The
prevailing winds on the experimental plot caused quick evaporation of moisture and formation
of a crust on the upper layer of the soil. Therefore, wind appeared to be the major factor proventing vegetation from returning to the barren area. Seeds falling to the soil from the surrounding plants either do not adhere to the soil sufficiently for germination or the moisture is not
sufficient to support germination and growth.
It is not known if the fruit from the crops grown in this experiment could be used for
human consumption. There is evidence that TCDD can be taken up and translocated in oats
and soybeans (Reference 3). However, no plants or fruit from this experiment were tested
for TCDD uptake. Additional experiments are needed to determine if TCDD or other herbiciderelated residues were present in these plants.
This experiment determined that a wide variety of agronomic plants can reach maturity
and produce fruit in an area that previously has received massive applications of herbicides.
It was believed that environmental conditions other than the residual effects of herbicides were
responsible for less growth of plants on the experimental plot.
Reference:
3. Isenbee, Alan R. and Gerald E. Jones. "Absorption and Translocation of Root and Foliage
Applied 2,4-Dichlorophenol, 2,7-Dichlorodibenzo-p-dioxin, and 2,3,7,8-Tetrachlorodibenzo-pdioxin." J. Aar. Food Chain. 19 (6) 1210 (1971.
19
(The reverse of this page is blank)
��INITIAL DISTRIBUTION
AFSC (DLW)
AFSC (SDWM)
USAF (SAMI)
ASD (ENYS)
AMRL (HEF/Maj Hilgendorf)
AU (AUL-LSE-70-239)
USAF Env Health Lab (CC)
AF (EHL)
Naval Ammo Depot (Code 501-A3)
USNWC (Code 454/N. Rumpp)
USNWC (Code 753 Tech Lib)
« .
Picatinny Arsnl (SMUPA-FR-L)
Picatinny Arsnl (SMUPA-AD-D-R-4)
Deseret Test Ctr Tech Lib
NASC (Code AIR-5323)
USMOS (Tech Lib)
DDC
NASA Mississippi Test Fac (Mr Wolverton)
U of W. Fla. (Dr Hopkins)
Edgewood Arsenal (SMUEA-SA)
ARL (LJ/Dr Tiernan)
AFSC (SO
AFSC (VN)
AFVI/L (DEE)
AFWL (LR)
AFRPL (DYSS/Dr Malone)
AEDC (Mr Hickerson)
NWC Env Eng (Mr. Ouimette)
AMD (RD/Maj Beatty)
USA Natick Lab (Kaplan/Levison)
Gulf Breeze EPA
USAF (SAM)
ASD (ENYEHM)
Ogden ALC (MMNOP)
USA FA (DFLC/Capt A Young)
ADTC (CSV/Maj Conrad)
ADTC (SD/Maj Syarto)
TRADOC (TAWC-LOf
AFATL (DL)
AFATL (DLOSL)
AFATL (DLJ)
AFATL (DLV)
2
1
1
1
1
1
1
1
1
1
1
1
1
1
2
2
12
1
1
1
1
1
2
2
1
1
1
1
1
1
1
1
1
2
3
1
20
21
(The reverse of this page is blank)
�
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
011
Folder
The folder containing the original item.
0095
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Creator
An entity primarily responsible for making the resource
Agerton, Bobby M.
Richard C. Crews
Description
An account of the resource
<strong>Corporate Author: </strong>Air Force Armament Laboratory, Environics Office (DLV), Eglin AFB, Florida
Date
A point or period of time associated with an event in the lifecycle of the resource
1975-01-01
Title
A name given to the resource
A Study of Agronomic Plants Grown on Herbicide-Contaminated Soils: Final Report: May 1974-August 1974
Subject
The topic of the resource
crop production
herbicide application
Eglin AFB
ecological impact
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/94128018f3c5e80d2ee47f4f887143ca.pdf
ade86b65f48332434bc463b69b80c050
PDF Text
Text
Item ID Number:
Author
Corporate Author
00100
Crews, Richard C.
Environics and human Factors Office, Air Force
Armament Laboratory, Eglin AFB, Florida
RODOrt/ArtlClO TltlO Species Diversity Indices of the Fish Populations of Streams Draining Selected Test
Areas on Eglin Air Force Base Reservation, Florida
Journal/Book Title
Year
1976
Month/Day
December
Color
Number of Images
5;
Project No. 5066; Task No. 01; Work Unit No. 001; Report No. AFATL-TR-76-145
Friday, December 08, 2000
Page 100 of 106
�<~
Crews, R. c.,
1976
AFATL-TR-76-145
Species Diversity indices of the
SPECIES DIVERSITY INDICES OF THE
FISH POPULATIONS OF STREAMS
DRAINING SELECTED TEST AREAS ON EGLIN
AIR FORCE BASE RESERVATION, FLORIDA
ENVIRONICS AND HUMAN FACTORS OFFICE
DECEMBER
1976
FINAL REPORT: MAY TO JULY
1976
AIR FORCE ARMAMENT L A B O R A T O R Y
AIR FORCE SYSTEMS COMMAND • UNITED S T A T E S AIR FORCE
EGLIN AIR F O R C E BASE, FLORIDA
�UNCLASSIFIED
S E C U R I T v CL • S S ' f l C A T I O N OF FHI*
t fV,;, Tl
INSTRUCTIONS
BEFORE COMPLETING FORM
'-, C A T A L O G N U M B E R
REPORT DOCUMENTATION PAGE
I. REPORT NUMBER
2. GOVT ACCESSION NO.
AFATL-TR-76-145
4. TITLE fmd Xt
S. T ' i F E OF KE.PGKT & PERIOD COVERED
SPECIES DIVERSITY INDICES 01- Tllfi FISH POPULATIONS
OF STREAMS DRAININC- S'fLECTF.D TEST AREAS ON KGLTN
AIR FORCE BASE RESERVATION, FLORIDA
7
AIJThORf's)
Final Report - May to July
1976
F
Pt'Rf-ORMING ORG. REPORT NUMBER
'fl " COKii R A C T OR GRANT NUMBERCtj"
Richard C. Crews
9
in PPOGPAM ELRMEMT. PROJECT TASK
PER "ORMING O R G A N I Z A T I O N NAMF AND AODRF.SS
APF/l « WORK UNIT NUMBERS
Ilnvironics and Human Factors Office
Air Force Armament Laboratory
Eglin Air Force Base, Florida 32542
Project No.
Task No.
Work Unit No.
1 I. C O N T R O L L I N G OFFICE NAME AND
12. R E P O R T DA TE
Air Force Armament Laboratory
Armament Development and Test Center
Eglin Air Force Paso, Florida 32542
14
5066
01
001
Dccembcr 1976
13
NUMBER OF PAGES
15
S E C U R I T Y CLASS, (ol this trpnrt)
50
MONITORING A G F N C Y NAMC ft "VDORESSdV i l l f t r r e n t from Controlling Oflirf)
UNCLASSIFIED
I5n
DECLASSIFICATION
SCHEDULE
DOWNGRADING
16. DISTRIBUTION ST A TEMEN T (ill this Rrpart)
Approved for public release; distribution unlimited.
17. DISTRIBUTION S T A T E M E N T (nf (he nhxtract xntfrfd In Rlork 20, If different trow Repor'l
IB. SUPPLEMENTARY NOTES
Available in DDC.
19. KEY WORDS (Continue on rf versa sjrfe If nrcefaarv and Irlfintlfv bv blt>rk numbct)
Species Diversity Indices
Fish Populations
Eglin AI-'B Selected Test Areas
Eglin AFD Selected Test Area Streams
20
Aquatic Baseline Data
A B S T R A C T (Continue on rnvrrsf airtr If nacea<;Hry and Identify hy block numh^r)
A baseline study of fishes was conducted in streams draining various test
ranges currently used for testing and evaluation of conventional munitions.
The purpose of the effort was to determine a species diversity index for each
of the streams to be used for comparison data in future studies and for use in
environmental documentation. Twenty-three species of fishes and one lamprey
species were collected or observed. All specimens were preserved fexcept
Etheostoma okaloosac Fowler) and catalogued for placement in the Air Force
DD
1473
EDITION OF 1 NOV 65 |S OBSOLETE
UNCLASSIFIED
�UNCLASSIFIED
5 E C J R I T > C L A S S I F I C A T I O N OF T H I S PAGEflWien Data Entered)
(Item 2Q concluded) Armament Laboratory's fish reference collection. I^any
streams sampled serve as the habitat for an endangered species, the Okaloosa
darter (Etheostoma _oka_loosae Fowler). One hundred and f i fi ecn specimens of
the Okaloosa darter were observed and released unharmed.
UNCLASSllMl-l)
SI ' " i p H I T v <~l_ A S S I F i r « T "»N r*'" T H I S PAr.F'K"
•>
�PREFACE
This technical report discusses a portion of the work performed at the
Air force Armament Laboratory, Armament Development and Test Center, Eglin
Air Force Base, Florida, under Exploratory Development Project 50660101
during the period May 1970 to July 1976.
The sources and manufacturers of materials and equipment used in this
study arc identified for reference onJy and do not constitute endorsement
of the companies or products by the United States Air Force.
This report lias been reviewed by the Information Officer (TO) and is
relcasable to the National Technical Information Service (NTIS). At NTIS
it will be available to the general public, including foreign nationals.
This technical report has been reviewed and is approved for publication.
FOR THE COMMANDER:
A. FARMER
Chief, Environics and Human Factors Office
i
(The reverse of this page is blank)
��TABLli OI: CONTENTS
Section
I
IT
III
Page
Title
1
INTRODUCTION
MATF.RIALS AND METHODS
..
2
28
DISCUSSION
31
REFERENCES
TV
RESULTS
33
OBSERVED NUMBER OF FISH BY LOCATION.
35
Appendix
A
111
�LIST OI: HOJRLS
Figure
1
Title
Collection Station Sl-'-l, Unnamed Tributary of Rocky Creek. .
I'agc
2
Collection Station Sl -2, Unnamed Tributary of Rocky Creek. .
3
4
3
Collection Station SF-3, Rocky Creek
5
4
5
Collection Station SF-d, Open Branch
6
Collection Station SF-5A, Fast Rocky Creek
7
6
Collection Station SF-5B, liast Rockv Creek
8
7
Collection Station SF-6, Unnamed Tributary of Little
Alaqua Creek . . . ,
9
Collection Station SF-7, Unnamed Tributary of Little
Alaqua Creek
10
8
;
Collection Station SF-6, Unnamed Tributary of Little
Alaqua Creek
Collection Station SF-9, Mattress Branch
12
ColJection Station SF-10, Unnamed Tributary of liast
Rocky Creek
13
12
Collection Station 5F-1L, Middle Creek
14
13
Collection Station SF-12, Basin Creek
15
14
Collection Station SF-1.5, Trout Creek
16
15
Collection Station SP-14, Mullet Creek
17
9
10
11
:
r
Jl
16
Collection Station .SI -l. >, Long Creek
18
17
Collection Station SF-16, Hickory Branch
19
7
18
Collection Station SF-1 , Schoolhousc Branch
20
19
Collection Station SI-'-18, Unnamed Tributary of Turtle Creek.
21
20
Collection Stati.on SF-1 9, Turtle Creek
22
21
22
Collection Station SF-20, Indigo Creek
23
Collection Station SK-2!A, Liveoak Creek
24
23
Collection Station SF-21B, Liveoak Creek
25
24
Collection Station SF-22, Bull Creek
26
25
Collection Station SF-23, Ramor Creek
27
.IV
�LIST OF TABLES
Table
1
2
Title
Page
Mean Species Diversity Indices (d) for Each Collection
Station
29
Fish Species Observed During Study
30
v
(The reverse of this paj>e is blank)
��SECT TON I
INTRODUCTION
Since November 1974, Air Force Armament Laboratory (AFATL) personnel
have been engaged in an effort to establish the existing site characteristics
for the following Eglin AFB Test areas: TA B-70, TA B-71, TA C-64, TA C-64A,
TA C-74, TA C-74L, TA C-72, TA C-52N, TA C-52C, and TA C-52A. These test
areas are utilized for the testing of conventional munitions. This effort
was initiated to meet the Council of Environmental Quality (CEOJ guidelines and Air Force regulation requirements to establish the existing site
characteristics of these tesx: areas for environmental documentation.
Many streams originate on, flow through, or otherwise drain these test
areas; therefore, an essential component of any site description is aquatic
baseline data. For this reason, the study reported here was conducted.
Ideally, the aquatic baseline would have encompassed both the aquatic vertebrates and invertebrates, but the lack of qualified personnel limited the
study to the ichthyofauns.. The aquatic baseline study was to be accomplished
on a four-season basis, but the time required to accomplish the overall
program and the other scheduled activities of AFATL personnel restricted the
study to the winter and summer seasons. The winter study was conducted
during November and December 1975, and the data were published in AFATL-TR76-4 (Reference 1).
The approach to this study was to establish the species diversity indices
of streams draining the tost areas previously mentioned, for use in comparing the resulting species diversity indices of future studies on the same
test areas. For locations and descriptions of these test areas and sampling
stations, refer to AFATL-TR-76-4. All identification of species was done by
personnel of the Environmental Research Facility. All specimens were preserved (except Etheostoma okaJoosae Fowler) and catalogued and will remain
at the Environmental Research Facility, Building 574, as a permanent reference collection of these test areas.
�SliCTTON 1 I
MATERIALS AND METHODS
A diversity index study of the fish populations of streams draining
various test areas within the Eglin AFB Reservation was conducted from May
to July 1976. Sampling stations were the same as those used in an earlier
baseline study conducted during November and December 1975 (Reference 1),
except for stations If) and 23 which were changed to alternate sites because
of the ease of accessibility of the new sites and the increased fish popu..ation. The times scheduled for collection of specimens were dictated by
range accessibility due to mission requirements and the other scheduled
activities of AFATL personnel.
T'ish populations of the streams were sampled with a small mesh seine,
and all specimens (except [jthcpstpma okaloosae Fowler) were fixed in 10 percent formalin immediately after capture, held in tap water for 24 hours, and
preserved in 40 percent isopropanol. All specimens were Identified to genus
and species (References 2 and 3) and catalogued for placement in the APATL
fish reference collection.
I'hotographs of each sairpling station were taken for use in environmental
documentation and for use as a basis of comparing stream conditions during
future studies (Figures 1 to 25).
During this study, many of the streams sampled were within the territory
of the Okaloosa darter (Etheostoma okaloosae Fowler), ;m endangered species.
All Okaloosa darter specimens were identified in the field and returned to
the stream. Kxtrcme caution was used to avoid Injury to the specimens and
to minimize habitat disruption.
The mean species diversity (d) indices were determined by the formula
presented by Lloyd, Zar, and Karr:
where C is 3.321928 (converts base 10 log to base 2), N is the total number
of individuals,
of individuals and n. is the total number of individuals in the j t h species
(Reference 4 ) .
�s
r
*£
M« w>*. * 4
p ^ */
«
i
!JS
<,
V !>1j|L
•« v
04
^
1
•t
.ii
»
^
* ; t
i*
i ',
1
,
*
I
; >s
'(.t
°va
:*
C
Wm
s•
*
S if:
^'f
"*:,
*» 1" £.
^-^j^Wi-^ ^'"-- i
iv X*-- -* nf.xji<^
Figure 1. Collection Station SF-1, Unnamed Tributary of Rocky Creek
�Sa&W&iSS '}"fi&-*' ,rSj
''^'^S^WSK^'iSSKff11*
,*„•„". 4fJf v
ms^wSsri^i*1'',. iKffffl
kM'11,' MiV'S^ J:P^'-'J» ^WW i . *!•«
.*" . ,„ , T'-^W* T^"E«.' ™V* , -s»i^
•fl..WrM%'Sfc.A1i1«^i :Vvi'>1lK3*' . K a i l *
'.."?» w^-.., •
'. ;f - **w*au
• ..^-;,r 'j^sS^^.^'-i*
Figure 2. Collection Station SF-2, Unnamed Tributary of Rocky Creek
�l/i
^ >*,-<: %>. wf ^sf-^aii^t^*:^ »*->** J?*V s. ^
Figure 3.
Collection Station SF-3, Rocky Creek
"- "
^
» *
�^'rithg'"
fs
* 4«< 8'S"* V. J8 * **
- h /, H,^^' "^ j;'*S^''i S1-!fl i1™'H^jtS^i*1^''1*
^•;,*:^4a|/i>V.to/^ )<
:•'•W&>3& *&."y^^^fe^xfe,"
'.^l^feM^^e^
^^^'ll^'
Figure 4. Collection Station SF-4, Open Branch
�£%;v -V x^'v^r^-,
»*•
W&3&'
Figure 5.
Collection Station SF-5A, East Rocky Creek
�00
111
' "'
" , ' / ' • '
' Vj.sJfr**
S'i.Uy+ *
"t V',,VA, iS^ua^^.iii.iSi*!!
Figure 6. Collection Station SF-5B, East Rocky Creek
�Figure 7. Collection Station SF-6, Unnamed Tributary of Little Alaqua Creek
�;•',,•;,;.;
,'"' '•"., ' ''•''',
, !.H'^
' "I ;•
;;.; ,/••*,#•,••< . •"
• '''
'. V,,'-" ''**«1, ,','*"•
. | •"„,','" i'Wj' & ' " .'J
'
i
AV•;':•••"•:'. > ,?<:/* : : ^ ^ ': *;t,'':^ ^ v ;
Figure 8. Collection Station SF-7, Unnamed Tributary of Little Ala^ua Creek
�" ••:i.AV-,'SiwS*JI
,-
'^ „ „ " * , . '
™. .* f
•f ;•%&
Figure 9. Collection Station SF-8, Unnamed Tributary of Little Alaqua Creek
�9* c i*&,"
* V
"5 Y "WF8T * * n*s? ,
J.LJ*Sg'
«
fc
,*-
'
^%^^
*
Sk*
BEsrsasasssi
' ' • - '
Figure 10. Collection Station SF-9, Mattress Branch
�Figure 11. Collection Station SF-10, Unnamed Tributary of East Rocky Creek
�Figure 12. Collection Station SF-11, Middle Creek
�Figure 13.
Collection Station SF-12, Basin Creek
�Figure 14. Collection Station SF-13, Trout Creek
�Figure 15.
Collection Station SF-14, Mullet Creek
�fc.
•* .....
m>- - • •- ;•...? :
."iTH:* , "•>'"*,'>. ,tl!H
00
,
^
'
' & - / " V
W i ^ ' '
v' J'1"
"" y:>^
,, ' „:/:""" ! ..',,,,'l;'""":^,¥, , A
?"'%^?^' /,-!":<.''.^" • :: ""^'^v^^
Figure 16. Collection Station SF-15, Long Creek
�Figure 17. Collection Station SF-16, Hickory Branch
�m
*,i * *' !&ij w UM..&
V
i
-SiiMS^: LJJ. .ui!w
NJ
o
•
'
Figure 18. Collection Station SF-17, Schoolhouse Branch
'
*
�'
«'' > ' *
V
„ **; ;•' .• £A
,V\ . '.,***;:f >> *'!";
f ' . ;,*"«
>",
*'! ','Sr |.
"'**'.
r
..-*n|™. *
,
- ,? ^ , .
i- ^ ;•• '
^
>.
* .
,
. .•
• VR^:
,
,. «, -yr
>" >- :• v^ i " ,, •'^,-!r"1""«:r -
-'•
~ '•
,
~ IT ^ r t.1
i'
jsit-^' •
. H-^rrp^ •—'JHfes'tT
"*
«%^
Figure 19. Collection Station SF-18, Unnamed Tributary of Turtle Creek
�i< ^ - ^M
*i&*\!t^
S5**|!f
Figure 20.
Collection Station SF-19, Turtle Creek
�V^ 1 • \/''''\''\ 'i /^'i.vi^lhal^
.'<.••> . . " • '
,
,,
;, , , ' ': % . s ^
^v;,'^«^
7.,, 'L
:
"t.Ji, V.H , ^'a, :>"
,r"|; ' ' ', ^
^ ' ^ *'• >'*
'V'^-V^i?P5
' '•; ,.•'• : ' " , r$" :V< ' '
'"'&
/A
•
L
"""
,
'<'.},, .
I 1 ' ' (*'
,()
, '^ ^ %^N, ,hf
i*& m^m^^^^^^\^ ''$$%
'•^^i^'^iiij^
''"'^f^
"'
.
' . ' '"fl l',.,| " l 1
'^
' '^' :,',
Figure 21.
Collection Station SF-20, Indigo Creek
�Figure 22. Collection Station SF-21A, Liveoak Creek
�i^v, ,.>.«-'; ." >v, .v.B-'iV ' ,*fr.» .••>.
i ^^Jdf^'4-x*, ,1.*.jsJK-:«jj#**.%%..j*; !••€*-"• •
» *^^£^ » , ^ l ;i>
i
S , ,
' ^
v
i
NJ
C.
: ^ ' ^ *>>'"•'*$*« '¥• *•
•'• '=' *i*
?>^;^T^|7.™-'!-» " v
•:Pf»3
>-''"$faim&
Figure 23. Collection Station SF-21B, Liveoak Creek
�• ^ i i
f M e i
jk*^33E*:l?
Figure 24. Collection Station SF-22, Bull Creek
�Figure 25. Collection Station SF-23, Ramer Creek
�SECTION III
RESULTS
The resulting diversity indices for the fish species collected during
this study are given in Table 1. No comparisons between the previous winter
studies (Reference 1) and these summer studies were made because of the
difficulties in interpreting extraneous variables such as the high water
conditions of the streams due to heavy rainfall during the winter months of
1975 and the resulting differences in physical and chemical characteristics
among the various streams.
Twenty-three species of fishes and one lamprey species were collected or
observed during this study (Table 2). One of the fish species, the Okaloosa
darter (Etheostoma okaloosae Fowler), is on the endangered list. One hundred
und fifteen Okaloosa darters were observed in the field, and all specimens
were released unharmed.
The sailfin shiner (Notropis hypselopterus Gunter) was the most abundant
species encountered. Also, the mosquitofish (Gambusia affinis Baird and
Girg.rd), blackbanded darter (Percina nigrofasciata Agassiz), brown darter
(Etheostoma edwini Hubbs and Cannon), speckled madtom (Noturus leptacanthus
Jordan), and spotted sunfish (Lepomis punctatus Valenciennes) were abundant
in most of the streams studied. A list of species collected from each station is given in Appendix A.
28
�TABLL: 1 .
Ml: AN SPI-CTI-S DIVI-RSITY I N D f C I i S fd) l-'OR I:ACII COLLECT TON STATION
COLLI-CTION STATION
d
S l ; - l , Unnamed T r i b u t a r y of Rocky Creek
2.72-1
SI : -2, Unnamed Trib.itary of Rocky Crook
1.981
SF-3, Rocky Crock
1.685
;
Sl -4, Open Branch
1.884
SF-5A, r;yst Rocky Creek
2.019
;
SI -513, Last Rocky Creek
1.423
SI : -6, Unnamed Tributary of Little A1 aqua Creek
0.530
SI-'-7, UunamcJ 1'riiiutary of Little Alaqua Creek
0.875
SF-8, Unnamed Tributary of Little Alaqua Creek
1.544
SF-9, Mattress Branch
1.55.3
1
SI- -10, Unnamed T r i b u t a r y of Last Rocky Creek
1.969
Sr-11, M i d d l e Creek
1.803
SF-12, Basin Creek
1.932
Sr-13, Trout Creek
1.884
;
SI -14, M u l l e t Creek
0.403
SF-15, Long Creek
1.604
SF-16, Hickory Branch
1.846
SF-17, Schoolhouse Branch
1.910
:
SI -18, Unnamed Tributary of Turtle Creek
SF-19, T u r t l e Creek
1.174
1.845
;
SI -20, Indigo Creek
2.386
SF-21A, Liveoak Creek
1.608
S1 ; -21B, Liveoak Creek
2.401
SF-22, Hull Creek
2.839
SF-23, Ramcr Creek
0.774
29
�MSI! S I M i C l l i S OBSr.KVr.D D U R I N G STUDY
TABU'
S c i e n t i f i c Name
Connnon Name
1.
Amhlopl itcs runes t r i _ s
(Rafincsquc)
2.
A£lirodqd«;rii.s_ sa^anus
-•>.
U_as_soiiia ex^e rjg_l_a dej
•1.
]Ukis_soina zonatum
(JoTtlon)
Banded pygmy s u n f i s h
:;.
jirjjnyzon succcta
t'l,ac(:pe s de')
Creek c h u h s u c k c p
6.
liriniy/on t_crmis
(Ap.nss i ? )
S h a r p f i n chuhsuckor
7.
l-.sox amcricanus
(iJnie in.)
Ucdl'in [)c-ckcr-el
rf.
Ijthoostoma o c l w m i
•'•
l[t_li£ostoma okaloosiic
((111 l i a m s )
(Jordon)
(llul)h.s t, C;innon)
(l:owlor)
sp.
Uock bass
I ' i r a f e perch
live PR lades pv»my sun f i s h
Drown d a r t e r
Okaloosa darter
Oranj>«strip(! darter-
1().
l]tli_costonui (llloccn_lra i
11.
l ; undujiis nptti
12.
(^ambi£Si_a al'flr^is
L.'5.
[chtliyomyzoii g£«cj_
M.
l_c_t_aj_urus ii_a_ta_L i_s
(l.i'Sucur)
Ye I low b u l I h c a d
15.
l,cjiom_i_s_ p_uiicta_tus
(Valenciennes)
Spoil e<l s u n f i s l i
10.
Microptcrus s;j_liiioLdcs
17.
MLnytToina nu;l;mo])s
18.
Notroj)ls ha_rpori
10.
NotrojM_s loJ.'scJoj)tc_nj;-L
20.
^o^roi''s sjjjpil'innjs
Jl.
Nqtrajiis_ t_exanus
fCirard)
Weed s h i n e r
22.
Nouirus funchris
( l i i l h e r t d Swain)
B l a c k madtorn
23.
Notiiru^s l_e[)tacantlu.i£
24.
Percina nigrofasclata
(Ajjassiz)
( B a i r d 11 ( l i r a r d j
( l l u h h s d Tr;uitni;ui)
fl.acopede)
(llafiiies(|uei
(I-'ov.'lor)
(dunthcr)
(Itailuy d Suttkus)
(.Jor-Jon)
(Agassiz)
Si a rhead topminnow
Mosquitofish
Southern brook lamprey
Lnrgcniouth bass
Spotted sucker
Kedcyc sliiner
Sa i 1 f i n sli iner
(•'lagt'in shiner
S[)cckled madtom
Blackbanded darter
�SECTION IV
DISCUSSION
During this study the water level of the creeks was low. This was quite
different from water conditions during a similar study clone in November and
December 1975 (Reference I) when the water level was very high because of
heavy rainfall during the last half of that year. The creeks had returned
to or were below normal level at the time this survey was initiated which
could possibly account for the large increase in the number of species
collected.
During this study 115 Okaloosa darters were observed and released. The
Oknloosa darter was placed on the list of endangered species in 1973 because
of the concern over possible habitat disruption and apparent competition
from the brown darter (Etheostoma edwini, Ilubbs and Cannon). The Okaloosa
darter is endemic to Okaioosa and Walton counties, and its known range is
limited to six streams surrounding Valparaiso and Niccville, Florida, which
drain into Toms, Boggy, and Kocky Bayous. The majority of the range of the
Okaloosa darter is located on the Egl.in Reservation except for a small amount
of privately owned acreage in the Valparaiso and Niceville areas. Most of
the range of the Okaloosa darter at Eglin is undeveloped with the exception
of a few cleared test areas (TA C-74, TA C-74L, and TA C-72) and a few
bridges scattered over various range roads. Even in the test areas which
have been cleared of vegetation, the Okaloosa darter appears to be doing
well and has been observed in large numbers. Many range roads crossing
Okaloosa darter streams have raised culverts overlaid with clay, and in
many instances this produces back water causing small impoundments. These
small impounded areas have a reduced water flow, but many Okaloosa darters
nave been observed from around the culverts of these areas. The most serious
problem facing the Okaloosa darter on the Eglin Reservation appears to be
competition from its closest relative, the brown darter. In recent years
the brown darter has invaded the territory of the Okaloosa darter on Rocky
and Swift Creeks. Dr. Mettee (Reference 5) stated that the brown and Okaloosa
darters could be ecological equivalents, and the competition and possible
hybridization could be detrimental to the Okaloosa darter. Observations
during this and other recent field studies indicate that a reduction in the
ratio of Okaloosa darters to brown darters may occur when an Okaloosa
darter territory is invaded by brown darters. During this study the only
brown darter collections in the territory of the Okaloosa darter were on
Hickory Branch. Collections on Hickory Branch during November 1975 (Reference 1) produced 5 Okaloosa darters and 3 brown darters while collections
during this study produced 9 Okaloosa darters and 23 brown darters. It has
been postulated (Refercnc3 6) that, given a situation where only a limited
amount of preferred habitat is available to both species, one species might
outcompcte the other due to shortage of food or space, or a combination of
both. This might provide the explanation for the population reversal mentioned above since Hickory Branch provides a very limited area of habitat
suitable for either of these species.
31
�During the November study (Reference 1), one brown darter was collected
from station SF-2 which is very close to the headwaters of Rocky Creek. Repeated collections in this same area have failed to produce any other specimens of brown darter. This single collection of the brown darter is the
only specimen which has been taken above range road 201 on Rocky Creek. The
next closest collection of the brown darter was obtained from an area on
Rocky Creek between range roads 200 and 201.
On Rocky Creek there are a few road beds with raised culverts, causing
small impoundments, which may prevent a further northward invasion of the
brown darter on Rocky Creek. Work is currently being done to monitor the
streams invaded by the brown darter to evaluate the apparent threat to the
continued existence of the Okaloosa darter. Also, study areas have been
identified by the Okaloosa Darter Recovery Team for determination of the
population densities, critical macro- and microhabitat, life history, and
effective land management techniques to insure the continued existence of
the Okaloosa darter on the Tiglln Reservation.
32
�RF.Fl-RHNCbS
1. Crews, R. C. , Aqua rjjc_ Baseline Survey of Selected Test Areas on
lifilin Air Force Base Reservation, Florida, AFATL-TR-7(>-'1, Eglin Air
Force Base, Florida, January f97.r>.
2. Smith-Vaniz, William I;. , Freshwater Fishes oF Alabama, Auburn
University Agricultural F.xperiment Station, October 1968.
3. Carr, A., ct al, Guide to the Reptiles, Amphibians and Freshwater
Fishes oF Florida, University of Florida Press, 1959.
4. Lloyd, M., et al, On the Calculation of Information-Theoretical
Measures of Diversity.' Am. Mid. Nat. 79(2)=257-272, 1968.
5. Status Report on the Okaloosa Darter,an Endangered Native Fish,
U.S. Fish and Wildlife Service, Division of Technical Assistance, Region
4, Atlanta, CA, September j.974.
6. Mettcc, M. F,, Yerger, R. W., and Crittenden, I!., A Status Report on
the Okaloosa Darter in Northwest Florida, Southeastern Fishes Council
Proceeding, Vol I No. 2, August 1976.
33
(Tlio reverse1 ol : Vliis prige js blisuk)
��APPENDIX A
OBSERVED NUMBER OF FISH BY STATION
Collection
Station
Number
Collected
Scientific Name
2
Rock bass
Ambloplites rupestris
4
Pirate perch
Aphredoderus sayanus
26
Okaloosa darter
Etheostoma okaloosae
52
Mosquitofish
Gambusia affinis
11
Southern brook lamprey
Ichthyomyzon gagei
14
Spotted sunfish
Lepomis punctatus
3
Largemouth bass
Micropterus salmoides
51
Sailfin shiner
NotropisHlypselopterus
19
SF-1,
Rocky
Creek
Common Name
Speckled madtom
Noturus leptacanthus
Blackbanded darter
Percina nigrofasciata
Okaloosa
Etheostoma okaloosae
7
SF-2,
Unnamed
Tributary
of Rocky
Creek
19
darter
t*~~
*--•
Mosquitofish
Gambusia affinis
2
Spotted sunfish
Lepomis punctatus
2
Largemouth bass
Micropterus salmoides
15
Sailfin shiner
Notropis hypselopterus
1
SF-3,
Rocky
Creek
7
Speckled madtom
Noturus leptacanthus
1
Rock bass
Ambloplites rupestris
8
Okaloosa darter
Etheostoma okaloosae
Mosquitofish
Gambusia affinis
1
Southern brook lamprey
Ichthyomyzon gagei
3
Spotted sunfish
Lepomis punctatus
Sailfin shiner
Notropis hypselopterus
19
110
35
�CoJIcct ion
St.-it ion
Number
Co Lice r et[
Sc i cut i f i e Name
Speckled madtom
N_o_turus lopt£ica_nthu_s
28
sr-.s
Common Name
l U a c k h a n d c d d.'irter
Pe re i na n i n ro fa s c_ia ta
16
Okaloosa d a r t e r
rthoostonia okaJ_oos£C
7,
(ConcL M)
SF-4,
Open
Branch
Mosqui r o l ' i s l i
> af i " n is
I
I
Spotted s u n K i s h
l.oj)iM|iis p u n c t a t u s _
10
Sail f i n shiner
No r. r<)|> Ls_ hvjise I ont_ery_s
Speckled niadtom
iNoLurus lejrtacanthus
lilackhundcd darter
SF-5A,
Hast
Rocky
i.; rock
Southern hrook l.nnproy
Pev_e_i_na n i g ro (:as c i;i_ta
IS
Okaloos;.) d a r t e r
38
Mosquito fish
(iamlujsia a_i"Fi_nis
Spotted sun fish
l.eponi_i_s jTimetatu^
.Sail f i n shiner
Ni ) t r o p i s hypselop t eru s^
D J a c k niadtom
Not.urus hjnehrjjj
Speckled madtorn
Notimis_ U|£ta_cant[ms
Ulackhanded darter
Percj.ii a n i g r o C a s c i n t J
n^ okaloosac
�Collection
Stalion
Number
Collected
.Scientific Name
1
Pirate perch
Aphredodcrus sayanus
6
Creek chubsucker
lirimyzon succcta
1
Okaloosa darter
l-ithcostoma okalopsae
y
Mosquito fish
Gambusia at'finis
S a i l fin shiner
Notropis hypseloptcrus
Speckled madt.oin
N'oturus leptacanthus
Dlackbandcd darter
1'ercina nigrofasciata
(Ircek chuhsucker
lirimyzon succcta
Mostjuitof Lsh
(iambusia at'finis
Flag f i n sh.incr
Notropis signipinnis
Mosquitot'ish
(lambusia a f f i n i s
9
[•'lagfin shiner
Notropis slgnipinnis
1
Black madtorn
Noturns funebris
1
sr-31),
I last
Rocky
("reek
Common Name
lUackbanded darter
1'crcina nlgrofasciata
Rrown darter
lithcostoma edwi ni
Mosquitofish
(iambus La affinis
Southern brook lamprey
Ichthyomyzon gagei
Spotted sunfish
Lcpomis punctatus
61
i
Sr-6,
Unnamed
Tributary
of Little Alaqua
Creek
1
20
1
46
Unnamed
Tr i biliary
of F.ittlc Aliiqua
Creek
SF-8,
Unnamed
Tributary
of L i t t l e Alaqua
Creek
�do 1 L e c t i o n
Station
Number
Collcct_e_d
2\
Sal J f i n sh i n c r
No_t.ropj_s hypseloptcrus
I 7 lag f i n s h i n e r
\^o 1 rop i s s i. g lup i nji i s_
I
S[>cckled mad lorn
Not u r n s l e p t a c a n r h u s
1
Sf-9,
M;u. tress
Branch
Sc_icnt i £i c _N_ajne_
56
SI--8
fConcl?d)
(ioininon Name
Blackbandcd d a r t e r
1'orc i n--i ru .i^ro Case J ala
1
Kedf.iii p i c k e r e l
americanus
Okiiloosa d a r t e r
l-.theosl oma t)kj£loosaj;
(lambusKi i H T i n i s
Ve 1 low l)ii I llioad
l_crajjiru.s na_t_a_l is
Sal ll'i n s h i n e r
Nol rop_i s hypsc I optcrus
B l a c k madtom
Not imis I'uncbr i s
Speckled iimdtom
Not wcu s I_c [) t a£_a_nt hus
Blackbandod d a r t e r
£crcin;i nlgrofasoata
Oka Loo. sa darter
litheostoma oka_lo_os_a_e
Mosquitof i s h
llamhusjjj a_f_Lj nj s
Spotted sun Pish
I .cpoin i^ [)imc t a t u s
32
Sail f i n s h i n e r
No_tropLs li>f^s£_lojitc^rus
(>
l ; ]a.L',fin s h i n e r
2.
Speckled madtoni
sr-io,
Unnamed
T r i b u t iiry
of 1-ar.l
Kocky
('rock
10
SI'-11 ,
MiJdle
('.reck
U l a c k h a n d e d darter
13
Mosqui I of ish
1
Southern brook lump rev-
i s s i j n i ) i nn is
Npturus _l_c])t;ican_t|iuj;_
ia ni;..;rol'asc.iala
is^i;i_ a_fl'inls
J_c]iUijono^on_ gageJ
Spot ted s u n f i s h
Sail f i n shiner
Not.£<)pis_ [iy]Tse_l_optcrus
�Col lection
'
'
Number
Collected
Common Name
Scj^ntjJfic Name
Speckled madtom
Noturus loptacanthus
Illackban-Jcd darter
Percina nigrofasciata
1
Pirate perch
Aphrcdoderus sayanus
20
Brown darter
litheostoma cdwini
17
Mosquitof'ish
Gamhusia affinis
Southern brook lamprey
Ichthyomyzon gagci
J3
Spotted sunfish
Lepomis punctatus
120
Sailfin shiner
NotropLs hypsclopterus
3
Weed shiner
Notropis tcxanus
3
Speckled madtom
Noturus leptacanthus
Blackbanded darter
Perc.ina nigrofasciata
1
Pirate perch
Aphredodcrus sayanus
1
livcrfjladcs pygmy sunfish
Kl_assoma evergladei
17
Brown darter
litheostoma edwini.
44
MosquitofLsh
(iambus ia a (-'Finis
Spotted sunfish
l.epomis punctatus
Sai If in shiner
Notropis hypsclopterus
Black madtom
Noturus funebris
Speckled madtom
Noturus leptacanthus
7
(Concl 'd)
15
Ra.s i n
Crock
2.
17
'['rout.
Crock
2
81
1
If)
39
�C o l l e c t ion
Station
Number
Collected
Scicntjjfic Name
P i r a t e percli
Aphrcdoderus sayanus
Brown d a r t e r
1 ithcostoma edw i n i
Moscniitof isli
Uinibu_s_i_a_ a_f_f i n i s
Spotted s u n f i s h
l.epomls punc_tatus
Sailfin shiner
\olrop i s livjKsclopterus
Speckled m u d t u m
Not_u_rus L e p t a c a n t h u s
Okaloosa darter
sr-u,
Mu Hot
("rock
Common Name
l : theostoina o k a l o o s a e
Mosquito i'i sli
(iambus La a f f i n i s
Southern brook lamprey
I c h t h y o m y z o n (ia
Sai I t'in s h i n e r
No^T'op i s hypscLup torus
1.0 111',
Crock
2$
i
4-1
I
Uedeyo s h i n e r
I
Speckled madtorn
Np_turiis Icptacanthus
3
lUnckhandcd darter
1'ercina n i ^ r o f a s c i a t a
sr-i6,
I'i rate perch
Aphrcdoderus sayanus
Hickory
Branch
llodfin [ ) i c k u r c l
l:so_x a m e r i o u n u s
Hrown darter
I.Lhcostoina edw i n i
Okaloosu darter
l.theostoma oka_loosac
Mosquito f i s h
Ci^ainbus ia afl'jni^
8
Southern brook Jainprey
Ichthyomyzoi
•>
Spotted s u n f i s h
l.epomis p_un£t^iLus_
1
l.ari>emouth bass
M L crop t cms saimuidcs
1
Spotted s u c k e r
M i n yt_r em a me 1 u n oji s
1
Redeye s h i n e r
Notropis harpe_ri
S a i l f i n shiner
Notropis hypselopterus
23
i)
37
161
�Collection
Station
Number
Collected
Scientific Name
5
Speckled madtom
Noturus leptacanthus
2
Blackbanded darter
Percina nigrofasciata
2
Redfin pickerel •"**
Esox americanus
9
Okaloosa darter
Etheostoma okaloosae
3
Mosquitofish
Gambusia affinis
1
Spotted sunfish
Lepomis punctatus
3
Spotted sucker
Minytrema melanops
100
Sailfin shiner
Notropis hypselopterus
14
Flagfin shiner
Notropis signipinnis
1
Black madtom
Noturus funebris
4
Speckled madtom
Noturus leptacanthus
28
Blackbanded darter
Percina nigrofasciata
2
Starhead topminnow
Fundulus notti
Mosquitofish
Gambusia affinis
1
Yellow bullhead
Ictalurus natalis
7
SF-16
Common Name
Spotted sunfish
Lepomis punctatus
4 -
Mosquitofish
Gambusia affinis
1
Southern brook lamprey
Ichthyomyzon gagei
21
Sailfin shiner
Notropis hypselopterus
52
Flagfin shiner
Notropis signipinnis
1
Black madtom
Noturus funebris
4
Speckled madtom
Noturus leptacanthus
(Concl'd)
SF-17,
Schoolhouse
Branch
SF-18,
Unnamed
Tributary
of Turtle
Creek
SF-19,
Turtle
Creek
26
41
�Collect ion
Station
Number
Collected
Blackhandcd darter
PCreina n.ij>ro fas data
ttock h;iss
Ami) I op 1 i tes
Pi rut o perch
II
.Sc_Lcntj I'i_c N;uiic
A]ihredodenis sa\ - £nus
Brown il.irVor
l_!_Hicost()iiui edwin i
^lo.'jijiii l o F i sh
SF-19
Common Name
( iu m h us i a a l: L n i s
fConcl'd)
SF-20,
IndLpo
('reek
J8
rupestj Ls
Southern brook lamprey
Spotted .sunl'ish
1
28
l,£jioinLs jumctatiis
lied eye s h i n e r
Not_rop i s hjj rper i
l:laul:in sliincr
j) s sj. £n iji i nn i s
1
Weed slilner
N'ojt rop i s t cxaniis
2
H I n e k mud torn
Noturus f n n e l i r i s
•I
Speckled m.idtom
Np_tu rus ]_cjit acaji L hus^
lUackb.'indcd darter
Pore ma ulnrol'asc i a t a
I ' i r a t e perch
.\phrcdod_cnis St)yanus_
I'.vcri;lades py^my : ; u n f i s l i
l.lassoma evert;ladci
Mo s q u i t o f i s li
(Iiimhusj a ;i_f firi j_;>_
Black madtoir.
Njpturus_ fiine_l)_ri_s
S j i c c k l c d :nadtom
Noturus l e p t a c a n l bus
bl>ickl)cinded darter
I'ercina n i p , r o F a s c i a t a
5'J
SI:-21A,
Livcoak
Crook
�Collection
Station
Number
Collected
Scientific Name
1
Rock bass
Ambloplites rupestris
1
Pirate perch
Aphredoderus sayanus
3
Everglades pygmy sunfish
Elassoma evergladei
3
Sharpfin chubsucker
Erimyzon tenuis
7
Brown darter
Etheostoma edwini
6
Mosquitofish
Gambusia affinis
3
Southern brook lamprey
Ichthyomyzon gagei
5
SF-21B,
Liveoak
Creek
Common Name
Spotted sunfish
Lepomis punctatus
Blackbanded darter
Percina nigrofasciata
2
Pirate perch
Aphredoderus sayanus
5
Banded pygmy sunfish
Elassoma zonatum
2
Redfin pickerel
Esox americanus
Brown darter
Etheostoma edwini
Orangestripe darter
Etheostoma (Ulocentra) sp.
Mosquitofish
Gambusia affinis
2
Southern brook lamprey
Ichthyomyzon gagei
1
Yellow bullhead
Ictalurus natalis
2
Spotted sunfish
Lepomis punctatus
10
Flagfin shiner
Notropis signipinnis
1
Speckled madtom
Noturus leptacanthus
28
SF-22,
Bull
Creek
12
2
16
43
�Co 1 lect ion
Station
SF-23,
K. liner
Creek
Number
Collected
Common Name
Sc. iont i fic_Nam«
1
Red Fin pickerel
lisox americanus
2
Drown darter
lithcostomn cdv^ini
4
Mosquito fish
(Iambus i a |i£{_i-_n_i s
2
Southern brook lamprey
Ichthyomyzon gat;ei
riagfni shiner
Notropis si g n i p i n n i s
Weed s h i n e r
Not roj) i s t_exanus
91
�INITIAL DISTRIBUTION
DDC
11
AUL (AUL/LSE-70-239)
1
ASD/ENn-A
1
TAWC/TRADOCLO
1
USA!1/SAM I
1
AFATL/DL
1
AFATL/DLOSL
9
Ogden ALC/MMWM
2
AFIS/INTA
I
Vegetation Control Div (SARIiA-CL-V)
1
I)DR£U'./Tech Lib
I
HSAFA/DFCBS
1
AFLC (I)S)
1
Deseret Test Con/Tech Lib
1
AFLC/MMNO
1
SAAMA/SFQT
1
Naval Weapons Cen/Tech Lib
1
Nuval Weapons Lab/Tech Lib
I
US Dept of Agriculture/Pesticide Coord 1
Agricultural Environ Qua I Inst/ARS
1
AFSC/SDW
1
AF/RDP
1
DDU5E(Env f, Life Sciences)
1
SAMUI-A-SA
1
AFSC/DtV
1
AHDC/DEN
1
HA (SAREA-TS-L) Tech Lib
L
FA (SARF.A-CL-V)
1
CINCPAC (J3AL)
1
USAJ: (Environ Health Lab)
1
NASA Mississippi Test Facility
I
Univ of West Florida
1
Tall Timbers Research Station
1
US Dept of Agriculture,
1
Forest Service/Eastern Region
ADTC/CSV
1
ADTC/DLV
10
NWC Env Eng
1
AMD/RD
1
USA Natick Lab
1
Gulf Breeze EPA
1
AMRL (THE)
1
AI;CEC/EQ
1
Game and Freshwater Fish Com
1
Archbold Biological Station
1
AMRL/TIIT
ADTC/DEN
ADTC/SGPH
45
(The reverse of this page is blank)
��r
ADTC
MAIL"
v
''C,\ PENALTY
\Fot?
~ FE8-4'77?!PR;l-'ATE
il c
.=33;
EGLIN AFB, FLA. 32542
'S.MET£fl j
63*878
OFFICIAL BUSINESS
PENALTY FOR PRIVATE USE MOO
USAFA/DFCBS
USAF Academy
CO
L
J,
�
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
012
Folder
The folder containing the original item.
0100
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Creator
An entity primarily responsible for making the resource
Crews, Richard C.
Description
An account of the resource
<strong>Corporate Author: </strong>Environics and Human Factors Office, Air Force Armament Laboratory, Eglin AFB, Florida
Date
A point or period of time associated with an event in the lifecycle of the resource
1976-12-01
Title
A name given to the resource
Species Diversity Indices of the Fish Populations of Streams Draining Selected Test Areas on Eglin Air Force Base Reservation, Florida
Subject
The topic of the resource
fish population
ecological impact
herbicide application
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/48ff1ae247f821790605c56f64d84fd4.pdf
de4427b1eef4aaab0bb5b208bf846c5b
PDF Text
Text
Item ID Number:
Author
00100
U.S. Air Force Communicati
Corporate Author
Headquarters, U.S. Air Force, Air Force Data Services
Center, Air Force Communications Service
RBpOPt/ArtiClB Title
Herbs Ta
Pe: Defoliation Missions in South Vietnam, 1965-1971. Data by Province.
Journal/Book Title
Year
Month/Day
Color
Number of Images
497
DOSCrlpten Notes
Included with the Herbs Tape printout is a memo from the veterans Education Project
explaining how to use the printout.
Thursday, December 28, 2000
Page 108 of 157
�MEMO ON OBTAINING AND USING
HERBS TAPE PRINTOUT
' The HERBS tap* is a computerized record of the
aerbicidc spraying missions conducted in Vietnam
between August 1965 and February 197]. It is a record of
approximately 86 percent of the missions conducted by
the Air Force. Using these records is one way to establish
exposure to Agent Orange.
Note^ however, that these records do not include
locations of those areas sprayed from trucks or by hand.
Just because exposure cannot be documented with the
HERBS tape printout does not prove there was no exposure.
The Air Force has stated that a typical spraying
mission covered a path 280 feet wide by 8.7 miles. No
data within the printout indicates possible drift of the
spray due to winds. Some estimates state the drift could
have been 20 kilometers (12 miles). In addition, the
veteran would not have to have been in the path of the
mission on the same day the mission was conducted.
Exposure may have occurred if the veteran had been in
the area up to 30 days after the mission. Clearly, the
means of being exposed are not limited simply to being
sprayed directly.
TO OBTAIN THE PRINTOUT AND MAPS
Direct a Freedom of Information Act request to:
Office of the Assistant Secretary of
Defense (Health Affairs)
ATTN: Captain Peter Flynn
Department of Defense
Washington DC 20301
.. .
Vietnam portion of the maps for Si2 (pre-paid; write
VEP, 1346 Connecticut Avenue NW, Washington DC
20036).
EXPLANATION OF DATA IN PRINTOUT
Each page of the printout is broken down into nine
columns. The headings and their explanation follow:
DATE:
CTZ: Combat Tactical Zone or Military Region (1, 2. 3
or 4)
MISSION:
Director, DMAODS
ATTN: DDCP
6500 Brooks Lane
Washington DC 20315
Order the following four maps to cover all of South
Vietnam:
..«^
Stock
Stock
Stock
Stock
No.
No.
No.
No.
1301XND4849
1301XNC4849
1301XNE48
1301XNE49
/ou can expect a 4-6 week delay.
The Veterans Education Project also will provide the
day-by-day printout and xeroxed copies of the South
Mission project number
AGN: Type of herbicide (0 for Orange; B for Blue; W
for White)
GALS: Number of gallons of herbicide sprayed during a
mission
TYP: Type of mission flown (C for crop mission/fixed
wing and helicopter; D for defoliation/fixed wing only; E
for enemy ground supply route/helicopter only; F for
friendly line of communication/helicopter only; P for
perimeter of military installation/helicopter only; S for
enemy cache site/helicopter only; W for waterway/landing zone/helicopter only
AREA:
LEG:
Printouts from the tapes have been produced in two
formats: one is a 316-page listing day-by-day of the
missions; the other is a 448-page listing by province of the
missions (and within each province, day-by-day).
Map's that show the Universal Tranverse Mercator
grids are necessary to be able to plot the missions.
Captain Flynn may be able to send them. An alternate
source is the Defense Mapping Agency. Send $7.40 (in a
check payable to the "U.S. Treasurer") to:
year, month, day
Calculated area in hectares of area sprayed
Mission leg (see more detailed explanation beto «•)
UTM: Universal transverse mercator grid coordinate
(see more detailed explanation beto w)
MORE DETAILED EXPLANATION OF COLUMN
HEADINGS "LEG" AND "UTM"
In providing a more detailed explanation of these two
categories of data, readings from page 2 of the day-byday printout for August 15, 1965, are used.
LEG
1A
18
UTM
Y0350155
YD450150
1A means the starting point of the first spraying mission.
Some flights may have had two drops or there may have
been more than one flight on that day; the beginning
point of the second drop would be designated 2A.
18 is the ending point. Some missions might not have
been in a straight line like this one; they might include
turns designated C or D and so on. The ending point then
would be the last alphabetical letter on that mission.
MAR-APR 1980
DISCHARGE UPGRADING NEWSLETTER
7
�YD is the label for the square on the map in which the
mission began; these labels are peculiar to maps marked
,/~~f{ with universal transverse mercator grids. The squares
» the maps provided by DOD measure 100,000 by
100,000 meters.
350155 is the geographic coordinate (within square YD)
for the start of the mission. The six-digit figure is actually
two 3-digit coordinates; the first three digits mark the
distance.along the horizontal axis; the second three digits
mark the distance along the vertical axis.
450150 is the coordinate for the end of the mission. A
line drawn between these two points produces the flight
path of the mission.
The following steps are designed to enable the
reader to plot the spraying missions and assist the
veteran document exposure to Agent Orange. They
are based on using the day-by-day printout and the
maps noted above. These suggestions will change as
better maps become available or other methods of
using the printout are developed.
NOTE: Useful mechanical aids in working with the
maps are rwo 6-inch clear plastic rulers with metric
marks on them. The centimeter marks on the ruler
match the grid marks in each square on the maps.
oTEP 1: FIND VETS POSITlON(s) ON MAP
Any map of Southeast Asia can be used—as long as the
UTM grid squares are overlaid on it (or you can transfer
a location on another map to a UTM map). The vet needs
to either point to a location or locations on a map or else
have some other recollection of an operation or unit's
name that can be tied to a specific location.
One major problem with the maps we have now is that
NO American-named base camps or fire bases, etc., are
shown on them; these maps show only Vietnamese names
for villages and geographic features. You also have to use
a separate key to determine names of provinces. Other
maps showing locations of divisions and companies may
be available. Even if those maps do not have UTM grids
on them, it may be possible to "transfer" the location to
a UTM map.
It may also be possible to locate in the veteran's service
records a list of operations in which he participated or
units to which he was attached. With such a list, it then
may be possible to either make an official request to the
Defense Department for"*the UTM coordinates of the
operation or unit or to request copies of those operation
or unit records.
The bottom line needs to be pinpoints on the map with
corresponding dates the vei was there.
TEP 2: LOCATE VETS POSITION IN THE
PRINTOUT
Flr»t, itan with those pages of the printout
corresponding to the dates of the vet's tour of duty.
»
DISCHARGE UPGRADING NEWSLETTER
MAR-APR 1980
However, as noted before it's unclear how long dioxin
may remain in the soil or water; you may want to review
the previous 30 days for spraying missions.
Sacond, scan the 2-lctter labels in the UTM column for
the label of the squares within which the vet was located.
Third, once you've located the square's label in the
printout, plot the spraying missions and mark them on
the map as explained in Step 3.
STEP 3: PLOT SELECTED SPRAYING MISSIONS
As noted above, the six-digit UTM is actually two 3digit coordinates; the first three digits mark the distance
along the horizontal axis; the second three digits mark the
distance along the vertical axis.
Ffrst, because of the scale of these maps (1:1,000,000).
round-off to the nearest zero and eliminate the last digit
of the horizontal and vertical coordinates within the
squares selected. In the example used above (starting
point of YD 350 155 and ending point of YD 450 150)
that would mean horizontal axis measurements of 3.5
and 4.5 and vertical axis measurements of 1.6 and 1.5).
Second, use the ruler and the rounded off, 2-digit
coordinate for the starting point to move along the
bottom line of the square (the horizontal axis) to the 3.5
mark. Then use the second ruler to move up on the
vertical axis to the 1.6 mark. Mark the intersection of the
rulers with an "x."
Repeat this for the mission's ending point (4.5 and
1.5). Draw a line between the points. This line, then.
plots the flight of that spraying mission.
Drift of the spray due to winds may have been up to
20,000 kilometers (2 centimeters on the map).
H
VA POLICY REGARDING
"ALLEGATION OF EXPOSURE"
Early in April a change to DVB Circular 21-80-1
(February 7, 1980), "Review of Agent Orange
Exposure Gaimants," was issued to all VA Regional
Offices. The change added the following paragraph:
"4. It is VA policy to resolve any reasonable doubt
in favor of the claimant. Consistent with this policy,
given the considerable uncertainties as to the
deposition of defoliants in Southeast Asia and troop
positions at pertinent times, we will accept in the
absence of positive evidence to the contrary a
Vietnam veteran's contention of exposure. . . . If
there is positive evidence that veteran could not have
been exposed, such as a headquarters assignment in
Saigon or a desk job at the Da Nang Air Force Base,
such facts should- be cited. Otherwise it will be
assumed that veteran was exposed to defoliants as
alleged and the claim for service connection will be
resolved on the basis of the relationship of the
disability in question to such exposure."
�~\
r
HEADQUARTERS
UNITED STATES AIR FORCE
j
L_
PSEPARED ECf
AIR PDECE CftTA SE3WICES
AIR FORCE OMIJNICMTCNS SEEWICE
�UNCLASSIFIED
MISSIONS STARTING IN
DATE
650817
650817
650S19
650819 .
65081C
650819
650819
650821
650821
650821
650821
650903
650903
650906
650913
650913
650921
660316
660316
660316
660316
660317
660317
660317
660317
660317
660317
660317
660317
660317
660317
660317
660318
660318
660318
660318
660313
66032.1
660322
660322
660322
660322
660322
660322
660322
660323
660323
660323
660323
660324
AGN
0
0
0
0
0
0
0
0
0
0
0
0
n
0
0
0
n
QUANG TRI
TYP
GALS
1250
C
0
1200
C
0
0
0 •
0 "- •.. -..
1600
c
0
0
0
1150
c
0
1000
c
550
c
0
1000
D
3000
C
0
0
0
3000
c
0
0
0
3000
c
0
0
3000
c
0
0
0
2000
c
.. 0
0
0
0
2000
c
1500
c
0
0
3000 •
0
0
0
0
n
3000
0
0
0
200J
D
PROV NO. =
LEG
1A
IB
1A
IB
2A
2B
2C
1A
IB
1C
ID
1A
IB
1A
1A
IB
1A
1A
IB
1C
ID
1A
IB
1C
ID
1A
IB
1C
1A
IB
1C
ID
1A
IB
1C
ID
IE
1A
1A
IB
1C
1A
IB
2A
23
IA
18
2A
2B
1A
UTM
YP195131
YD140240
Y0222193
YD194208
YD161229
YD150250
YD175241
YD170110
YD250180
YD170270
YD100210
YD095240
YD080330
YD100320
YD2 10300
Y0270330
YD158400
YD060160
YD220160
YD220050
YDH0050
YD0522S.7
YD097265
YD160312
YD089334
YD260410
YD320340
YD230330
YD202107
YD140148
YD150145
YD170112
X0980350
YD160350
YD160290
Y0000290
XD980300
YD050420
YD040140
YD090120
YD085160
YD135400
YD190375
YD190395
YD240420
YC192384
YD194395
Y0125413
YD134400
YD130420
�MISSIONS STARTING IN
DATE
660324
6603.24
660324
660324
660324
660324
660331
660331
660407
660437
660409
660409
660415
660415
660415
660415
660422
660422
660422
660422
660422
660428
660428
660428
660428
660429
660429
660505
660505
660602
660602
660604
660604
660605
660605
660605
660605
660610
660610
660830
660830
660830
660S30
660830
660906
660906
660909
660909
660909
660909
AGN
0
0
rj
0
0
0
0
0
0
0
0
0
0
0
0
0
n
GALS
0
0
0
2000
0
0
2000
0
100
0
1000
0
1900
0
0
0
1100
0
0
0
0
2000
0
0
0
1000
0
1000
0
1000
0
1000
0
2000
0
0
0
2000
0
3000
0
0
0
0
2000
0
3000
'• 0
3000
0
PROV NO.
QUANG TRI
TYP
D
C
0
D
C
C
D
0
0
D
D
D
D
D
0
D
D
LEG
IB
1C
ID
1A
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
2A
28
1A
IB
2A
2B
2C
1A
IB
1C
ID
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
10
1A
IB
1A
IB
1C
2A
28
1A
IB
1A
IB
1A
IB
UTM
YD197410
YD195400
Y0130415
YD137392
YD140430
YD190370
YD225185
YD220230
Y0220410
YD200390
YD120420
YD160420
YD110050
YD135125
YD190110
Y0210065
YD160305
YD096327
Y0040285
Y0045265
YD0002S5
YD200420
Y02 52449
YD201415
YD253446
YD203413
Y0257437
YD135415
YD200420
YD120420
Y0200400
Y0120420
YD200400
X0990470
XD990440
Y0020470
YD020440
YD130417
YD190405
*Q685456
XD660470
XD660538
XD670570
X0670490
XD665542
XD665466
X0665453
XD730477
XD666478
XD731480
�UNCLASSIFIED
MISSIONS STARTING IN
DATE
660911
660911
660911
660911
660911
660911
660911
660911
660911
660911
660911
660912
660912 •
660912
660912
660912
660912
660912
660912
660912
660912
660912
660912
660913
660913
660913
660913
660913
660913
660913
660913
660913
660913
660914
660914
660914
660914
660914
660914
66'0914
660914
663914
660914
660914
660914
660914
660915
660915
660915
660915
AGN
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
QUANG TRI
************
TYP
LEG
GALS
1A
1500
0
IB
0
D
1A
3000
0
IB
2000
D
1A
0
IB
0
2A
0
28
0
2C
2000
D
1A
0
IB
3000
D
1A
0
IB
0
1C
2000
C
1A
0
IB 2000
D
1A
0
IB
D
3000
1A
0
IB
2A
0
0
26
0
2C
3000
D
1A
0
IB
3000
D
1A
0
IB
0
2A
0
28
3300
0
1A
0
IB
0
24
0
28
2100
D
1A
" 0
IB
0
2A
0
26
0
2C
2700
0
1A
0
IB
2200
D
1A
0
IB
0
2A
0
2B
D
2700
1A
0
IB
2700
D
1A
0
IB
2A
0
0
2B
PROV NO, =
UTM
XD660535
XD730517
XD665525
XD730513
XD701557
XD705548
XD713543
XD710555
XD720540
YD152398
YD183377
XD663455
XD665475
XD689465
XD693580
XD685560
XD754570
XD770535
XD530680
XD530695
X0560698
XD560708
X05 77690
XC730575
X0715577
XD767580
XD780540
X0813560
X0780560
XD735546
XD728536
X0700538
XD700558
XD700570
X0710580
XD730576
XD745540
X0735540
X0762560
XD742536
XD660580
XD680580
XD655555
XC690555
XD728573
XD740540
XD660556
V0695540
XD660536
XD695530
�DAT?
660915
660915
660915
660915
660915
660915
660915
660915
650915
660915
660915
660916
660916
660916
660916
660917
660917
660917
660917
660917
660917
660917
660917
660918
660918
660918
660918
660918
660918
660918
660918
660918
660918
660918
660918
660918
660919
660919
660919
660919
660919
660919
660919
660919
660919
660919
660920
660920
660920
660920
A9N
a
0
0
0
0
0
0
0
0
0
0
0
o'
0
0
GALS
0
2700
0
0
0
2700
0
1600
0
0
0
3400
0
0
0
2550
0
0
0
2700
0
2650
0
1800
0
0
0
0
3000
0
3000
0
1800
0
0
O
1300
0
0
2700
0
0
0
1300
0
0
1800
'- 0
0
0
TYP
D
p
LEG
2C
1A
IB
2A
2B
1A
IB
D
D
C
D
D
D
D
D
0
C
C
0
C
1A
IB
2A
26
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
2A
28
2C
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
1C
1A
IB
2A
2B
1A
IB
1C
1A
IB
2A
2B
UTM
XD684540
XD690530
X0690480
XD660480
XD660530
XD840561
XD872580
XD71.0479
X0710510
X0690513
X0690475
X0740570
X0750570
XD740550
XD750550
YD050350
Y0150320
YD050320
YD110290
X0810580
XD850530
XD800570
X0780570
XDS20530
XD850530
XD870540
XD870580
XD810580
XD700580
X0780580
XD810550
XD740550
X0820530
XD850530
XD810580
XD870580
YD130240
YD030260
YD030270
YD000430
Y0010400
YD000030
YD000340
YD043493
YD130454
YD152524
YD030170
YD130170
YD030270
YD130270
I
�UNCLASSIFIED
DATE
660920
660920
660920
660920
660920
660920
660920
660920
660923
660923
660923
660923
660923
660923
660923
660923
660923
660923
660923
660923
660923
660923
660924
660924
660924
660924
660924
660924
660924
660926
660926
660926
660926
660926
660926
660926
660926
660927
660927
660927
660927
660927
660927
660927
660927
660928
660923
660928
660928
660928
AGN
0
0
0
0
0
0
0
0
0
0
0
r>
0
0
n
0
0
0
QUANG TRI
******
******
LfG
TYP
GALS
1A
C
1800
IB
0
2A
0
2B
0
1A
1800
C
IB
0
2A
0
28
0
1A
D
1800
IB
0
1A
D
1800
IB
0
1A
D
1800
IB
0
1A
D
1800
IB
0
2A
0
2B
0
3A
0
38
0
4A
0
48
0
1A
D
1800
IB
0
2A
0
2B
0
1A
D
1800
IB
0
1C
0
1A
3000
C
IB
0
1A
1350 •
C
IB
o "- • - —
1A
1800
D
IB
0
1A
D
3000
IB
0
1A '
D
2420
IB
0
1A
D
1800
IB
0
1A
0
1800
IB
0
n
1A
3000
13
0
1A
D
3000
IB
, 0
1A
D
1800
IB
0
1C
0
PROV NO. =
M I S S I O N S S T A R T I NIG IN
G
UTM
YD170270
YD140240
YD210170
YD240200
YD290020
YD340020
YC310910
YC420910
XD747610
XD795634
XD738600
XD779605
XD700637
XD810638
XD660580
XD662635
XD660635
XD662580
X0698638
X0660638
XD702632
XD660635
XD660600
XD660580
XD700610
XD700590
XD700605
XD715625
X0663618
YD080160
YD150120
YC560790
YC570870
XD8 15640
XD940635
XD870546
YD015623
XD815634
X0840620
XD810640
XD900620
XD905628
YD005650
XD870545
YC020630
XD796605
XD844618
XD845594
XD845617
XD865617
�UNCLASSIFIED
MISSIONS STARTING IN
04TE
660928
660928
660928
660928
660929
660929
660929
660929
660929
660930
660930
660930
660930
661001 .
661001
661001
661001
661002
661002
661003
661003
661004
661004
661004
661004
661004
661004
661007
661007
661007
661007
661008
661003
661008
661008
661008
661008
661011
661011
661011
661011
661011
661011
661011
661011
661012
661012
661012
661012
661012
AGN
0
0
0
0
Q
n
0
Q
0
0
0
0
0
0
0
0
Q
vv
W
W
W
GALS
1800
0
1750
0
1800
0
0
2000
0
1300
0
3000
0
1800
0
2000
0
1800
0
1000
0
2700
0
2500
0
1800
0
2000
0
1000
0
1840
0
0
0
1700
0
2600
0
0
0
1800
0
0
0
2400
0
0
0
1800
PROV NO. =
QUANG TR I
TYP
D
D
D
D
D
D
C
D
D
D
C
c•
C
C
c
c
c
D
D
P
0
LEG
1A
IB
1A
IB
14
IB
1C
1A
IB
1A
IB
IA
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
2A
28
1A
IB
2A
2B
1A
IB
2A
2B
1A
UTM
XD810640
XD903621
XD880574
XD910566
XD770580
XD780608
XD797599
XD740620
X0780640
YD131540
Y0095550
Y0044500
YD050524
XD705635
X0660624
XD720609
X0710633
• XD720594
X.D743586
XD710625
XD670615
YD080160
YD150220
YD087120
Y0220130
YC670850
YC700890
Y0570175
Y0400150
YC820850
YC880860
Y0348038
YD365040
YD252122
YD273120
YC885840
YC882750
YD120460
Y0145525
YD045503
Y0130460
YD050515
YD100485
YD1 10430
YD135525
X0970600
XD970605
YD010620
YD010625
X0970613
UNCLASSIFIED
�MISSIONS STARTING IN
QUANG TRI
$$ £ } * * * *
£ : : * * *
0-1TF
661012
661012
661012
661013
661013
661013
661013
661013
661013
661013
661013
661013
661013
661013
661013
661013
661013
661013
661013
661014
661014
661014
661014
661014
661014
661014
661014
661016
661016
661016
661016
661016
561016
661016
661016
661016
661016
661016
661016
661016
661016
661016
661016
661026
661026
661026
.661026
661103
661103
661103
AGN
D
0
0
0
W
W
W .
W
GALS
0
0
0
1800
0
0
0
2700
0
0
0
1800
0
0
0
2700
0
0
0
1800
0
0
0
1803
0
0
0
1SOO
0
0
0
1400
0
TYP
D
C
D
D
D
D
o
D
b
W
W
0
2700
0
0
0
1800
0
0
D
P
0
W
W
2700
0
0
0
1800
0
0
D
r>
LEG
IB
2A
28
1A
IS
2A
28
1A
IB
2A
2B
1A
IB
2A
26
1A
IB
2A
2B
1A
IB
2A
2B
1A
13
2A
28
IA
IB
2A
2B
1A
IB
2A
2B
1A
IB
2A
28
li
IB
2A
28
. 1A
IB
2A
28
1A
IB
2A
UTM
XD978613
XD970649
XD97S649
XD970610
XD936623
XD970620
XD940&30
XD9T8610
XD986612
XD976659
X0988658
XD990610
XD990653
YD000618
Y0000653
X0936624
XD970610
XD929613
XD9&9599
XD958589
XD915603
XD940605
X0917597
X0970618
XD970657
X0955620
XD955655
YD000632
Y0037649
YD000645
YD035660
XD930643
XD955625
XD935&22
XD955652
X0882578
X0936584
XD685535
XD922570
YD002620
Y0002654
YD040670
YD040t>35
XD890590
XD945583
XD890580
XD980552
X0900630
XD900640
X0930640
�DATE
661103
661104
661104
661105
661105
661109
66110?
661109
661109
661110
661110
670127
670127
670205
670205
670205
670205
670205
670206
670206
670206
670206
670206
670217
670217
670217
670221
670221
670222
670222
670314
670314
670315
670315
670315
670315
670316
670316
670316
670316
670317
670317
670317
670317
670319
670319
670320
670320
670321
670321
AGN
W
W
W
W
W
0
W
W
a
W
W
Q
0
W
B
0
W
n
0
n
GALS
0
2700
0
2700
0
1800
0
1800
0
2700
0
1800
0
1800
0
0
0
0
5400
0
0
0
0
2700
0
0
2700
0
2700
0
1800
0
1800
0
0
0
1800
0 '
900
0
900
0
900
0
2700
0
3600
0
1800
0
TYP
D
D
n
D
D
D
D
D
D
D
0
D
D
D
D
D
D
D.
P
D
LEG
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1C
ID
IE
1A
IB
1C
ID
IE
1A
IB
1C
1A
IB
1A
IB
1A
IB
IA
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
UTM
XD940620
XD700635
XP840630
XD660605
XD622710
X.D729576
X0690597
X.08 00600
XD960595
XD8 84609
XD935610
XD700620
XD812623
XD880670
X0930660
XD980678
YD080700
YD100740
XD880664
X 09 3 065 4
X.D980672
Y0080694
YD100734
Y0070620
YD080690
YD102740
XD880660
X0960650
XD800660
X0880660
XD800660
XD880660
XD700640
X0657640
XD 70 5 65 7
XD657657
XD763640
XD700640
XD763640
XD700640
XD850648
XD930643
XD850648
XD930648
XD770660
y 066 0660
XD765653
XD657658
XD770650
^0850660
�)G
MISSIONS STARTING IN
PROV NO,
QUANG TR I
* * * *
* * * :
9ATE
670322
670322
670322
670322
670322
670322
670325
670325
670325
670325
670325
670327
670327
670329
670329
670402
670402 .
670402
670402
670403
670403
670422
670422
670427
670427
670427
670427
670429
670429
670430
670430
670430
670430
670430
670430
670501
670501
670501
670501
670502
670502
670502
670502
670502
670502
670503
670503
670503
670503
670504
AGN
0
W
0
0
W
0
0
0
0
0
o
0
n
0
G
oo
0
n
0
0
GALS
1800
0
1800
0
0
0
2700
0
1500
0
0
3300
0
1860
0
2200
0
2700
0
1800
0
2630
0
2790
0
1860
0
2790
0
2790
0
1100
0
3270
0
1860
0
500
0
2790
0
0
0
3860
0
1860
TYP
D
n
r
c
D
n
D
V
r
D
D
P
D
D
D
D
D
D
P
D
D
. 0
0
0
2790
0
2790
D
P
LEG
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
13
2A
2B
1A
18
U
IB
1A
IB
1A
UTM
XD850650
YD020670
XD765667
X0800667
XD 76 5660
XD800660
XD851595
XD96'0590
YD037580
YD071625
Y0075693
XD945595
YD080695
YD030580
XD960590
XD960590
YB040585
X 097 0590
YD040590
Y0045594
YD076680
YD070610
YD070690
XD924597
XD965564
YD010590
YD050610
XD764659
XD940647
XD660605
XD710620
XC840590
X0845610
XD995590
YD063618
XD840590
XD910560
YD808585
YD837606
YD030594
YD055610
XD985590
YD070670
XD765655
X.D890650
X0770650
X0930650
XD775245
X0850627
XD810640
�DATE
670504
670504
670504
670505
670505
670507
670507
670513
670513
670513
670513
670514
670514
670514
670514
670515
670515
670517
670517
670517
670517
670517
670517
670517
670517
670518
670518
670513
670528
670526
670528
670528
670528
670528
670608
670608
670608
670608
670608
670608
670608
670610
670610
670610
670610 •
670611
670611
670616
670616
670622
iGN
n
D
0
0
0
0
n
n
a
0
0
a
0
0
0
0
0
GALS
0
1360
0
2950
0
2790
0
2790
0
1860
0
2100
0
2330
0
2560
0
1000
0
2450
0
1860
0
3720
0
5000
0
0
2790
0
750
0
2230
0
2740
0
0
0
0
0
TYP
D
D
D
0
0
D
D
D
C
0
D
0
D
D
0
D
C
0
W
n
n
n
2560
0
0
0
279J
0
1660
0
2640
C
LEG
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
18
1A
IB
IA
IB
1A
IB
1A
18
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
IA
IB
1C
10
2A
2B
2C
1A
IB
1C
ID
D
IA
13
D
1A
IB
i 1A
C
UTM
X0980570
XD940660
YD030660
XD730580
XD760560
X0940665
YD030665
XD780580
XD830600
XD810620
XD770610
XD683583
XD748555
XD730610
XD780580
XD731623
XD815627
XD983300
XD987345
XD824549
XC784560
X 08 4 964 8
XD942617
XD850599
XD935600
XD940670
X0050620
XD040670
XD662454
X0730473
XD714628
XD657616
XD742628
*D830631
YD230190
YD150250
YD120250
Y0120260
YD100270
YD260140
YD200170
Y0090180
Y0120150
YD220180
YD130160
XC735615
X 07 70530
XD750610
XD790530
YD000350
�I
MISSIOMS STARTING IN
04TE
670622
670622
670622
670622
670624
670624
670625
670625
670630
670630
670714
670714
670721
670721
670730
670730
670730
670730
670830
670830
670903
670908
671216
671216
671216
671216
671219
671219
671220
671220
671221
671221
671223
671223
671226
671226
671228
671228
680102
680102
680104
680104
680104
680104
680105
680105
680106
680106
680112
630112
aGH
0
0
0
0
0
0
3
w
0
0
0
0
Q
Q
0
0 .
n
Q
0
n
0
n
QUANG TR I
************
TYP
LEG
GALS
0
IB
0
1C
0
2A
0
28
2690
D
1A
0
IB
1540
D
1A
0
IB
2180
C
1A
IB
0
2100
P
1A
0
IB
1A
500
C
0
IB
1A
1440
C
IB
0
0
2A
0
2B
D
2850
1A
0
IB
1A
8200
D
0
IB
n
3000
1A
0
IB
2900
D
1A
0
IB
2900
D
1A
0
IB
2800
C
1A
0
IB
3000
D
1A
0
IB
3000
1A
D
0
IB
1A
3000
D
0
IB
2700
D
14
0
13
2800
1A
D
0
IB
D
1A
2950
IB
0
D
1A
2900
IB
0
D
2625
1A
IB
0
P
1920
1A
0
IB
P
1A
2600
IB
0
PROM NO. =
UTM
YD030290
Y0100290
YD160310
Y0060350
XD540750
XD670570
XD847554
XD910536
YD220135
YD160100
XD850620
X0980570
YD042498
YD067486
YD040413
YD000425
Y0060411
YC065420
YD043500
Y0132458
YD116701
Y0215742
X0951580
YD020448
YD068658
YD210686
YD070611
YD211537
YD080691
YD193711
YD070641
YD209664
YD080702
YD210733
YD070621
YD200641
YD070677
YD212699
YD070650
YD215677
XD954580
YD021450
YD080700
YD210733
YD0706i5
YD1S0626
YOOB8688
YD211711
YD070660
YD209690
1
�UNCLASSIFIED
MISSIONS S T A R T I N G IN
DATE
680112
680112
680328
680328
680328
680328
680329
680329
680408
680408
680423
630428
630430
680430
6S0503
680503
630505
680505
680508
630508
680512
680512
680513
680513
680514
680514
680516
680516
680517
680517
680518
680518
680521
680521
630522
680522
680523
680523
680525
680525
680530
630530
680603
680603
630604
680604
680607
680607
68060S
680609
AGN
0
0
0
•
J
0
o
0
n
0
0
0
0
0
0
0
0
0
Q
0
0
0
0
0
n
n
GALS
1650
0
2150
0
2400
0
1925
0
3000
0
2950
0
3000
0
3000
0
3000
0
2500
0
3000
0
2400
0
3000
0
2700
0
3000
0
2000
0
3000
0
2650
0
2800
0
2700
0
3000
0
3000
0
2700
0
2850
0
1800
0
PROV NO.
QUANG TRI
TYP
D
D
n
D
D
D
D
D
0
r
D
r
D
D
D
r
0
n
R
LEG
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
D
C
P
D
n
n
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
UTM
YD240340
YD360413
YD080700
YD210700
Y0220330
YD370420
XD960580
XD990440
YD213337
YD369433
YD215728
Y0075697
YD207718
YD080697
YD210340
YD360432
Y0000440
XD840380
XD960580
YC020457
YD015450
XD849381
YD210708
YC090687
YD012454
X0850338
Y0190699
YD075689
YD015447
XD859333
YD23B342
YD349409
YD007457
XD850390
YD020433
XD899388
YD209655
YDO 70638
XD862381
Yn020446
Y0252297
YD398334
YD2 10730
YD080710
YD2 10640
YD070620
Y0210670
YD070650
YD237326
Y0373413
�UNCLASSIFIED
MISSIONS STARTING IN ftUANG TRI
PROV NC. =
* f ^ *!t * * *
* c t (
* * *
OATE
630611
630611
630612
630612
680614
680614
630616
680616
680626
630626
680627
680627
680712
630712
683730
680730
680812
630612
680819
680819
680820
680820
680903
680903
681022
681022
631027
681027
681108
681108
681122
681122
681128
681128
681128
681128
681201
681201
631201
681201
681202
681202
631202
681202
681202
681202
681202
681202
681202
631202
AGN
0
0
0
0
0
0
0
0
0
0
0
0
0
B
B
3
0
0
0
0
0
GALS
2500
0
2750
0
2000
0
1950
0
2900
0
2300
0
2000
0
3000
0
5000
0
1800
0
2900
0
5000
0
2700
0
3000
0
3000
0
3000
0
3000
0
0
0
3000
0
0
0
3000
0
0
0
3000
0
0
0
2000
0
TYP
D
D
0
0
0
D
D
D
D
D
D
D
D
0
D
C
D
D
0
n
D
LEG
IA
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
2A
28
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
UTM
YD208679
YD070654
YD242309
Y0387400
YD396385
Y0252298
XD848393
YDO 10460
Y0210691
YD070668
Y02 10343
YD358434
XD962580
YD020460
Y0200281
YD368385
YD228305
YD373396
YD239291
YD395387
YD332255
YD430253
YD195383
YD370383
Y0105615
YD175735
YD131615
YD200735
YD138615
YD200725
YD140635
YD202742
X0895636
XD932654
Y0019657
Y0065684
XD895629
XD935646
YD023650
Y0070675
XD895636
XD932653
YC020657
YD070686
XD660570
XD660480
XD660570
XD65964Q
XD667570
XD667480
r>
�UNCLASSIFIED
MISSIONS STARTING IN
DATE
681202
681202
681205
681205
681205
681205
631205
681205
631205
681205
681205
681205
681206
681206
681206
631206
631209
681209
681209
681209
681211
681211
681211
681211
681211
681211
681211
681211
681212
681212
681212
681212
681214
631214
681214
681214
681214
681215
631215
681217
681217
681217
681217
681217
681216
681218
681226
681226
681226
631226
AGN
GALS
QUANG TRI
TYP
0
0
0
3000
D
0
0
0
0
0
3000
D
0
0
0
0
0
4000
D
0
0
0
0
3000
P
0
0
0
0
3000
D
0
0
0
3000
D
0
0
0
0
0
3000
D
0
.
0
0
0
3000
0
0
0
0
0
2400
D
n
0
0
3000
P
0
0
0
0
n
3000
0
W
3000
0
0
0
D
n
PROV NO.
LEG
2A
28
1A
IB
1C
2A
2B
1A
IB
1C
2A
2B
IA
IB
2A
2B
1A
IB
2A
2B
1A
IB
1C
1A
IB
2A
2B
2C
1A
IB
2A
28
1A
13
1C
2A
28
1A
IB
1A
IB
2A
2B
2C
1A
IB
1A
IB
1C
2A
/ UTM
XD667570
XD667640
XD704627
XD749652
XD804656
X0832637
XD895628
XD701634
XD747658
XD807665
XD835644
X0865640
XD662480
XD662650
XD662570
XD662650
XD668570
XD667480
XD668580
XD665650
YD160416
Y0212420
YD287412
XD702632
X0750656
XD806662
XD834643
XD895635
X0667568
X0667490
X0667570
XD667640
X0703629
XD749653
XD805601
XD833640
X0880634
XD671483
XD671640
XD705625
X0750648
XD804654
XD832635
X OS 8562 3
XD677480
XD677650
XD710620
XD752643
XD802641
XD830629
�D^T^!
681226
690101
690101
690110
690110
690110
690110
690111
690111
690111
690111
690121
690121
690121
690121
690127
690127
690127
690127
690127
690129
690129
690210
690210
690210
690210
690210
690212
690212
690212
690212
690219
690219
690302
690302
690322
690327
690327
690327
690327
690327
690402
690402
690402
6S0402
690407
690407
690407
690407
690407
4.GN
n
w
W
W
0
0
0
0
0
0
B
W
w
n
0
GALS
0
3000
0
3000
0
0
0
3000
0
0
0
3000
0
0
0
3000
0
0
0
0
3000
0
3000
0
0
0
0
3000
0
0
0
2500
0
3000
0
310
3000
0
0
0
0
3000
0
0
0
3000
0
0
3000
0
TYP
D
0
D
D
D
D
D
D
D
V
P
D
D
D
0
LEG
2B
1A
IB
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
2A
26
1A
IB
2A
2B
2C
1A
IB
1A
18
1C
2A
26
1A
IB
2A
2B
IA
18
1A
IB
IA
1A
IB
2A
2B
2C
1A
IB
2A
26
1A
IB
1C
1A
IB
UTM
X0884521
YD160412
YD307412
XD673570
XD673480
X0673570
XD673650
XD895623
X0933640
XD246645
XD070671
XD985615
XD934637
X0025643
YD070668
YD170427
YD260429
YD170429
YD208430
YD264439
YD175396
YD342396
X0706624
X0752646
X0803655
XD830632
XD895622
XD895634
XD932650
YD020655
YD070683
YD160420
YD2S0420
YD171402
YD331402
YD116701
YD707622
YD752645
YD802647
YD826631
Y0390623
YD896627
XD932644
YD020648
Y0070677
YD241359
YD200367
YD173396
YD221321
YD291374
�DATF:
690407
690414
690414
690414
690414
690414
690416
690416
AGN
690425
690425
690425
690425
690426
690426
690426
690426
690426
690426
690426
690426
690426
690507
690507
690507
690507
690507
690510
690510
690510
690516
690516
690516
690517
690517
690517
690518
690518
690518
690601
690601
690601
69060?
690602
690602
690604
690604
690604
690622
690623
690623
B
G
0
0
0
B
G
W
W
W
W
0
n
0
w
0
GALS
0
2000
0
0
2000
0
2000
0
1700
0
0
0
400
0
0
0
0
2000
0
0
0 •
400
0
0
0
0
2000
0
0
2000
0
0
2000
0
0
3000
0
0
3000
0
0
2000
0
0
2800
0
0
325
2000
0
TYP
c
r
D
D
F
D
F
0
D
D
P
0
C
D
P
D
LEG
1C
1A
IB
1C
1A
IB
1A
IB
1A
IB
2A
2B
1A
2A
3A
4A
5A
1A
IB
2A
28
1A
13
1C
ID
IE
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
> 1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
1A
IB
UTM
YD318405
YD223318
YD292370
YD322405
YD210704
YD070681
Y021Q736
YD147620
YD172401
Y0206403
YD248418
Y0263442
YD195665
YD173658
YD13665
YD195673
Y0159687
YD167390
YD210397
YD252411
YD270438
YD152663
YD150670
YD160660
Y0160670
YD170670
YD231306
YD304359
YD335396
YD2253l'6
YD295369
YD322403
YD240355
YD198361
YD166394
XD895632
XD930650
X0020656
YD227313
YD297364
Y0327400
YD242368
YD205375
YD173402
YD229308
YD302365
YD332398
YC335480
YD224316
YD299375
r
�UNCLASSIFIED
MISSIONS S T A R T I N G IN' QUANG TRI
DATE
690623
690716
690716
690725
690806
690806
690827
690827
690827
690827
691012
691012
691015
691015
691015
691017
691017
691017
691018
691018
691013
691020
691020
691020
691021
691021
691021
691021
691021
691021
691112
691112
700114
700123
700125
700227
700227
700227
700227
700909
4GN
W
0
W
W
0
W
8
W
3
0
B
B
0
0
0
0
9
W
B
B
GALS
0
1000
1500
325
3000
0
700
0
40
0
500
0
3000
0
0
2100
0
0
3000
0
0
3000
0
0
1300
0
0
1300
0
0
90
75
660
660
660
1700
0
0
0
935
TYP
P
P
P
C
F
F
C
D
D
D
D
0
D
\
\
P
P
P
P
P
P
P
PROV NO.
LcG
1C
1A
1A
1A
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
1A
1A
1A
1A
1A
IB
2A
2B
1A
UTM
YD323403
YD000480
YD000480
YD337478
XD965470
XD833390
X 09 2 6 4
.43
YD333485
X0926443
YD333485
YD017452
YD058432
XD809472
XD868401
XD965432
XD807472
XD865399
VD965425
XD817448
XD864390
XD965420
X0799466
XD864387
XD965416
XD803478
X.0865396
XD965422
X0803478
XD865396
XD965422
Y0135642
YD115701
YD115701
YD115701
YD135642
XD669569
XD669660
XD669569
XD66S480
Y0135646
UNCLASSIFIED
r
�NREC= 17300
NREC= 17300
NPPOV=
NPROV=
311
311
MZREC=
NZREC=
529
529
UNCLASSIFIED
�DAT?
650815
650815
650822
650822
650822
650622
650322
650822
650823
650823
650823
650823
650823
650823
650824
650824
650624
650824
650825
653825
650826
650826
650907
650907
650908
650909
650910
650911
650912
650917
660213
660215
660228
660308
660338
660308
660308
660308
660308
660308
663308
660300
660308
660308
66030 S
660314
660314
660315
660315
660315
«GN
0
GALS
0
2000
800
0
TYP
C
C
0
0
0
0
0
0
2000
C
0
0
0
0
0
0
1900
0
0
2000
0
0
2000
0
0
1900
0
2000
0
1150
3000
2900
4000
2000
2000
1000
2000
2900
2000
0
0
0
0
0
0
0
c
0
0
0
C
c
c
c
c
c
0
'D
D
D
D
0
D
D
C
0
0
0
0
0
0
0
0
0
0
0
0
2000
r
0
0
1600
0
0
C
LEG
1A
IB
1A
16
1C
ID
IE
IF
IA
IB
1C
ID
IE
IF
1A
18
1A
IB
1A
IB
1A
18
1A
IB
IA
1A
1A
1A
1A
1A
1A
1A
1A
1A
IB
2A
2B
3A
36
3C
4A
4B
5A
5B
5C
1A
IB
1A
IB
1C
UTM
YD350155
YD450150
YC870720
ZC000835
YC940860
YC880850
YC855903
YC770B20
YC870720
ZC000835
YC940860
YC880850
YC855903
YC770820
YC790300
YC950850
YC600890
YC710890
YC710725
YC700770
YD330180
YD420160
Y0270100
YD365025
YC680860
YD385000
Y0385000
YC 52 08 15
YC495835
YC402981
YC500S40
YC500S40
YC500840
YD375174
Y0502130
YD592150
YD573177
YD440220
Y0486243
Y0480251
YD506210
YD486240
YD497191
Y0517176
YD530180
YD410240
Y0570180
Y0511180
Y0550192
YD400173
�UNCLASSIFIED
0",TB.
660315
660404
660404
660404
660404
660406
660406
660406
660406
660406
660406.
660406
660406
660406
660427
660427
660427
660427
660428
660423
660423
660428
660429 '
660429
650430
660430
660430
660430
660512
660512
660512
660512
660531
660531
660531
660531
66J705
660705
660706
660706
660707
660707
660707
660707
660708
660708
660708
660708
660709
660709
A, ON
0
0
0
0
GALS
0
1850
0
0
0
2000
0
0
0
. 0
0
0
0
0
1650
0
0
0
1250
0
TYP
C
C
C
,
•„ , -. - .
'
:
C
0
U
0
0
9
0
0
0
n
0
0
1000
0
1300
0
0
0
3000
0
0
0
1900
0
0
0
2000
0
1700
0
2000
0
0
0
1000
0
0
0
1000
0
C
C
C
C
D
D
P
D
F
LEG
1C
IA
IB
2A
29
1A
IB
2A
2B
3A
3B
4A
46
4C
1A
IB
2A
2B
1A
IB
2A
28
1A
IB
1A
IB
2A
2B
IA
IB
2A
2B
1A
IB
1C
ID
1A
IB
1A
IB
1A
IB
1C
ID
1A
IB
1C
ID
1A
IB
UTM
Y0502130
YC655782
YC692798
YC704742
YC698776
YD261120
YD370090
Y025C040
YD370040
YD280020
YD340020
YC310910
YC420910
YC310990
YC800840
YC875863
YC881753
YC886843
YC660885
YC705890
YC835760
YC890830
YD470195
YD450230
YD295015
YD364013
YC327999
YC334982
Y0310000
YD360000
YC310915
YC400940
YD280020
YD338020
YC420900
YC3 06900
ZC130955
ZC155960
YD900015
YC912890
AT940925
AT940940
AT925940
AT925925
AT955945
AT965930
AT960920
AT950945
AT825978
AT840955
�MISSIONS START ING IN
THUA THIEN
%3k$%:% **$$•%$
n£,T £-
660709
660709
660710
660710
660710
6.60710
660710
660710
660710
660710
660712
660712
660712
660712
660713
660713
660713
660713
660718
660718
660729
660729
660729
660729
660731
660731
660731
660731
660803
660803
660803
660803
660804
660804
660804
660804
660805
660805
660806
660806
660806
660807
660807
660807
660607
660808
660808
660809
660809
660810
AGN
0
0
n
o
0
0
n
0
o
GALS
0
0
1000
0
0
0
1400
0
0
0
2000
0
0
0
2000
0
0
0
2000
0
2000
0
0
0
1750
0
0
0
1550
0
0
0
2000
0
0
0
0
n
0
0
o
0
3000
0
2000
0
0
2000
0
0
0
. 1900
0
2000
0
2000
TYP
D
D
D
r
D
D
.
D
D
*
LEG
1C
ID
1A
IB
2A
28
1A
IB
2A
2B
1A
IB
1C
10
1A
IB
1C
ID
1A
IB
1A
IB
2A
26
1A
IB
2A
26
1A
IB
D
r
D
r>
r
r
c
1C
ID
1A
IB
2A
2B
1A
IB
1A
IB
1C
1A
IB
24
2B
1A
IB
1A
IB
1A
'
UTH
AT830955
AT820980
ZD1 50065
ZD150080
ZD160080
ZD163068
AU835015
AU848018
AU832040
AU825040
ZD140040
ZD170035
ZD165065
ZD150060
YC915905
YC930905
YC915875
YC930875
ZC070970
ZC060932
ZD15C080
ZD150040
ZD1300/+0
ZD140080
AT960940
AT970920
AT975945
AT965950
ZC050930
ZC060940
ZC050960
ZC065975
ZC130955
ZC150940
ZC160955
ZC150968
YC502875
YD395005
YC915955
YC900990
Y0905015
YC478836
YC5207SO
YC555806
YC-+90875
AU835055
AU820G90
YC332932
YC417945
YC902975
�DATE
660810
660810
660810
660810
660810
660810
660810
660811
660811
660812
660812
660812
660612
660812
660812
660813
660813
660816
660816
660816
660816
660818
660818
660818
66081G
66081B
660818
660818
660818
660821
660821
660824
660824
660827
660827
660827
660827
660827
660827
660827
660828
660828
660831
660831
660904
660904
660S06
660906
661015
661015
0
GALS
0
0
0
2000
0
0
0
2000
0
1900
0
0
0
2000
0
2000
0
2000
0
0
0
2000
0
0
0
2000
• 0
0
0
2000
0
2000
0
1600
0
0
2000
0
0
0
1400
0
2000
0
2000
0
2000
w
1250
AGN
n
0
0
0
0
0
0
IJ
0
0
0
0
0
g
0
TYP
n
D
D
D
D
D
D
D
D
D
C
D
D
0
D
D
'•' o
0
C
LEG
16
2A
2B
1A
IB
2A
26
1ft
IB
1A
13
2A
26
1A
IB
1A
16
1A
IB
2A
28
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
1A
16
1A
16
1C
1A
16
2A
28
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
UTM
YC909015
YC890970
Y0896015
ZC150967
ZC170960
ZC170960
Z'C 17 0990
YC534835
YC435965
AU826050
AU820090
ZD146045
ZD162062
AT820998
AT837960
YD393015
Y0489890
YC500870
YC551302
YC339923
YC416940
YC955960
YC915893
YC905950
YC905375
YC915955
Y0912015
YC902950
Y0895016
ZC070970
ZC050930
YD382032
YC530310
YC440388
YC520783
YC545804
YD915016
YD893016
YC920892
YC900392
ZD140049
ZD160080
YD370023
YC430950
YC339918
YC439926
YC543805
YC465905
YD365015
YC490850
�UNCLASSIFIED
PROVED. "=*--•••-~2':
MISSIONS STARTING IN
DAT IE
661017
661017
670330
670330
670403
670403
670416
670416
670416
670416
670419
670419
670423
670423
670423
670506
670506
670506
670508
670508
670509
6 70 50"=
670509
670509
670511
670511
670519
670519
670526
670526
670527
670527
670529
A ( *J "? c
O T^c;P £ *
670529
670531
670531
670607
670607
670607
670607
670612
670612
670612
670612
670614
670614
670623
670623
670629
THU* THIEN
AGN
W
GALS
4500
0
. TYP
D
3720
0
:
S
0
3
P
0
1000
0
930
0
880
C
C
C
•
}
B
0
0
3
0
3
0
0
"J
0
0
0
0
0
0
T
0
1830
•
C
0 i , - -~
1860
D
0
0
2790
C
0
2360
C.
0
0
3720
C
0
I860
D
0
2790
C
0
4500
D
0
2360
C
0
4350
C
0
4500
T
0
0
4500
D
0
4650
D
0
0
0
5580
D
0
0
0
2790
f
o •
27'90
0
1860
C
C
LEG
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
18
1A
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1-A
IB
1C
1A
18
1A
IB
2A
2B
1A
18
2A
2B
1A
IB
IA
IB
1A
UTH
YD360016
YC490850
YD415265
YD482245
YC865833
YC878860
YD455338
YD6 00250
YD455338
YD600250
YD520280
YD600260
YD600260
YD520300
YD610240
Y0420260
YD480240
YC630750
YC700780
YC700900
YD330030
YC470870
YD330030
YC470870
YD420290
YD460280
YC308936
YC432962
YD540290
Y0600250
YD415278
YD470267
YC540790
YC500830
YC450940
YC310940
YC45C990
YC540780
YC490840
YC460900
YC430940
YC541796
YC492845
YC423397
YC412958
YC560770
YC540970
YC300910
YC440960
YC620740
�OAT^
680424
63J424
680424
680424
680429
630429
630502
680502
630502
580502
630503
680503
680504
680504
630504
630504
680505
630505
680505
680505
680506
630506
680508
6S0508
630503
680508
630509
680509
630509
680509
680510
680510
680510
680510
680511
680511
680512
680512
680513
680513
630513
680513
680515
680515
6S0515
630515
680516
680516
680516
680516
AGN
W
0
n
0
n
0
0
0
n
0
0
a
0
a
0
0
0
0
n
GALS
3000
0
. 2700
0
2400
0
2900
0
0
0
2200
0
3000
0
3000
0
3000
0
0
0
3000
0
3000
0
0
0
3000
0
0
0
2800
0
3000
0
3000
0
2800
0
3000
0
0
0
. 3000
0
2500
0
3000
0
0
0
TYP
n
0
p
p
0
p
D
D
D
D
D
D
D
D
C
P
D
D
P
LEG
1A
IB
1A
18
1A
IB
1A
IB
2A
26
1A
IB
1A
IB
IA
IB
1A
ie
2A
26
1A
IB
1A
IB
1C
ID
1A
IB
2A
28
1A
16
1A
18
1A
18
1A
16
IA
IB
1C
10
1A
IB
1A
IB
1A
IP
24
2(3
UTM
AU340063
AU820087
AU840063
AD 82 002 7
ZC026958
YD955088
YD453258
Y0513190
YC494172
YD435225
Y0600092
YD72Q105
AT810960
ftU8 10000
ZC060980
ZD050030
YD420220
Y0490160
YQ520200
YD470250
YC 540980
YD630100
YD420219
YD484159
Y0520197
Y0464249
YP412201
YD471146
YD517195
YD460248
YC905893
YD893013
YC 542 980
Y0620102
YC536980
YD634100
YC533980
YD618095
YD418194
YD467148
YH516194
YP^+62234
YC425962
YD543035
YP418215
YP522199
YD413204
YD473147
YD511188
Y0446248
�DATE
630519
680518
680518
630518
680519
680519
680519
680519
680520
680520
680522
660522
680522
680522
680523
680523
630523
680523
680524
680524
680524
680524
680526
660526
680526
680526
680527
680527
680527
680527
630527
630527
680601
630601
630601
680601
680601
630601
680601
630601
630602
680602
&.3N
680605
630605
680605
680608
680608
68060S
630608
68060P
G
0
n
0
0
0
0
0
n
0
0
o
0
0
0
0
GALS
2900
0
0
0
2650
0
0
0
3000
0
3000
0
0
0
2000
0
0
0
2900
0
0
0
2700
0
1750
0
2000
0
2900
0
0
0
1700
0
.0
0
2000
0
0
0
3000
0
2500
0
0
3000
0
0
0
2000
TYP
D
p
D
D
0
D
D
D
C
D
C
P
C
D
p
n
LEG
1A
IB
1C
10
IA
is
2A
26
1A
18
1A
IB
2A
28
1A
18
2A
28
1A
IS
2A
2B
1A
IB
1A
13
1A
IB
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
1A
IB
1C
1A
IB
2A
2B
14
UTM
YD4I2200
YD469155
XD525203
XD477248
YD422223
YO487163
YD5 13190
YD451249 '
YC 42 3966
YD550038
Y041119S
YD469144
Y0515192
YD45 5-249
YC42396O
YC458993
Y0453020
Y0544O34
YC423967
YC450997
Y0452QOO
Y055O042
YC545980 |
YO400374
YO288304
YD40Q374
YC8907O3
YC88888Q
YC426958
YC459930
YO459O20
YD540032
AT80496Q
AU800002
AT829960
AU825000
YD418214
YO480156
YD522199
YD470243
AS990790
AS390900
YC 54 09-90
YC450940
YC450910
YD430230
YD490170
YD530210
YD460250
YC 540930
�MISSIONS STARTING IN
DATE
680608
680608
680608
680610
68G610
6b0616
680616
680617
680617
630617
680617
68061S
680618
680618
6S0618
68062'!
630621
680621
680621
630622
680622
680623
680623
630623
680625
680625
680625
680626
&30626
680626
630627
680627
630627
680628
680623
680628
630628
680629
680629
630701
680701
680702
680702
680702
630702
680702
630702
630704
680704
630704
.4 ON
0
0
0
0
0
0
0
0
0
n
0
0
G
0
0
0
0
0
n
GALS
0
0
0
2750
0
1900
0
2000
0
0
0
3000
0
2700
0
3000
0
2300
0
3000
0
3000
0
0
3000
0
0
280O
0
0
2300
0
0
2500
0
2000
0
2950
0
3000
0
2700
0
0
3000
0
0
2700
0
0
THUA THIEN
TYP
D
r
0
c
p
p
c
D
P
'
PROV NO.
LEG
IB
2A
28
1A
IB
1A
IB
1A
IB
2A
28
1A
IB
1A
18
1A
16
1A
18
1A
IB
1A
18
ie
D
0
D
C
0
0
c
D
1A
13
1C
1A
IB
1C
1A
IB
1C
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1C
0
1&
18
1C
0
IA
18
1C
UTM
Y0530010
Y0570000
Y06 10090
YC 53 8 98 7
YC447910
YC 69 795 4
YO665090
YD417208
YD477152
Y0527208
Y0483248
YC 53 499 2
YC443910
YC712960
YC685090
YC420985
YC53B831
YC 703 95 2
¥0675082
YC387958
YC49.2820
YC699948
YC666982
Y066fc084
YC7S5798
YC854837
YC903S92
YC 7 1095 8
YC 6=82990
YD67SQ88
YC792781
YCa62322
YC91O883
K 04 8 986
ZDO40O10
YD&OOO95
YO720112
YCTO7957
YD676O93
ZC135930
ZD111014
YC705945
YC67C990
YD670090
YC776817
YC847354
YC900915
YC 7 1796 4
YC68&993
YC686090
UNCLASSIrltO
�D^TE
680704
680704
630704
680707
680707
630712
680712
630712
6 807 12
630712
630714
630714
680715
630715
680716
630716
630719
630719
630719
630719
630719
630719
630720
630720
680722
680722
680722
680722
630722
630722
680723
680723
680726
680726
680726
630726
630726
680727
680727
630727
680723
63J72P
530730
630730
630731
680731
630731
680731
630801
680801
AGN
Q
n
Q
0
0
o
0
0
n
0
n
0
G
n
0
0
n
0
n
0
Q
GALS
2700
0
0
2400
0
4000
0
1800
0
0
1600
0
2650
0
1200
0
2500
0
2900
0
0
0
3000
0
2000
0
0
0
1750
0
2000
0
2000
0
1750
0
0
3000
0
0
5700
0
3000
0
2100
0
3000
0
3000
0
TYP
D
D
0
D
D
D
D
D
D
C
D
D
D
D
n
C
D
D
r
C
C
LEG
1A
IB
1C
IA
IB
1A
IB
1A
IB
1C
1A
IB
IA
IB
1A
IB
1A
13
1A
IB
2A
28
1A
IB
1A
IB
2A
2B
IA
IB
1A
IB
1A
IB
1A
IB
1C
IA
IB
1C
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
UTM
Y0523040
Y0502140
YD535200
YD600099
YD720113
YD541042
YD579208
YD600092
YD630092
YD072104
YC720965
YD695100
YD527040
YD504136
YD600097
YD72011
YP720110
YC68C096
YD437249
Y0507183
YD527213
YD489249
YC779810
YC860925
Y0417210
YC476153
YC500176
Y0431232
YC897908
YD830050
YD535040
YD571213
YC874898
YD799061
YD600093
YD680093
YD720103
YC7V0800
YC850840
YC900S90
YC883900
YD805065
YD280270
YD400357
YC719966
YC696993
YD600083
YD72i-UOO
YD 53 6040
YD560202
'•
.
�UNCLASSIFIED
MISSIONS STARTING -IN
D*Tt
680801
630801
630801
680801
6SOS01
680801
680601
680803
680803
680803
580303
680803
680804
680804
680804
630804
680804
680804
680806
680806
630807
630807
6S0807
630807
680807
680807
680807
680807
680807
630807
680810
680810
680810
680810
680811
680811
680811
680811
680811
680811
680811
630311
680811
630811
680812
680812
680812
680813
680813
680813
AGN
0
•3
0
0
0
0
0
0
0
0
0
0
0
0
0
o
0
0
GALS
3600
0
0
0
2253
0
0
3000
0
0
2800
0
3000
0
0
1700
0
0
3000
0
2000
0
3000
0
0
3000
0
2000
0
0
4500
0
2100
0
2800
0
0
0
1800
0
0
2800
0
0
3000
0
0
2400
0
0
THUA THIEN
TYP
D
D
D
C
D
D
D
D
D
n
D
D
n
D
n
PROV NO. =
LEG
1A
IB
2A
26
1A
IB
1C
1A
IB
1C
1A
IB
1A
IB
1C
1A
18
1C
1A
18
1A
18
1A
IB
1C
1A
IB
16
18
1C
1A
IB
IA
IB
1A
IB
2A
2B
1A
IB
n
p
C
1C
1A
18
1C
1A
18
1C
1A
IB
2A
UTM
Y0423227
Y0489165
YD526218
YD492249
YC71S966
YC696993
YD696090
YD545043
YD528130
YD584208
YC790789
YC915883
Y0303250
YP323278
YD468278
YC775815
YC843848
YC892910
YC865893
YD789060
YD680074
YD664134
YC694943
YC664980
YD663090
YC530960
YD523020
YC786797
YC854834
YC905390
YC878899
YD305063
YD600099
YD685099
YC906890
YC917926
YC891939
YC901021
YC546980
YD540015
YD63S033
YC790810
YC843839
YC896399
YC892906
YC868944
YDS 13060
YC910892
YC919925
YC895989
�MISSIONS STARTING IN
DATE
600813
680313
680813
630813
680815
630815
630315
633815
680815
680815
680615
680815
530815
630815
680816
630816
630819
AGN
0
0
3
0
P
0
68081<?
680819
630820
680820
680821
630821
630821
680823
680823
630823
630823
680824
680824
680824
630824
680824
630824
6S0824
630825
630825
630825
680826
680826
630826
680827
630S27
630827
630823
630828
680830
630830
680330
630830
0
0
Q
GALS
0
2000
0
0
2500
0
0
0
2500
0
0
3000
0
0
3000
0
2750
0
0
3000
0
5000
0
0
2675
0
TYP
r
D
D
D
D
C .
0
C
0
0
0
Q
3
0
Q
0
B
n
0
3000
0
0
0
0
3000
0
3000
0
0
1500
0
0
1975
0
0
2250
0
3800
0
1000
0
PROV NO.
THUA THIEN
r
D
D
D
D
D
C
C
LEG
2B
1A
IB
1C
IA
IB
2A
2B
IA
IB
1C
1A
IB
1C
IA
13
IA
18
1C
1A
IB
1A
IB
1C
IA
IB
2A
23
1A
IB
1C
2A
28
1A
IB
1A
18
1C
IA
IB
1C
1A
IB
1C
iA
IB
IA
IB
1A
IB
UTM
Y0904020
AT893950
AT840958
AT830998
YC912891
YD903018
YC924933
YC 899993
YD600087
YD682087
YD720098
YC778812
YC 84 7 848
YC894902
YC389904
YC81506O
YC786795
YC85&343
YC904897
YD533Q41
YD513137
YC785805
YC850843
YC900S98
YC 9 6 89 2
0
YC915925
YC89Q988
YD901O22
Y0531040
YD511137
YD565215
YC923886
YC9.1O93O
YC783992
YC867S31
YD540040
YD520131
YD578211
1C 12 5940
ZC175947
ZC185987
YC774820
YC841855
YC876397
ZC127952
1C 1 0 8
8 9 6
YC580830
YC550980
YC580830
YC550980
.! I ," r •; I P I :
'•
�IONS START ING IN
KIS?
THUA THIEN
************
DATE
630831
680831
680831
880831
600901
680901
680902
680902
680902
680902
630902
630902
680902
63090?
680903
680903
680903
68C90G
6 8090 b
680908
630903
680909
660909
680909
680909
680909
680910
680910
680910
680911
680911
630912
680912
680912
680912
630912
680912
680913
680913
680913
680913
680C14
680914
680914
680916
680916
680916
680916
680916
680917
AGN
0
3
n
0
a
0
Q
n
0
0
0
0
0
0
D
GALS
1700
0
0
0
6000
0
3000
0
1600
0
2800
0
0
4550
0
0
0
3550
0
0
0
3600
0
3000
0
0
3925
0
0
3000
0
2850
0
4000
0
6000
0
3000
0
0
TYP
C
c
C
14
18
0
1A
IB
1A
16
1C
1A
IB
2A
2B
14
IB
2A
28
1A
IB
1A
IB
1C
1A
1R
2A
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
26
n
D
D
0
o
0
r
D
n
r
D
0
0
a
0
n
3000
0
0
6000
0
3000
0
0
5000
L6G
1A
18
2A
2B
1A
IB
D
1A
IB
1C
C
C1
0
1A
IB
1A
IB
1C
IA
UTM
YC77VS60
YD729014
Y0710071
¥0721099
YC730796
YC730790
YC671760
YC671950
ZC027920
YD381000
ZC04O853
YC969348
YC881876
YC783963
YP732D20
Y0715072
YD727097
YC 790975
YC748022
Y0732022
YD739092
YD25Q301
YD440310
ZCCH0857
YC970850
YC912871
YC781961
Y0724099
YC713072
YC778959
Y0720101
YD738055
YD804022
YD280268
YD470278
YC900900
YD826054
YD400165
YDV52141
YD529129
YD580210
YC538735
YC533970
YC653060
YC683760
YC683950
ZC040369
YC970863
YC920879
YC868694
|
�DATf
630917
680918
630916
680919
680919
680919
630919
680919
680919
630920
680920
630920
680921
6S0921
680927
630927
680927
681001
681001
631001
681001
6S1001
681001
681002
631002
681002
631002
681005
631005
681005
681005
631005
631007
681007
631008
681008
631000
631008
681009
681009
681009
681026
631026
681026
631030
681030
681102
681102
6P1102
681102
AGN
0
0
rj
Q
0
W
W
W
W
W
W
W
W
W
W
W
B
0
n
GALS
0
4000
0
3000
0
0
1500
0
0
3000
0
0
5000
0
3000
0
0
3000
0
2900
0
0
0
3000
0
3000
0
3000
0
3000
0
0
3000
0
4000
0
4000
0
4000
0
0
3500
0
0
2950
0
3000
0
0
0
.
TYP
n
n
r
c
c
D
LEG
IB
1A
IB
IA
IS
1C
1A
IB
1C
IA
16
1C
1A
IB
1A
IB
1C
D
0
D
D
0
0
D
D
D
1A
IB
1A
IB
2A
26
IA
16
1A
IB
IA
16
IA
IB
1C
IA
IB
1A
IB
C
C
t
Y0490139
Y0531128
YD58O2O3
YC89O9G5
YO&22Q56
YD28Q275
YD455272
YT785965
YD738O16
YD533040
YO514129
YD5T4210
YD733093
YD798040
ZC022920
Y098OQOO
1A
IB
n
UTM
Y0789071
Y0160408
YC325408
YC544S8Q
Y0538Q16
Y0626083
ZC040S70
ZC865972
YC922B32
ZC040851
YC980846
YC911B6 7
YC665788
YC665950
ZC040860
YC972«54
YC914872
Y0250282
Y0490283
1A
IB
1C
1A
IB
1C
1A
IB
1A
IB
2A
28
Y0795O65
YD400154
YD492129
YD537124
YC782B03
YC851840
YC898ii93
YD280276
Y0470275
YC991920
Y0943004
YC993-J20
Y0947002
�MISSIONS STARTING IN
IG IN
THU* THIEN
PROV NO.
£
681104
681104
681121
661121
631121
681121
631209
681209
681209
681209
631217
681217
681217
681217
681227
681227
681227
681227
681229
6R122<=
681229
681229
68122<5
681229
681231
681231
681231
681231
690130
690130
690209
69020"^
690209
690209
690220
690220
690220
690220
690403
690403
690413
690413
690413
690414
690416
690416
690416
690419
69041^
690419
4GN
0
GALS
3000
TYP
n
0
3000
n
0
0
0
3000
0
0
0
3000
0
0
0
2400
D
r
r>
0
0
0
2200
0
0
0
0
n
3000
0
p
3000
D
r
0
0
0
3
3000
D
0
0
3000
0
0
0
2700
0
0
0
0
0
330
0
3000
0
0
165
2000
D
c
F
D
P
P
0
•o
55
0
0
S
LEG
1A
IB
1A
18
2A
2B
1A
IB
2A
26
1A
18
2A
28
1A
IB
2A
28
1A
IB
2A
28
1A
IB
1A
IB
2A
28
1A
IB
1A
IB
2A
2B
16
IB
2A
2B
1A
IB
1A
IB
1C
1A
1A
IB
1C
.16
IB
1C
UTM
YD745036
YD615000
7.C008920
YC96290Q
ZC011920
YC965900
ZC017920
YD97200O
ZC012920
YD968000
YD738058
YD802028
Y0740Q50
YD808020
YC791970
YD742022
YD725072
YD732092
ZC045930
ZC067936
2C059961
ZC071969
YD736080
YD791052
ZC006920
YC966990
ZC003920
YC963990
YD463244
YD506181
Y043224Z
YD505182
YD478154
YD416211
YD400150
YD494125
YD539122
YD564158
YD587O67
Y0604077
YC543980
YD536018
YD623082
YD533,>21
Y0520O40
YD500136
YD54817U
YD466272
YD463267
UNCLASSIrI=0
�DATc
690419
690419
690419
6?041S690419
690419
6^0420
690420
690420
690421
690421
690421
690421
690421
690421
690421
690422
690422
690422
690422
690422
690422
690422
690422
690423
690423
690423
690424
690424
690424
690424
690425
690425
690425
690425
690427
690427
690427
690427
690427
690429
690429
690430
690430
690430
690430
690503
690503
690503
690503
AGN
p
B
B
n
0
0
n
w
0
n
Q
0
3
0
B
W
3
B
3
W
GALS
0
110
0
2600
0
0
2000
0
0
220
0
0
0
3000
0
0
110
0
220
0
3000
0
0
0
55
110
0
220
0
3000
0
2000
0
0
0
2700
0
0
3000
0
2700
0
65
0
35
35
2000
0
0
0
TYP
F
o
c
•
"- •-•-<
0
P
E
r
p
E
E
0
C
LFG
10
1A
I
B
1A
IB
1C
u
IB
1C
1A
IB
1C
10
It
IB
1C
1A
IB
1A
IB
1A
18
2A
2B
1A
1A
IB
1A
16
IA
IB
1A
18
ZA
C
r
r
f
C
C
n
2B
IA
IB
1C
1ft
IB
IA
18
1A
IB
1A
1A
1A
IB
2A
26
om
YD455275
Y055O040
YD5 80048
VC61Q81Q
YC574&27
YC540795
YC612313
YC574832
YC53979T
YD463287
YD471283
Y9467273
YD4852T5
YC530Q40
YP5O913<»
Y054U76
Y0400275
Y0455275
YO46G322
YD5ZTO35
YO400148
Y 049 312 3
YDS* 1121
YC 5661 5 7
Y04 89198
YD460023
YP526Q35
YD460023
YD526035
YC565530
YD53O030
YC613T93
YC605S09
YC573823
YC540785
YC788791
YC867832
YC916?89
YC555830
YC52998U
YC575&30
YC548980
YC864833
YC 86 0840
YC946344
YC947346
YD400135
YC4C5H9
YD546117
YH570152
�M I S S I O N S STATING IN
O^TP
?,GN
690507
690507
690507
690509
690509
69J510
690510
690511
690511
690511
690511
690511
690513
690513
690513
690513
690513
690513
690513
690513
690513
6 JO 51 3
690513
690513
690513
690513
690513
690513
690513
690513
630513
690514
690514
690514
6S0514
690514
690514
690514
690514
690514
690514
690514
690514
6^0514
690514
690514
6905L4
690514
690514
690514
n
id
W
B
a
B
B
W
•i
GALS
2000
0
0
3000
0
2000
0
3000
0
0
3000
0
62
0
0
0
0
0
0
0
0
12
0
0
0
0
0
0
0
3000
0
41
0
0
0
0
0
0
0
•
B
6
o
41
0
0
0
0
0
0
0
0
28
THIFN
TYP
n .
c
•D
0
C
C
C
r
c
c
r.
PP.OV NO. =
L? G
1A
IB
1C
1A
IB
1A
18
1A
IB
1C
1A
IB
1A
2A
3A
4A
5A
6A
7A
8A
9A
1A
2A
3A
4A
5A
6A
7
7A
1A
IB
IA
2A
3A
4A
5A
6A
7A
8A
9A
1A
2A
3A
4A
5A
oA
7ft
3A
9A
IA
UTM
YC568830
YC558S65
YC538980
YC57383Q
YC542000
YP544015
YD634083
YC780808
YC835832
YC8959Q2
YC533800
YC420950
YC886322
YC382818
YC879313
YC 87 1806
YC 86 1800
YC8558Q2
YC857790
YC&64778
YC 85 7 790
YC 84 7 780
YC833776
YC878777
YC904792
YC 90879 8
YC894774
YC 84 8 75 6
YC559330
YC 5.3 2 930
YC 7^2 80 3
YC822313
YC 8 15360
YC950849
YC784a04
YC7823O7
YC7958i08
YCS02S47
YC8208i86
YC 95 8*2 9
YC817S3S
YC795823
YC737353
YC810SOi3
YC333c(t2
YC956351
YC963317
YC7937ol
YC725893
�'•' 1 S S IONS START ING IN
P4Tc
690514
690514
690514
690514
690514
690514
690514
690514
690514
690514
690514
690514
690517
690517
690517
690519
690519
690520
690520
690523
690523
690525
690526
690526
690531
690531
t.90531
690531
690531
690601
690601
690601
690601
690601
690601
690602
690602
690602
690602
690602
690602
690604
690604
690606
690606
690606
690606
690606
69 060 B
690605
AGN
6
W
GALS
0
0
0
0
0
41
0
0
0
3000
THUA THIEN
************
TYP
C
D
0
0
W
n
2000
P
0
0
3000
D
0
0
0
0
0
3000
0
2000
0
55
3000
P
C
P
D
n
0
275
0
P
0
3000
D
• o
0
0
165
0
P
0
0
1
220
0
55
0
3000
0
0
0
2000
P
P
D
n
0
n
0
3000
n
0
275
0
P
2000
r>
0
D
0
0
W
3000
0
P
L EG
2A
3A
4A
5A
6A
1A
2A
3A
4A
1A.
16
1C
1A
1R
1C
16
IB
1A
IB
1A
IB
l.A
1A
IB
•1A
2A
1A
IB
1C
1A
2A
3A
1A
2A
1A
IA
IB
1C
IA
IB
1C
1A
IB
14
2A
1A
IB
1C
1A
IB
UTM
YC81580d
YC833648
YC95684?
YC956814
YC788802
YC963817
YC793761
YC725893
YC815306
YC 534980
YDS 2 702 5
YH6050S2
YC702800
YC701875
YC 7 00950
YC570330
YC541980
YC50B800
YC380970
YC562830
YC536930
YC397950
YC700750
YC700950
YC397947
YC326927
YC533021
YC626391
YC685088
YC397950
YD406036
YD425011
YC397950
YD4Q6336
YD355071
YC430960
YD55U020
YD590050
YC914SS90
YC924921
YC908960
YC430962
YD542017
YC397950
YD425011
YC425970
Y0540020
YD6160SO
YC428967
YC540016
�UNCLASSIFIED
MISS!Pr!S STARTING IN
OAT E
690608
690608
690609
690609
690609
693616
690616
690616
690617
690617
690617
690617
690618
690618
690618
690620
630621
69J621
690621
690621
690621
690622
690622
690622
690622
690624
690624
690624
690624
690627
690627
690627
690627
690629
690630
690630
690630
690630
690630
690701
690701
690701
690701
690701
690701
690701
690702
690702
690703
6V0703
THUA THIEN
SGN
GALS
0
0
TYP
3
1700
c
0
o
n
n
0
3
g
0
0
3
0
0
0
0
0
n
n
0
0
0
475
0
0
330
0
0
0
110
0
55
330
425
0
2000
0
0
440
0
0
0
2000
0
0
0
495
0
4000
0
465
440
0
3000
0
0
380
0
4000
0
0
0
0
165
0
220
0
PROV NO,
LEG
2A
2B
IA
IB
1C
1A
2A
3A
1A
IB
1C
10
1A
13
1ft
f
p
f
P
P
P
IA
0
P
C
f
n
f
f
p
f
0
.
iA
2A
IA
IB
1C
IA
2A
3A
4A
1A
IB
2A
28
IA
IB
IA
IB
IA
IA
16
IA
IB
1C
iA
IB
IA
IB
1C
2" A
F
P
26
IA
IB
1A
2A
UTM
YD6280d8
Y0650086
YC787794
YC684ii37
VC9Q8838
YC397953
YD4250U
YD343194
Y053CU20
YC397950
Y 03 5 5 07 I
YD425011
YD473Q31
YD450015
YD355d37 1
Y034-3194
YD355Q71
YC439^67
AT956&92
AT956-925
AT936947
YO3&5O71
Y0425011
YC4399&7
Y0623ff96
YC 42 6976
¥052602 1
YD617O09
YD68QO«8
Y 06 50096
>Yi>57OO50
YD2.ft026 5
YD4702&4
YD32425?
Y 04 7 3 03 1
YD450Q15
YC 42 3 97 7
YD534fc027
Y06O4O83
YD4-52O30
YC439565
YC4 56995
Y 04 5 201 5
YC472027
Y 049 3 03 2
Y0523027
YD472030
YC<*39965
YD355071
YD406036
�0,'Tc
690704
690704
690705
690705
690706
690706
650706
690706
690706
69070V
690709
690713
690713
690713
690715
690715
69J716
690716
690717
690717
690717
690718
690713
690718
690718
590718
690721
690721
690722
690722
690724
690724
690726
690726
690726
690726
690727
690727
690727
690806
690806
690806
690806
690813
690814
690814
690323
690S23
690823
69DS24
AGN
0
(J
n
0
0
fj
0
0
0
0
0
0
n
0
0
a
w
w
B
W
3
n
TYP
GALS
P
335
0
4000
D
0
0
4000
0
D
4000
0
0
n
6000
0
D
3000
0
0
p
6000
0
D
5000
0
D
4800
0
0
F
250
0
2600
C
0
0
D
3000
0
0
2800
0 '
D
1800
0
3500
D
0
0
0
D
2000
0
0
3000
P
0
0 - • .. „
0
P
480
5000
D
0
P
320
4000
C
0
p
2700
LEG
1A
2A
1A
IB
1A
18
IA
IB
1C
1A
IB
1A
IB
1C
1A.
IB
1A
IB
1A
IB
1C
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
1C
ID
1A
IB
1C
Ifl
IB
1C
10
1A
1A
IB
1A
IA
IB
It
UTM
YD355071
YD406036
YC521772
YC385928
YC568828
YC450982
Y0243103
YD308055
YC33694Q
YC881966
YD712062
Y0250095
Y0303053
YC382938
YC 879962
YD705050
YC878957
YD631057
ZC060930
ZC060860
ZC 11 0 4
88
AT951898
AT9 53926
ZC053927
ZC053867
ZC1 10852
Y0299104
YC435973
ZC065926
ZC065862
ZC068925
ZC068867
ZCQ62927
ZC062860
ZC130844
ZC157S49
ZC042930
ZC042342
ZC110826
YCS42987
YC977852
ZCQ40852
ZC110835
YC435965
YC531815
YC395992
YP529O28
YD310114
YC447982
YC553316
<
/
f
�UNCLASSIFIED
MISSIONS STARTING IN
IG IN
THUS
THI EN
PROV NO. =
& 2rsfr£-^- •±-^- -A* £••&>& &
ff
AGN
690824
690824
690830
690830
690G30
690P30
690905
690905
690911
690911
690911
690911
690912
690912
690912
690912
690913
690913
690915
690915
690915
690915
690921
f.90921
690921
690921
690922
690922
690923
690923
690923
690923
690923
690924
690924
690925
690925
690926
690926
690927
690927
69092S
690928
690928
690928
690929
690929
690929
690929
690929
W
B
0
0
o
3
3
0
0
0
0
0
0
0
0
0
0
0
0
Q
W
GALS
0
0
100
140
5000
0
4000
0
4000
0
4700
0
4800
0
2500
0
3600
0
6000
0
5800
0
4700
0
3800
0
6000
0
5000
0
0
5000
0
5000
0
3500
0
4500
0
2000
0
3800
0
4000
0
6000
0
TYP
2100
r
0
0
P
P
0
r
0
D
r
D
0
C
P
P
0
c
c
r
D '
D
.c
D
D
P
D
LQG
18
1C
1A
IA
IA
18
1A
16
1A
IB
1A
is
1A
IB
1A
IB
IA
16
IA
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IE
1C
IA
IB
1A
13
1A
IB
1A
IB
1A
IS
1A
IB
1A
IB
14
IB
1A
IB
1C
UTM
YC503804
YC684924
¥0758856
YC53 180.8
YC425950
YC533833
YC4Q7999
YC 56 3 32 4
YC445980
YD310115.
¥0446984
YC531803
YC423S48
YC791342
YC711974
YC561822
YC444979
YC559821
YC440<i7!7
Y0303108
YC440977
YC492845
YC793844
YC713573
YC52078Q
YC384959
Y0242Q93
Y03O1Q52
YC380935
Y0313H7
YC450984
YC498818
YC381974
Y0315U9
YC453987
YC329U5
YC458990
YC532813
YC418969
YC571828
YC4489S7
YC534817
YC403999
YC554318
YC435973
YC440968
YC490013
�O'-TE
690929
690930
690930
690930
690930
691014
691014
691015
691015
691015
691015
691016
691016
691016
691016
691016
691016
691016
691018
691018
691019
691019
691019
691019
691020
691020
691020
691020
691020
691024
691024
691024
691024
691031
691102
691102
691105
691105
691111
691111
691112
691112
691113
691113
691113
691113
691113
691115
691115
691115
AGM
W
0
0
W
0
W
0
0
0
0
n
3
e
n
0
B
3
%
3
3
3
0
3
0
GALS
0
1300
0
0
0
4000
0
165
0
6000
0
4300
0
1500
0
0
0
0
2400
0
2000
TYP.
2000
0
3000
0
0
0
0
330
0
275
0
110
2400
0
2400
0
160
120
160
0
160
40
40
1700
0
120
1900
0
D
• o
D
LEG
10
1A
IB
1C
10
D
1A
IB
P
1A
2A
1A
18
1A
IB
1ft
IB
1C
2A
2B
1A
IB
1A
IB
1A
18
IA
IB
1C
2A
28
1A
IB
1A
IB
1A
IA
IB
1A
P
D
C
0
D
D
F
F
P
D
r
p
F
F
P
P
P
n
p
c
IB
iA
14
1A
IB
1A
1A
IA
1A
IB
1A
1A
IB
UTM
YC53C028
YC440920
YC455995
Y0452015
YD494033
YC797846
YC 716976
YC836996
YC 863938
YC490839
YC368998
YD316121
YC453987
YC440967
YC459996
Y0457Q14
Y0495028
YD527026
YC796349
YC718973
YC697760
YC697950
YC697760
YC697950
YC440967
YC459996
YD45 7Q1 4
YD495O28
Y0527026
YD680Q92
YD62O094
YP68 0 9 2
0.
Y 062 009 2
YC4S0197
Y0452232
Y0595123
Y033O339
YD436238
YC835996
YC8649S8
YC 88 8986
YC 864938
Y04<-O198
YD577172
YDS 1 6.2-20
YC7i}0031
Yr8939i63
YP762056
Y0455234
YD521190
�M I S S I O N S STARTING IN
04TF
691115
691121
S91121
691121
691121
6^1121
691201
691201
691206
691206
691206
691206
691207
691207
691214
691223
691223
691227
691227
691230
691230
691231
691231
700121
700121
700214
700214
700214
700214
700214
700214
700219
700219
700219
700219
700221
700221
700221
700221
700221
700221
700221
700221
700221
700221
700221
700221
700221
700221
700221
AGN
0
8
GALS
0
150
0
510
0
200
B
o
3000
0
2000
0
F
P
D
2900
D
0
220
40
620
655
p
p
p
p
2190
F
2000
0
3000
0
3
n
0
0
F
0
55
0
n
TYP
r
c
c
p
0
0
0
THUA THIEN
************
B
0
350
0
110
0
0
0
C
8
2100
C
0
0
9
B
3
3000
0
0
0
100
0
0
0
0
100
0
0
0
0
0
F
r
c
c
PROV NO.
LEG
1C
1A
18
1A
16
1A
1A
IB
1A
16
1A
18
1A
IB
1A
1A
IB
1A
1A
1A
1A
1A
18
1A
IB
1A
IS
1C
10
1A
IB
1A
IB
1C
10
1A
IB
1C
ID
IF.
1A
IE
IF
1G
1H
1J
0
IK
0
0
1L
1M
2A
0
UTM
YP599128
YC680092
YD616087
YP680092
YD616037
YP6200S5
YD457238
YD599129
YD455235
Y0598127
YD749043
YD595132
YO745036
Y0595123
YD324258
YO748039
YD598128
VD620O95
¥0620095
YC 864588
YD490198
YD680092
Y06 16087
YD6 18094
YD599073
YC614936
YC 636941
YC597935
BS600924
YP325132
Y04530O1
YD244103
YD3Q8057
YD314038
YC 3 85=40
YC672860
YC632932
YC672362
YC632&97
YC637388
YC630935
YC&30935
YC 62 593 6
YC615935
YC630698
YC6C0928
YC673864
YC600932
YC.601926
Yf 62 5936
�MISSIONS STARTING IN
04TF
651115
&91121
691121
691121
&91121
691121
691201
691201
691206
691206
691206
691206
691207
691207
691214
691223
691223
691227
691227
691230
691230
691231
691231
700121
700121
700214
700214
700214
700214
700214
700214
700219
700219
700219
700219
700221
700221
700221
700221
700221
700221
700221
700221
700221
700221
700221
700221
700221
700221
700221
AGN
0
3
GALS
0
150
0
510
0
200
&
n
3000
0
2000
0
THUA THIEN
************
TYP
F
F
P
D
r
0
0
2000
D
0
0
0
0
n
6
o
0
0
0
8
8
3000
0
55
D
2900
P
D
0
220
40
620
655
P
.P
P
P
2190
0
350
0
110
0
0
0
2100
F
F
C
c
0
3
3000
P
B
0
0
0
100
0
0
0
c
3
100
0
0
0
0
0
0
0
0
0
0
c
LEG
1C
1A
IB
1A
IB
1A
1A
IB
1A
IB
1A
IB
1A
IB
1A
1A
18
1A
1A
1A
1A
1A
18
1A
18
1A
IB
1C
ID
1A
IB
1A.
15
1C
ID
1A
IB
1C
10
IE
IA
IE
IF
1G
1H
1J
IK
1L
1M
2A
UTM
YD599128
YC680092
YD616087
YD680092
Y0616087
Y0620095
YD457238
Y0599129
YD455235
YD598127
Y0749043
YD595132
Y0745036
YD595123
YD324258
YD748039
YD598128
YD620095
Y0620095
YC 864 98 8
YD490198
YD660092
YD616087
YD618094
YD599073
YC614936
YC636941
YC 5 9 793 5
BS600924
YP325132
YD453001
YD244103
YD308057
YP314038
YC385940
YC672860
YC632932
YC672862
YC632&97
YC637883
YC630935
YC630935
YC625936
YC615935
YC630898
YC600928
YC673864
YC600932
YC601926
YC625936
�DM-.
700221
700221
700223
700223
700223
700302
700302
700303
700303
700303
700313
700313
700330
700330
700331
700331
700409
700409
700409
7UJ410
700410
700410
700410
700411
7004 11
700411
700411
700411
703411
700411
700411
700417
700417
700417
700417
700419
700419
700420
700420
700510
7J3510
700510
700510
700510
700510
700510
700510
700510
700510
730510
AGN
B
0
B
n
0
n
0
n
0
8
3
0
W
W
3
3
GALS
0
0
3000
0
0
3000
0
2000
0
0
3000
0
2900
0
3000
0
2000
0
0
65
0
0
0
150
0
0
0
1600
0
1500
0
255
0
0
Q
3000
0
2100
0
75
0
0
0
0
0
0
0
0
53
0
TYP
P
0
r
LEG
3ft
4A
1A
IB
1C
1A
IB
1A
16
D
P
0
r
F
E
0
0
S
D
P
C
1C
1A
16
1A
IB
1A
18
1A
IB
1C
1A
IB
2A
28
IA
IB
1C
10
1A
18
IA
1-8
1A
IB
1C
ID
1A
IB
IA
16
1A
2A
34
4fl
5A
6A
7A
3A
9A
C
1A
2A
UTM
YC615935
YC630S98
YD244107
¥03 I 0060
YC389942
YD360140
YP509041
Y0326133
YD358097
YC453008
YC354147
YD508040
Y0535031
YC684949
YD357152
YD51O043
Y0541023
YC619974
YC682943
YD307187
YO320177
YD3Q5176
YD310180
YD30Q19O
YD321182
Y0312187
YD322181
Y0328135
YD455004
YD323128
YC457998
YC640130
YD663130
YD64O105
YD668105
Y0357150
YD509O42
YD34613S
Y051OO27
YD047257
Y0089262
YD119288
YO075265
YP082259
YD084249
YH034231
YD055254
Y0102272
YP037272
Y0080254
�MISSIONS STARTING IN
Di"
700.'.'0
,,''AGN
'
700531
700531
700531
700601
700601
700715
700715
700902
700922
TYP
0
70J5io
f
I
'
i
:
.
t
,'
i
GALS
THUA THJEN
B
B
B
B
B
B
3
0
0
825
710
913
0
225
0
495
0
450
450
PROV NO.
LEG
UTH
4A
'
' F
"- -*
F
F
F
P
P
Y0095263
5A
6A
11
IA
1A
IB
IA
IB
1A
IB
1A
1A
YD!33267
Y0044287
YD550035
Y062Q095
YD62C095
Y0550035
YD62C095
YD55Q035
YD620095
Y0550035
YD490198
YD620095
UNCLASSIFIED
UNCLASSIFIED
�NREC= 16927
NREC = 16927
NPCOV=
?4PROV=
457
457
NZR=C=
N^REC=
756
756
UNCLASSIFIED
�M I S S I O N S STARTING IN
PSTE
660217
660217
660217
660217
660217
660217
660218
660218
660218
660218
660219
660219
660219
660219
660219
660219
660220
660220
660225
660225
660225
660225
660225
660615
660615
660619
660619
660622
660622
660624
660624
660703
660703
660817
660817
660817
66081?
660822
660822
660822
66J822
660825
660902
660902
660903
660903
660903
660903
660<?08
661011
AGN
0
0
0
Q
0
0
p
o
0
f)
0
n
n
GALS
4000
0
0
0
0
0
2'000
0
0
0
1500
0
0
0
0
0
3000
0
1650
0
0
0
0
2000
0
2000
0
800
0
1000
0
1000
0
500
0
. 0
0
1400
0
0
0
1000
Q
1000
0
2000
0
0
0
2000
2700
0
n
w
QLMNG NAM
TYP
C
C
c
c
c
D
D
D
D
D
C
C
c
c
c
c
r
PROV NO. =
LEG
IA
IB
2A
28
3A
38
1A
IB
2A
2B
1A
IB
2A
2B
3A
3B
1A
IB
1A
IB
2A
2B
2C
1A
IB
1A
16
1A
18
1A
13
1ft
18
1A
IB
2A
23
1A
IB
2A
26
IA
IA
18
1A
16
2A
2B
1A
1A
UTM
YC 82 0570
YC980610
YC980570
ZC030575
YC780480
YC880545
YC820570
YC980610
YC780480
YC880545
YC880470
YC900470
YC780480
YC810480
YC380490
YC900490
YC900325
ZC100380
YC955290
YC950332
YC830320
YC836350
YCS45320
AT924909
AT924871
AT935870
AT928930
AT920910
AT920930
AT937870
AT930930
A, T9 3 0930
AT920875
YC900330
YC960330
YC900290
YC960290
ZC040340
ZC1003dO
ZC040380
ZC100340
YC820530
YC 805495
YC855522
YC820560
YC990560
YC820630
YC990630
YC900600
YC900470
.<.
Ft'=0
�11* TF
660217
660217
660217
660217
660217
660217
660218
66021S
660218
660218
660219
660219
66021°
660219
660219
660219
660220
660220
660225
660225
660225
660225
660225
660615
660615
660619
660619
660622
660622
AGN
0
660624
660624
660703
6S070.?
660817
660817
660817
660817
660822
660822
0
660822
660822
660825
660902
660902
660903
660903
660903
660903
660908
661011
0
0
0
0
0
0
o
o
GALS
4000
0
0
0
0
0
2000
0
0
0
1500
0
0
0
0
0
3000
0
1650
0
0
0
0
2000
0
2000
0
800
0
1000
0
1000
TYP
C
c
C
c
c
r>
0
0
D
D
0
0
n
g
0
Q
n
w
500
0
0
0
1400
0
0
0
1000
1000
0
2000
0
0
0
2000
2700
C
C
c
c
V
c
c
LEG
1A
16
2A
28
3A
38
1A
IB
2A
26
1A
IB
2A
28
3A
3B
1A
IB
IA
IB
2A
2B
2C
1A
IB
1A
IB
1A
IB
1A
18
14
IB
IA
18
2A
28
1A
IB
2A
29
1A
1A
18
1A
IB
2A
28
1A
1A
UTH
YC820570
YC980610
YC980570
ZC030575
YC780480
YC880545
YC820570
YC980&10
YC780480
YC880545
YC880470
YC900470
YC780480
YC810480
YC880490
YC900490
YC900325
ZC100380
YC955290
YC950332
YC830320
YC836350
YC345320
AT924909
AT924871
AT935870
AT92893Q
AT920910
AT920930
AT937870
AT930930
AT930930
AT920875
YC 9 00330
YC960330
YC900290
YC960290
ZC040340
ZC100330
ZC040380
ZC100340
YCS20530
YC 805495
YC855522
YC820560
YC990560
YC820630
YC990630
YC900600
YCS) 00470
UNCLASSIFI5D
DNCl.ASSIFI'30
�Ill ^>b U'Nb
b I AK I
iiy
IN
y UAtvil7
i^A )*S
£ jgr* *••& 4r4r*r -tr *•<*•*
GALS
0
0
0
TYP
1800
AGN
S61011
661011
661011
661011
661011
661011
661011
661117
661117
661117
661117
670330
670330
670331
670331
670331
670331
670516
670516
670516
670516
670527
670527
670605
670605
670605
670605
670605
670605
670618
670618
670929
670929
680529
630529
600607
680607
630611
630611
680613
680613
630615
630615
630620
680620
680625
680625
6B0625
680625
680629
C
0
0
0
W
1800
0
0
W
1800
C
0
0
2360
0
c
0
1860
0
0
0
2790
0
D
0
1700
C
0
n
a
B
0
0
0
o
o
o
c
0
0
0
2000
0
2360
0
0
0
0
0
1860
0
2000
0
2000
0
3000
0
1900
0
2000
0
2000
0
2000
0
3000
0
0
0
3000
C
c
c
c
n
0
D
C
C
c
n
D
LEG
IB
2A
26
1A
IB
2A
28
1A
IB
1A
18
U
IB
1A
IB
IA
IB
IA
19
2A
2B
1A
IB
1A
18
2A
28
3A
3B
1A
IB
1A
IB
1A
ie
1A
16
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
U
UTM
YC940630
YC800460
YC99O560
ZC110660
ZC090660
YC999665
YC975665
ZC175564
ZC203566
ZC125580
ZC168555
AT934920
AT936863
AT945925
AT885S54
AT947920
AT948890
YC385554
YC927551
YC961563
ZC063568
YC775486
YC 8S 9 4 7
5
YC840-620
YC890630
YC97O67Q
YC99O670
ZC110640
ZC090670
YC830350
YC960360
ZC01Q660
ZC180660
ZC142263
ZC195317
ZC140260
ZC210330
YC770651
YC925645
ZC092225
AT799326
YC775659
YC934657
ZC070254
ZC208346
YC769647
YC815616
YC850614
YC935644
YC767644
UNCL4SS!FI=P
�M I S S I i'NS
I
04 T £
60G6Z9
68iJ630
680630
680705
680705
680706
680706
680736
680706
680706
68U708
680708
680703
680708
680708
S T A R I ING
4 ON
O
0
n
0
0
i~j
' J
6 SO 70 K
680708
680708
680708
680709
680709
680711
680711
680711
680715
680715
680713
680718
680720
680720
680720
680720
630721
630721
680723
630723
6S0723
680727
680727
680730
680730
680902
630802
630802
680802
680802
630803
680803
680803
680808
0
0
Q
0
IN
GALS
0
2800
0
3000
0
2000
0
0
2850
0
2000
0
0
2000
0
0
0
3000
0
4500
0
3000
0
0
3000
o0
0
w
0
0
0
n
0
n
n
6000
0
2000
0
0
0
3000
0
3000
0
0
2000
0
3000
0
3000
0
0
6000
0
3000
0
0
2500
WUANb NAM
************
TYP
LEG
18
C
1A
18
D
1A
IB
D
1A
IB
1C
n
'
1A
IB
0
1A
IB
1C
0
1A
IB
2A
26
D
1A
IB
D
1A
IB
D
1A
IB
1C
1A
C
IB
f
1A
IB
D
1A
IB
2A
28
C
1A
IB
o
IA
IB
1C
1A
r
IB
r
IA
IB
D
1A
18
1C
D
1A
IB
r;
ItIB
1C
IA
o
UTM
YC940642
ZC070240
ZC212325
YC772653
YC940650
ZC070228
ZC162228
AT798307
8T047549
AT953549
YC791787
YC869827
YC9286S7
YC770657
YC820624
YC846621
YC943655
ZC150910
ZC100973
AT950546
BT070546
YC780638
YC850610
YC930640
YC972653
YC938654
BT058527
AT887527
YC773658
YC819626
YC846623
YC940657
BT070538
AT945538
YC94O645
ZC020674
ZC 11 0670
YC94Q664
ZC138632
YC940644
ZC135660
YCS06493
YC844520
YC825610
ZC070250
ZC210340
YC940639
ZC070644
ZC130659
YC805490
�MISSII:'Mi
DATE
680808
630809
680809
680809
680S09
630810
630310
680812
680812
680814
680814
630820
630820
680820
680821
680821
630822
680822
630822
630824
680824
680824
630825
680825
680825
630825
6S0825
680825
680826
680326
680826
630827
680827
680828
&30828
680829
680829
680829
680830
680830
63C830
680908
630908
680909
680909
680910
680910
680910
630910
680914
STARTING IN
AGN
0
0
0
a
0
0
0
0
0
0
0
0
0
n
0
n
0
0
o
GALS
0
3000
0
0
0
3000
0
3000
0
3000
0
6000
0
0
3000
0
4600
0
0
4000
0
0
2000
0
0
0
3900
0
6000
0
0
2000
0
3000
0
3000
0
0
3000
0
0
3000
0
2900
0
1850
0
0
0
3925
lJUANG NAM
************
TYP
D
LEG
IB
1A
IB
24
2B
1A
10
IA
18
IA
18
1A
16
1C
1A
P
1A
C
o
n
C
D
IB
IB
n
D
c
D
n
D
P
D
D
D
D
n
1C
IA
IB
1C
1A
IB
2A
28
1A
IB
1A
18
1C
1A
18
1A
13
1A
18
1C
1A
IB
1C
1A
18
1A
13
IA
iB
2A
26
IA
UTM
YC825613
YC940644
Y0020633
YD070683
YC137662
YC8064S8
YC825613
YC848484
YC981596
YC940652
ZC140665
ZC070240
ZC140242
ZC206325
YC940i&67
ZC02O682
ZC070234
ZC140234
ZC210315
ZC070246
ZC132246
ZC209335
YC94O646
ZC020666
ZC020670
ZC 13 5664
YC 84 049 3
YC96560O
ZC07Q223
ZC148223
AT791310
YC 846486
YC9826.02
YC815515
YC955644
YC940665
ZC120678
ZC006678
YC806486
YC853515
YC824612
YC799524
YC950660
YC844481
ZC040481
ZC175122
ZC205153
ZC10690B
ZC156869
YC907519
UNCLASSIFIED
�MISSIONS
DATE
680914
680517
630917
630917
680921
680921
681004
631004
631004
68100^
681007
681007
681010
631010
690211
690211
690211
6903 18
690318
690318
690320
690320
690320
690327
690327
690327
690328
690328
690323
690324
690328
690323
69041 1
690411
690411
690411
690411
690412
690412
690412
690412
690413
690413
690413
690413
690417
690417
690417
690417
690417
STAKTlNti
AGN
0
W
W
W
W
n
a
0
W
B
0
0
0
n
IN
GALS
0
2800
0
0
5000
0
2000
0
0
0
4000
0
4000
0
3000
0
0
3000
0
0
3000
0
0
3000
0
0
8250
0
0
0
0
0
3000
0
0
0
0
3000
0
0
0
3000
0
0
0
3000
0
0
0
0
QUANC NAM
TYP
D
C
0
D
n
D
D
D
D
E
UTM
ZC060519
ZC100642
AT815654
AT860680
YC834491
YC986621
ZC180825
ZC147841
ZC122832
ZC059854
YC971854
YC911875
YC850432
YC993607
YC940655
ZC020677
ZC060680
ZC090648
AT813658
AT857636
ZC090659
AT811669
AT852695
ZC090650
ATS 15660
AT850685
AT970570
AT9706OQ
AT980600
AT98360Q
BT012560
AT970570
ZC18Q845
ZC147860
ZC12285.0
ZC062869
ZC040869
YC910638
ZC019658
ZC070663
ZC130663
LEG
IB
1A
IB
1C
1A
IB
1A
IB
2A
26
1A
IB
1A
13
1A
. IB
1C
IA
IB
1C
16
18
2B
IA
IB
1C
1A
IB
1C
10
IE
IF
C
n
c>
p
1A
IB
1C
10
IE
1A
IB
2A
28
1A
IB
2A
28
1A
IB
1C
2A
26
zcisae25
.
ZC145342
ZC 121 832
ZC060853
ZC180035
ZC145854
ZC121340
ZC060S63
ZC040863
UNCLASSIFI=0
�llSiiUNb
Of.TE
690424
690424
693426
690426
690427
690427
690427
690427
690427
690427
&90511
690511
69051 1
690511
690511
690511
690511
690511
690512
6-70512
690515
690515
690515
690513
690518
690518
690522
690522
690525
690525
690526
690526
690526
690526
690526
690526
690526
690526
690526
690526
690527
690527
690528
690528
69052 B
690528
690526
690523
690529
690529
SlAKTINii
AGN
3
B
0
0
0
W
W
W
B
n
0
0
0
0
0
IN
QUANb NAM
GALS
TYP
2700
C
0
1500
D
0
495
F
0
0
0
0
0
110
fc
0
0
0 '-• - ~223
W
0
0
0
3000
P
0
2900
C
0
0
3000
D
0
0
3000
0
0
3000
D
0
2090
E
0
0
0
0
0
0
3000
D
0
0
3000
D
0
220
W
0
0
0
0
0
2500 '
D
•o
LFG
1A
IB
1A
18
1A
IB
1C
10
IE
IF
1A
IB
1C
ID
16
IB
1C
ID
1A
IB
1A
18
1C
1A
IB
1C
1A
IB
1A
IB
1A
IB
1C
2A
2B
2C
2D
1A
IB
1C
i\
IB
1A
IS
1C
ID
IE
IF
IA
lb
UTM
BT070545
ST982545
AT963927
AT948943
BS914239
BS917239
BS914246
BS915256
BS912259
8S901259
BS927222
BS927219
BS931219
BS931222
BS865339
BS880339
BS860315
BS864315
ZC14C632
AT650673
ZC13O616
AT795616
AT859661
ZC141&41
ZC198657
A.T850685
AT947545
BT071545
ZC145635
AT350&30
BT110620
BT127630
BT110650
BT110650
OT085640
BT077660
BT105660
YC924547
YC 93949 2
ZC058506
YC990368
ZC091258
BS74943S
8S749415
8S740415
3S760415
3S760438
^5749438
YC933551
YC949507
UNCLASSIFIED
�DATE
690529
690602
690602
690602
690603
690603
690603
690603
690603
690603
690603
690603
690603
690604
690604
690604
690605
690605
690605
690605
690605
690605
690605
690605
690605
690605
690605
690605
690605
690605
690606
690606
690606
690606
690606
690606
690607
690607
690607
690609
690609
690609
690609
690609
690609
690609
690611
690611
690613
690613
AGN
D
D
0
0
0
0
0
0
H
W
W
W
0
!!
0
0
GALS
0
2000
0
0
2000
0
0
3000
0
0
0
3000
0
3000
0
0
3000
0
0
0
2000
0
0
0
3000
0
2000
0
0
0
3000
0
3000
0
0
0
3000
0
0
3000
0
0
3000
0
0
..0
4000
0
3000
0
TYP
0
LrG
1C
1A
IS
D
D
P
P
D
D
n
D
D
D
D
P
0
1C
1A
IB
1C
1A
IB
1C
10
1A
IB
1A
IB
1C
IA
IB
1C .
10
1A
IB /
1C
ID
1A
IB
1A
18
1C
ID
1A
IB
IA
IB
1C
ID
IA
IB
1C
1A
IB
1C
IA
IB
P
n
2A
2B
1A
16
1A
IB
UTH
ZC064520
YC900540
ZC02U570
ZC120570
YC910555
ZC020578
ZC091-575
ZC162794
ZC146763
ZC123745
ZC102672
ZC148632
AT850680
YC949347
ZC024418
ZC065507
ZC064864
ZC130840
ZC153848
ZC165J40
ZC169790
ZC130740
ZC154759
ZC109671
ZC149629
AT850675
ZC 16 7 79 2
ZC127742
ZC152761
ZC107671
ZC143639
AT850689
YC725643
YC804611
YC820611
YC912631
YC901553
ZC017532
ZC083578
YC898557
ZC015584
ZC083582
YC725644
YC800615
YC876616
YC945652
ZC024400
ZC063508
YC876533
YC912548
�DATE
690613
690613
690615
690615
690615
690615
690618
690616
690618
690618
690618
690618
690618
69061SI
690619
690619
690620
690620
690620
690620
690621
690621
690621
690621
690622
690622
690622
690622
690624
690624
690624
690624
690625
690625
690625
690626
690626
690626
690626
690630
690630
690710
690710
690710
690713
690713
690713
690713
690713
690717
AGN
GALS
TYP
0
0
0
3000
D
0
0
0
0
1400
0
0
0
0
0
0
0
1800
0
0
2800
0
0
3000
D
D
D
0
0
0
0
0
0
0
o
n
0
0
n
0
3000
0
0
0
2000
0
. 0
0
2000
0
0
0
4000
0
0
3000
0
0
0
2000
0
6000
0
0
80
0
7000
0
0
5000
0
D
P
D
D
D
0
P
C
D
LEG
2A
26
1A
IB
1C
10
1A
IB
1C
ID
1A
IB
1C
1A
IB
1C
1A
IB
1C
10
1A
IB
1C
10
1A
IB
2A
2B
1A
IB
2A
28
1A
IB
1C
1A
IB
2A
28
1A
IB
1A
IB
1C
1A
IB
1A
18
1C
1A
UTM
ZC020573
ZC052572
YC731658
YC810626
YC863627
YC941662
ZC176736
ZC161754
ZC136733
ZCU7668
ZC93555Q
ZC9475J5
BT063517
YC932549
YC945500
ZC060515
ZC72t647
ZC801615
ZC907634
ZC872615
YC720658
YC805623
YC863623
YC940660
AT95Q527
BTOQ3527
4T976545
AT950545
YC873619
YC940652
YC 72 764 8
YC80O619
YC953345
ZC035424
ZC065506
YC726&48
YC800620
YC87O620
YC945651
ZC 14463 7
AT 85 068 3
ZC100230
ZC185232
AT815260
8T215562
BT180540
ZCOB2244
ZC146247
4T798332
7.C072256
�OATP
690717
690717
690719
690719
690719
690722
690722
690724
690724
690724
690724
&90724
690724
690724
690724
690724
690724
690724
690724
690724
690725
690725
690801
690801
690801
690801
690301
690801
690801
690801
690801
690802
690802
690802
690803
690803
690803
690803
690803
690803
690807
690f07
690807
690807
690807
690807
690807
690807
690607
690809
AGN
0
0
0
0
0
0
0
0
n
0.
0
W
w
w
w
n
GALS
0
0
4000
0
0
1525
0
3000
0
0
0
3000
0
0
0
1500
0
2000
0
0
1500
0
3000
0
0
2500
0
0
2500
0
0
2000
0
0
2000
0
0
2000
0
0
3000
0
0
0
0
2000
0
0
0
3000
TYP
D
P
P
D
n
n
D
D
P
D
r.
0
0
P
P
f!
LEG
IB
1C
1A
IB
1C
IA
13
1A
IB
1C
ID
1A
IB
1C
ID
1A
IB
1A
IB
1C
1A
IB
1A
18
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
IA
13
1C
1A
IB
1C
IA
IB
1C
10
IE
1A
18
1C
10
IA
UTM
ZC140260
AT780330
YC93255Q
YC945505
ZC062517
ZC130846
ZC162852
YC730656
YC8 10622
YC363621
YC950563
ZC165794
ZCl4ci762
ZC127745
ZC105672
ZC135350
ZC185861
YC903558
YC020575
YC117569
ZC155224
ZC213162
YC928548
YC940500
ZC062514
YC751760
YC 7 8 9690
YC791630
YC819633
YC 873682
YC950687
YC 8 1363 4
YC870684
YC960691
YC8H639
YC 96869 3
YC9606S9
YC816635
YC 36 968 5
YC960694
YC825632
YC930680
YC954667
YC980682
ZC0036S2
ZC 17 0790
ZC155753
ZC 13273 S
ZC110670
YC830630
0
�PATF
690809
690809
69080?
690809
690815
690815
690815
690913
690913
690913
690914
690914
690914
690914
6S0914
690914
690914
690922
690922
690922
690929
690929
690929
690929
690929
691001
6^1001
691010
691010
691010
691012
691012
691012
691012
691012
691013
691013
691013
691013
691013
691013
691014
691014
691016
691016
691016
691016
691017
691017
691017
4GN
0
0
0
0
0
w
w
0
w
n
0
o
0
w
w
GALS
0
0
0
0
3000
0
0
2700
0
0
3000
0
0
2500
0
0
0
3400
0
0
2800
0
0
0
0
4600
0
2900
0
0
5000
0
0
0
0
3000
0
0
3000
0
0
1900
0
3000
0
0
0
1800
0
2000
TYP
P
P
P
0
D
0
D
D
P
D
D
P
0
D
D
L£G
IB
1C
10
IE
1A
16
1C
IA
IB
1C
1A
IB
1C
1A
IB
1C
ID
1A
18
1C
1A
IB
1C
2A
26
1A
18
1A
IB
1C
1A
IB
1C
2A
28
1A
IB
1C
1A
IB
1C
1A
IB
1A
IB
1C
IP
1A
IB
1A
UTM
YC930676
YC950665
YC982679
ZC003679
YC754761
YC792690
YC794633
YC757761
YC 7 95690
YC797633
YC926547
YC942493
ZC059508
ZC173787
ZC158756
ZC134731
ZCU36fO
YC764763
¥C 79 7 69 5
YC799633
YC936550
YC949507
ZC063520
YC931541
YC943499
ZC061512
YC890455
ZC065240
ZC178246
ZC210279
YC835624
YC927664
YC953668
YC995668
ZC005668
YC935550
YC949505
ZC063518
YC955342
ZC040425
ZC069505
YC978356
ZC083247
YC731658
YC808527
YC862627
YC941622
ZC023668
ZC154662
YC893562
�IG
MISSIONS STARTING IN
PROV NO.
QUANG NAH
EA
s
^ ^^^^Jfc^^^^^ *
691017
691017
691019
691019
691019
69101°
691019
691021
091021
691021
691022
691022
691023
691023
691023
691024
691024
691024
691024
691024
691025
691025
691025
691118
691118
691118
691118
691118
691118
691230
691230
691230
691230
691230
691230
691230
700203
700203
700222
700222
700?22
700224
700224
0
0
0
0
n
o
GALS
TYP
0
0
3000
D
0
0
0
0
2600
0
0
0
3000
D
0
3000
D
0
0
3000
D
0
3000
D
0
0
3000
P
0
0
2400
T
0
0
0
0
0
2000
D
0
0
0
0
0
0
2400
.
D
0 v .....
2700
P
0
0
2600
P
0
LEG
IB
1C
1A
IB
1C
2A
2B
1A
IB
1C
1A
IB
1A
IB
1C
U
IB
1ft
IB
1C
1A
IB
1C
U
IB
1C
2A
28
2C
1A
IB
1C
1-0
2A
28
2C
1A
IB
1A
IB
1C
1A
IB
UTM
ZC019586
ZC092580
YC833628
YC930671
YC951659
YC985675
ZCOG4675
YC932549
\
YC946502
ZC062515
ZC200332
ZC047419
YC959339
YC048425
YC07550E
YC988367
ZCU9O258
/
YC 95 8340
ZC 04442 6
/
ZC067503
YC 9 7 935 7
ZC053286
ZC085252
ATB 83829
*
AT871770
AT883746
AT876730
AT884717
AT 90 2 7O 7
AT86883O
AT866800
AT863790
AT8577A6
AT859732
AT8757O8
AT 89 769 7
ZC170899
AT900899
ZC 1 70901
ZC 197900
AT900901
YC967364
ZC088255
UNCLASSIFIED
�NREC= 17597
NREC= 17597
NPP.OV=
NPROV=
178
178
NZREC=
NZREC=
365
365
�OATF
660209
660209
66020?
660209
660209
660209
660209
660209
660209
660211
660211
660211
660211
660211
660211
660211
660211
660212
660212
660212
660212
660607
660607
660607
660607
660611
660611
660612
660612
660612
660612
660614
660614
660614
660614
660617
660617
660617
660617
660620
660620
660623
660623
660625
660625
660627
6o0627
661017
661017
661103
4GN
0
u
0
0
n
0
0
0
0
0
0
n
0
0
w
w
GftLS
1550
0
0
0
0
0
3000
0
0
2000
0
0
0
2750
0
0
0
750
0
0
0
1800
0
0
0
1900
0
2000
0
0
0
2000
0
0
0
2000
0
0
0
1900
0
2000
0
2000
0
1400
0
600
0
2700
TYP
C
C
C
C
C
D
D
D
D.
D
D
D
n
D
C
r
LEG
1A
16
1C
2A
2B
2C
1A
IB
1C
1A
IB
2A
28
1A
IB
2A
28
1A
IB
2A
26
1A
IB
2A
2B
1A
IB
1A
IB
1C
ID
1A
IB
. 2A
2B
1A
IB
1C
10
1A
IB
1A
IB
1A
IB
1A
IB
1A
19
14
UTM
BT320020
BT390020
BT440000
BS32097Q
• BS39097Q
BS440985
3T1302>0
BT113250
RT130280
AT850030
AT950030
AS850970
AS95097Q
YB980930
ZB090980
YB980900
ZB090900
3T250030
BT290030
BS250980
8S290930
BT255240
BT231225
BT242206
BT263224
3T235216
BT259232
YC985095
YC985055
ZC025095
ZC025055
ZC002100
YC9850S5
ZC003058
YC990060
YC985095
YC985055
ZC025055
ZC025O95
BT263235
BT235217
YD220427
YD253444
ZC008095
YC993070
BT266225
BT242208
BT270010
3S370000
BT240208
�UNCLASSIFIED
MISSIONS STARTING
OAT~
661103
661103
661103
661103
661103
661111
661111
661111
661111
670223
670223
670228
670228
670301
670301
670301
670301
670312
670312
670312
670312
670312
670312
670315
670315
670315
670315
670512
670512
670512
670512
670616
670616
670616
670616
670619
670619
670817
670817
670826
670826
670830
670B30
670831
670831
670331
670831
670901
670901
670901
AGN
H
0
0
0
0
B
3
0
0
0
B
3
P
B
B
B
IN
GALS
0
0
0
0
0
2700
0
0
0
2700
0
2400
0
2700
0
0
0
1800
0
0
0
900
0
300
0
0
0
2790
0
0
0
1655
0
0
0
2000
0
1550
0
2450
0
225D
0
2770
0
2770
.0
1700
0
0
OUftNG
TIN
TYP
P R D V NO.
LEG
IR
2A
2B
3A
3B
1A
D
18
2A
26
C
1A
C
C
C
C
C
C
^
C
C
C
C
C
C
C
C
IB
1A
13
1A
IB
2A
28
LA
IS
2A
28
IA
18
1A
16
2A
26
1A
16
2A
26
1A
IB
1C
10
16
IB
IA
18
1A
IB
1A
IB
IA
16
1A
IB
1A
IB
1C
UTH
BT265227
BT157142
BT208180
BTI7412Q
BT224160
BT170125
BT220165
BT165135
3T215173
BS430990
BS320990
BT060230
BT150280
BT060240
BT150290
8 T 06 0290
BT150290
BT060257
BTO60290
8TO6O24Q
BT124273
BT060257
BT06Q290
AT872O18
AS905970
AT9100Q9
AS930983
BT06029Q
8T 1 30290
BT060240
3T15Q290
AS94098Q
AT870020
AS910960
AT920020
BT 06 0240
BT150290
3T390000
BT2S0095
BT I 4007 2
3T300066
AT887247
AT985O67
AT800190
AT9612&6
BT14006B
3T230068
AT81S265
AT873217
AT925246
=
�M I S S I O N S STARTING IN
HATF
670921
670921
670922
670922
670922
670922
670923
670923
670924
670924
670927
670927
670928
670928
670930
670930
671001
671001
671001
680727
680727
630823
6S0823
680823
660823
680831
680831
680908
680908
680910
680910
630911
630911
630911
680912
680912
680912
630912
630912
680912
680914
680914
630915
680915
680915
680915
630915
680915
680917
630917
AGN
3
13
a
8
3
B
B
at
0
0
B
0
0
0
o
0
0
0
0
QUANG TIN
GALS
1600
0
2000
0
0
0
3000
0
3000
0
2800
0
3000
0
2000
0
2000
0
0
2200
0
2900
0
0
0
5000
0
3000
0
5400
0
5800
0
0
1300,
0
0
0
0
0
3000
0
3000
0
0
6000
0
0 .
3000
0
TYP
c
c
c
c
c
c
c
c
0
D
c
D
D
D
n
D
D
n
n
PRQV NO.
LEG
1A
IB
1A
IB
2A
2B
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
18
1A
IB
1C
1A
IB
1C
2A
2B
2C
1A
IB
1A
18
1C
1A
IB
1C
1A
IB
UTM
BT307006
3T265133
3T21S040
BT285115
BS235990
BS184995
BS184995
BS03d990
AS800697
4T870093
BS225993
BT048015
3T240050
BT290100
BS052952
3T141014
AT945110
8T021031
AT943075
BT264081
BT120081
ZC055J90
ZC080086
ZC185130
ZC210130
BT200212
BT050212
ZC060083
ZC080083
BT260077
BT128077
ZC205152
AT807196
AT910243
AT880231
AT901205
AT901179
AT919156
AT919156
A T9 19 140
AT940070
4T834184
ZC060081
ZCOB203!
ZC180123
BT263067
CT140067
3T120062
BT180043
BT260028
�OATS
680V 17
680917
680918
630918
680918
680919
630919
630919
680920
680920
680920
680921
630921
681003
631003
681003
681003
681003
681003
681003
631003
681003
681003
681003
631004
681004
681006
631006
631006
631006
681010
681010
631010
681010
681010
631010
681102
681102
631102
631102
681102
631103
631103
681103
681103
681116
681116
681116
6iil 118
631115
A GN
0
0
GALS
- 0
0
3000
0
0
3550
TYP
D
r>
Q
W
o
W
W
W
W
W
0
0
0
0
0
3200
0
• 0
3000
0
3000
0
0
0
0
3000
o
0
0
0
0
3650
0
3000
0
0
0
5000
0
0
0
0
0
3000
0
0
0
0
3000
0
0
0
3000
0
0
4000
0
r
c
n
c
0
D
0
n
D
c
c
LEG
2A
2B
1A
IB
1C
1A
IB
1C
1A
13
1C
1A
IB
16
IB
2A
2B
2C
1A
lt>
1C
2A
28
2C
1A
IB
1A
18
2A
28
IA
IB
1C
2A
2B
2C
1A
IB
2A
26
2C
1A
IB
2A
28
IA
IB
1C
1A
IB
UTM
BT300006
BT390006
ZC215144
41312166
A T9 I 6231
ZC210148
AT810190
AT913235
ZC1981S.7
AT801203
AT906252
AT891243
AT95912Q
BS160899
BS112922
BSO98949
BS060S44
BS022979
AT881233
AT903206
BS9Q3179
AT929157
AT929140
AT944U1
BT260061
BT132061
BT174O59
BT260045
BT30O023
RT390023
AT883.225
AT868188
AT868159
AT886140
AT886122
AT90S10Q
AT890242
AT915210
AT93316Q
AT933145
AT953123
3T1940J2
!iT 260021
BT310009
BT390010
ZC209149
AT810192
AT911239
BT175061
BT2 60046
�MISSIONS STARTING IN
DATF
681118
681118
690301
6903Jl
690301
690301
690301
690301
690404
690404
690404
690404
690411
690411
690411
690411
690411
690412
690412
690412
690412
690501
690501
690501
690501
690501
690501
690502
690502
690502
690502
690503
690503
690503
690503
690503
690503
690504
690504
690504
690504
690504
690504
690504
69050^
690506
690506
690506
690506
690506
AGN
GALS
0
0
3000
0
0
0
0
0
3000
0
0
0
2000
0
0
0
0
3000
0
0
0
3000
0
0
3000
0
0
3000
0
0
0
2000
0
0
0
0
0
2000
0
0
0
0
0
0
2000
0
0
0
0
0
qUANG TIN
TYP
PROV NO. =
LEG
2A
26
IA
18
1C
2A
2B
2C
1A
IB
2A
26
1A
IB
1C
2A
2B
1A
IB
2A
2B
1A
18
1C
1A
IB
1C
1A
IB
2A
26
1A
IB
1C
2A
2S
2C
1A
18
1C
ID
IE
IF
IG
1A
13
1C
10
IE
IP
UTH
BT300026
BT390026
AT885236
AT908210
AT908181
AT925161
AT944117
AT925141
YC809036
YC869031
YC889065
YC906129
YC8 10045
YC864040
YC881068
YC898132
YC898186
YC 8 10041
YC868034
YC867066
YC904132
ZB142836
AS854836
AS864859
YB938823
YB932944
YC952005
AT812199
AT874U1
AT926060
AT942053
AT876035
AT902969
AT876U35
AT8730A8
AT849072
ATS09142
AS788960
ZB170931
ZB156931
ZB129918
ZP110918
ZBO9»9OO
Z 6070900
AT383040
AS910972
4T883040
AT8&0051
AT842O90
ATS10143
UNCLiSSlFIIi;
�PATE
690604
690604
690610
690610
690610
690610
690612
690612
690612
6<S0612
690612
690612
690613
690613
690613
690613
690614
690614
690614
690614
690614
690614
690629
690629
690703
69J703
690703
690703
690703
690709
690709
690709
690709
690705
690709
5907 10
6^0710
690710
690710
690714
690714
690714
690714
690714
690720
690720
'690725
690725
690725
690801
ASM
3
0
f)
0
GALS
3000
0
3000
0
0
0
1200
0
4000
TYP
C
r
r
r
0
8
8
0
3
8
0
0
0
0
4000
0
4000
0
5000
0
0
0
0
0
5000
0
2100
0
0
0
0
3000
0
0
0
0
0
6000
0
0
0
B
0
n
U
6000
0
0
0
0
5000
0
1500
0
0
3000
c
c
D
C
C
n
r
c
n
D
p
LEG
IA
IB
1A
IB
2A
2B
1A
IB
IA
IB
1C
10
IA
IB
1A
IB
1A
IB
1C
2A
28
2C
IA
IB
IA
IB
1C
10
IE
1A
IB
2A
2B
3A
3B
1A
13
2A
2B
1A
IB
2A
2B
2C
1A
13
1A
IB
1C
IA
UTM
BT157247
AT970247
AT943050
AT925058
AT872108
AT81119S
ZC15O223
ZC213160
ZC150223
ZC213160
ZC151223
ZC058264
BS270980
BS070930
4T99022Q
BT034217
AT881038
AS905970
AT878035
AT873O48
ATC30093
AT801140
AT976235
3T166233
9T160212
BT126212
BT103202
BT030202
AT970223
AT879036
AS90497Q
AT879036
AT87204-9
AT844080
AT806141
AT945046
AT923054
AT8711Q6
AT818196
BT179215
BT125218
BT100210
9T031208
AT970230
ZC058293
ZC026169
ZC150223
ZC135238
ZC055263
Z321E840
�UNCLASSIFIED
MISSIONS
DATE
690301
690801
690801
690801
690802
690802
690802
690802
690802
690803
690S03
690804
690804
690804
690804
690809
690809
690809
690812
690812
690812
690812
690812
693814
690814
690815
690S15
690315
690815
690815
690815
690903
690903
690903
690921
690921
690921
690921
69J921
690921
690521
690921
690921
690921
69J921
690921
690921
690921
690921
690921
STARTING
AGN
0
H
T
W
B
0
0
0
H
B
B
B
B
IN
GALS
0
0
0
0
2000
0
0
0
0
2000
0
5000
0
0
0
3000
0
0
5000
0
2300
0
0
2000
0
3000
0
0
0
0
0
4600
0
0
38
0
0
0
150
0
0
0
0
225
0
0
'0
.
187
0
0
QUANC-
TYP
n
0
c
r
0
D
D
r
p
c
c
c
c
PROV NO.
TIN
LEG
IB
1C
2\
28
1A
IB
1C
2A
2B
1A
IB
1A
IB
1C
10
1A
IB
1C
1A
IB
1A
IB
1C
1A
IB
1A
IB
2A
28
3A
3B
1A
13
1C
IA
16
1C
ID
1A
IB
1C
ID
IE
IA
IB
1C
ID
It
IB
1C
UTM
ZB218867
AS799903
AS876903
AS903938
ZB070902
Z8090902
ZS155933
ZB180933
AS767961
ZC061293
ZC020160
AT947U7
AT936O63
AS982S68
B 50209-59
SS200927
BS252936
BT322005
AT980227
BT180227
SS201926
BS254935
BT3260.03
ZC 062293
ZC030169
AS795965
AS844998
AS352934
AS88O9H3
AS903967
AS933.967
BS204923
BS263933
BS31O980
BT084226
8TO84224
BTO96225
. 3TCVS6223
BT084205
BTO65203
6T085206
3T087200
BT052200
BT057233
S TO 5 7241
3T110232
BT110230
3T008213
3TOOS220
BT035213
=
�tmF
690921
691020
691020
691020
691027
69102?
691027
691027
700114
700114
700114
700123
700123
700123
700123
700123
700123
700123
700123
700123
700123
700123
700123
700128
700128
700128
700123
700123
700128
700201
700201
700201
700201
7J0201
700201
700201
700201
700201
700201
700201
700201
700201
700201
700201
700201
70J201
700201
700201
700202
700202
AGN
3
0
6
0
0
GALS
0
37CO
0
0
160
0
0
0
3000
0
0
360
0
0
0
110
0
0
TYP
C
IB
P
0
215
0
0
0
3000
C
P
P
F
D
0
0
0
0
0
0
0
110
0
0
0
0
0
110
0
0
0
P
P
J
W
W
0
0
110
0
0
0
-.0
0
220
0
1C
1A
IB
1C
0
0
LEG
ID
1ft
P
P
ID
1A
IB
1C
1A
IB
1C
ID
1A
IB
1C
ID
1A
IB
1C
ID
1ft
IB
1C
ID
IE
IF
1A
16
1C
ID
IE
IF
1A
IB
1C
ID
IE
IF
1G
1
1A
16
1C
ID
IE
1A
IB
UTM
BT0352Q7
AT992154
ATS88109
BT015083
AT988248
4T992248
AT992252
AT988252
AS934966
AS975975
PS052952
BT047245
BT05824-5
3T058256
BT047256
AT990254
AT995254
AT995250
AT990246
BT170079
BT171077
BT173075
3T175077
ZC055294
ZC061256
ZC029227
ZC033207
ZC023165
ZC027153
BT431081
3T438078
ST439075
BT437073
3T434073
BT433077
3T413022
BT412035
BT402042
3T425061
BT434055
BT426047
BT443037
BT449036
RT453035
BT456043
BT451045
BT448038
3T047245
8T058245
�MISSIONS STARTING IN
!G IN
QUA KG TIN
PROV NO. =
B***********
AGN
700202
700202
700204
700204
700204
700204
700204
700204
700204
700218
700218
700218
700218
700213
700218
700218
700218
700220
700220
700220
700225
700225
700225
700225
700225
700324
700324
700324
700324
700324
700331
700331
700331
700331
700331
70Q331
700331
70040C
700408
700408
700408
700408
700408
70040?
700408
700408
700408
700416
700416
700416
GALS
0
0
440
0
0
0
0
0
0
3000
TYP
P
C
0
0
0
0
0
0
0
1000
P
0
0
2700
0
0
0
0
310
0
0
0
0
440
0
0
0
0
0
0
140
0
0
0
0
180
0
0
0
0
770
0
0
D
P
C
C
C
C
LEG
1C
10
1A
13
1C
10
IE
IF
1G
IA
IB
1C
10
IE
2A
28
2C
IA
18
1C
1A
18
1C
ID
IE
1A
18
1C
10
IE
IA
IB
1C
ID
1E
1F
1G
IA
IB
1C
ID
lr:
1A
13
1C
ID
IE
IA
IB
1C
UTM
BT047256
BT058250
BT 5 3 8020
BT542022
3T548Q18
BT556003
3T551006
8T548006
BT541014
AT951125
AT948104
AT966091
AT985100
8T015073
BT 12 702 3
BS174995
8S205966
BS200926
65260^37
BS301977
ZC057293
ZC058272
ZC027228
ZC 03 1209
ZC020165
AT988246
AT990252
AT993252
AT991249
AT988248
BT160030
BT180130
BT180040
BT170040
BT170050
&T160050
8T160030
BT22C090
BT230090
BT230095
BT220095
BT220090
BT265075
6T270075
BT270085
BT265Jfc5
3T265Q75
BT110257
BT110267
3T121272
�DATE
70041t>
700416
700416
700416
700416
700416
700416
700416
700416
700416
700416
700416
700416
700416
700416
700416
700427
700427
700427
700427
700427
700429
700429
700429
700429
700429
700429
700429
700429
700429
700429
700429
700429
700429
700429
700429
700429
700615
700615
700615
700615
700615
700615
700615
700615
700705
700705
700705
700705
701005
V3N
0
0
3
3
B
B
B
W
X
B
GALS
0
0
0
350
0
0
0
0
0
365
0
0
0
0
0
0
300
-o
0
0
0
150
0
0
0
0
0
2906
0
0
0
150
0
0
Q
0
0
220
0
0
0
330
0
0
0
333
'0
0
0
20
TYP
c
C
LEG
1C
IE
IF
1A
IB
1C
ID
IE
IF
1A
IB
1C
ID
IF
c
p
c
p
p
p
p
f
IF
1G
1A
IB
1C
10
IE
1A
IB
1C
ID
IE
IF
1A
IB
1C
ID
1A
IB
1C
10
IE
IF
IA
IB
1C
ID
IA
IB
1C
ID
IA
IB
1C
ID
U
UTM
BT131272
BT131257
3T110257
ST080257
BT080268
8T090268
3T090264
BT1G0264
BT100257
BT090278
BT110287
BTU0272
BT101272
BT101208
BT090288
BT090278
BT080237
BT090236
BT108233
BTH0230
8T080235
AT988252
AT990250
BT988248
AT985249
BT02003Q
AT945108
AT945125
AT975132
BT016U5
BT020100
AT988252
ATS9025O
8T988248
AT9852-+9
8T0200SO
AT945108
BTOfc0250
BT060255
BT045255
BT045250
BT060250
BT060255
8T045255
3 T 04 5 250
BT170Q74
BT178031
BT178075
RT170031
Ar9311.02
•
«
�M I S S I O N S S T A R T I N G IN
DJTt
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
701006
AGN
B
B
fl
B
B
3
8
R
Q'JANG T I N
****<-* *
GALS
TYP
LEG
IB
0
0
1C
ID
0
0
IE
0
IF
1G
0
15
C
1A
0
ie
0
1C
0
ID
0
IE
0
IF
0
1G
1A
7
C
0
IB
0
1C
0
ID
26
C
1A
0
IB
0
1C
0
ID
0
IE
IF
0
0
1G
' 0
1H
20
C
1A
0
IB
0
1C
0
ID
0
IE
0
IF
22
C
li
0
IB
0
1C
0
ID
0
IE
22
C
1A
0
IB
0
1C
0
ID
" 0
IE
13
C
1A
0
IB
0
1C
0
ID
0
IE
0
IF
60
C
IA
0
IB
0
1C
UTM
AT934104
AT93310B
AT935110
AT938109
AT9401O2
AT9311Q1
BT045103
3T042107
BT044110
BT042H3
BT039113
BT04010<>
BT0391Q5
BS040974
BS046978
BS048977
BS042973
BS080969
BS082966
8S086957
8S092955
BS091950
BS085955
BS082962
BS075967
8S136918
33148917
BS150915
8S146913
BS142915
6S135915
BS104930
BS110930
BS113924
3S110920
BS106922
BS080923
9S085925
BS094922
PSOS5920
BS082918
6T039106
BT044102
BT041100
BT040097
BT037097
BT039102
4T936UO
ATC36104
AT942113
j
�M I S S I O N S S T A R T I N G IN
OATe
701006
701006
701006
701006
701006
70100&
701006
701006
701006
7H100&
701009
701009
701010
701014
701014
701014
701014
701014
701014
701014
701014
701014
701014
701014
701014
'iGH
8
GALS
0
0
0
0
13
0
0
0
8UAN6 T I N
TYP
C
0
0
H
3
5
8
3
100
0
48
78
0
0
0
0
0
0
30
0
0
70
0
C
P
C
C
C
P R Q V NO.
LEG
10
IE
IF
1G
1A
18
:
1C
10
IE
IF
1A
18
1A
IA
18
1C
10
IE
IF
1G
1A
IB
1C
1A
18
UTM
AT947114
AT947104
AT945099
AT940102
AT934110
AT933US
AT93512Q
AT934120
AT930115
AT933108
AS950960
AS960950
BT420O47
ZC182206
ZC188204
ZC191201
ZC186194
ZC191201
ZC 192205
ZC 182209
ZC200210
ZC205210
ZC21Q203
2C200H88
ZC210188
ijr-4C.LAS5
=
�IREC= 17565
!REC= 17565
NPPOV =
"JPHQV=
146
146
NZR£C=
NZR£C=
429
429
UNCLASSIFISO
�M I S S I O N S STARTING
:>4TF
660212
660212
660212
660212
660212
660212
660212
660212
660217
660217
660217
660217
660226
660226
660226
660226
660226
660226
660226
660226
660227
660227
660227
660227
660227
660227
660227
660227
660227
660227
660227
6 60 2 2 7
660227
660227
660820
660820
660820
660820
660820
660820
660823
660823
663826
660826
660826
660826
660826
660907
660907
660907
4GN
0
0
0
0
0
0
0
0
PROV NO.
NGAI
GALS
TYP
2000
C
0
0
0
0
0
0
0
2600
C
0
0
0
3000
C
0
0
0
0
0
0
0
2850
C
0
0
0
0
0
0 '- • - ::0
0
0
0
0
0
0
2000
C
0
0
0
0
0
800
C
0
1350
C
0
0
0
-. 0
2400
C
0
0
LiG
1A
IB
1C
10
2A
2B
2C
20
IA
16
2A
2B
1A
18
2A
2B
3A
3.B
4A
4B
1A
IB
2A
2B
2C
3A
38
4A
4B
4C
40
5 A.
5B
5C
1A
IB
1C
2A
2B
2C
1A
16
1A
IB
2H
28
2C
IA
IP
2A
UTM
BS470735
BS480734
BS462707
3S492711
BS522718
BS5357G5
BS51269U
BS528690
85170835
BS23083Q
BS24.0625
BS275635
BS480455
BS5Q5437
BS5 18420
BS549399
8S640365
BS6S3386
BS641430
BS628458
BS497454
3S482440
BS 53 342 7
BS54042?
3S546406
3S645440
BS635460
85440470
BS43845.0
BS425445
BS4E3.4TO
BS2O5437
BS2 29455
8S23143O
BS48Q445
BS504437
BS55Q398
BS635365
BS655380
BS628460
BS49O455
BS570390
35483703
BS465740
BS510690
BS520730
BS5256E5
BS 54 043 5
3S553395
BS644443
\
�M I S S I O N ? ST*» TIN'S IN!
QUANG NGAI
* Jh** * # 5: * • # $
.
* * .
DATST
660907
660907
660907
661012
661012
661012
661012
661012
661012
661015
661015
670304
670304
670304
670304
670313
670313
670313
670313
6,70313
670313
670314
670314
670315
670315
670315
670315
670500
670508
670516
670516
670516
670516
670609
670609
670609
6706U9
670609
670609
670609
670609
670618
AGN
W
W
VI
0
3
r>
3
a
5
0
3
B
D
6 706 1 3
670618
670618
67J619
670619
670619
670619
670719
0
0
ri
0
GALS
0
0
0
2600
0
600
0
0
0
1800
0
1500
0
0
0
1800
0
900
0
0
0
1200
0
900
0
0
0
2300
0
2250
0
0
0
2415
0
0
0
1600
0
0
0
500
0
500
0
1800
0
890
0
3000
TYP
f
C
r
C
C
c•
C
C
C
r
c
LEG
26
34
3B
1A
18
1A
IB
2A
2B
1A
IB
1A
18
2A
23
IA
IB
1A
IB
2A
26
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
2A
2B
IA
IB
2A
c
c
c
r
r
r
2B
1A
IB
2A
28
IA
IB
1A
IB
1A
16
1A
16
IA
UTM
BS627463
BS635365
BS655400
BS250630
BS200840
3S213455
BS220457
BS239430
3S231427
BS425460
BS220440
BS460450
BS5 00440
BS520430
BS550400
BS460455
SS548404
BS480455
BS548404
3S640432
BS604520
BS490700
BS460750
BS598477
BS603523
BS640369
3S653493
BS49O690
3S460770
B 5 34 0 6
40
BS24O640
B5340600
BS280640
3S340450
BS320600
BS240630
853.10670
B5500460
85510440
BS520420
B555Q400
BS450740
BS48076O
B 5 53 068 0
BS520720
BS310840
BS220870
BS220310
BS190S70
BS64O430
�D.4TC
670719
670724
670724
670727
670727
670727
670309
6 70 80S>
67080?
670809
670810
670810
670610
670910
670811
670811
670311
670811
670811
670315
670815
670815
670818
670818
670821
670821
670821
670822
670822
670822
670822
670823
670623
670823
670823
670823
670823
670823
670824
670824
670826
670826
670827
670827
670827
670827
670905
670905
670905
670905
A SN
0
Q
B
GALS
0
2000
0
1700
0
0
1690
0
0
Q
B
8
B
B
3
B
B
B
B
B
6
8
B
W
n
2800
0
0
0
2600
0
0
3000
0
2400
0
0
550
0
2000
0
0
2200
0
0
0
2000
0
2000
Q
0
0
0
2750
0
3000
0
3000
0
2QOO
0
1650
0
750
0
TYP
L =G
18
C
C
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
r
1A
IB
1A
IB
1C
1A
IB
2A
23
IA
IB
2A
28
1A
IB
1C
14
IB
1A
IB
1C
1A
IB
1A
IB
1C
1A
IB
1C
ID
1A
IB
1A
IB
1C
ID
IE
1A
IB
1A
IB
1A
IB
IA
IB
IA
IB
1A
IB
UTM
BS600520
BS640430
BS610530
BS485695
BS46075Q
3S480770
BS564153
BS56B263
XS9S3755
YS002749
BS50246O
8S544400
8S513450
BS563390
8S190080
3S260625
BS315670
BS285467
BS280630
8 S 50 1381
8S569388
BS529447
B5595485
8S617566
BS190730
BS260620
BS310&8Q
BS380550
BS390680
BS360550
BS365610
BS252656
BS350510
BS590470
8S610565
BS626455
BS602502
BS620530
BS243657
BS342515
BS237656
BS344500
3S230660
3S350492
BS203666
BS322515
BS793248
BS760290
BS79824S
BS760390
,
�MISSIONS
D4TP
670906
670906
670923
670923
670925
670925
670925
670925
670926
670926
670926
670926
670926
670928
670928
67092*?
670929
670930
670930
670930
670930
680403
680403
680620
680620
630630
680630
680630
630713
680713
680714
630714
680719
680719
680720
680720630722
680722
680726
6S0726
680802
630802
680814
630814
680816
630816
680823
680823
6d0827
680827
STiRTING
4GN
0
8
B
B
B
6
P,
B
0
n
a
0
0
0
0
o
n
0
0
0
n
3
IN
GALS
1750
0
3000
0
3000
0
0
0
2600
0
1700
0
0
2950
0
2000
0
2000
0
0
0
3000
0
2000
0
2900
0
0
1500
0
3000
0
2000
0
1000
0
1800
0
3000
0
3000
0
1800
0
3000
0
3000
0
6000
0
PROV NO. =
QUANG NGAI
T¥P
r
c
c
LEG
14
IB
1A
IB
IA
IB
2A
c
c
c
c
c
D
C
c
2B
IA
IB
1A
16
1C
1A
IB
1A
IB
IA
IB
2A
28
1A
18
1A
IB
IA
IB
1C
D
1A
0
1A
IB
IA
IB
IA
IB
1A
IB
1A
16
1A
IB
r
0
D
D
P
ie
C
1A
r
P
16
1A
16
1A
IB
e
1A
IB
UTM
BS761320
BS735353
BS320600
5S373363
BS47G375
8S565392
BS55042Q
BS613466
BSU079Q
BS251682
65620567
BS596472
BS627558
BS312601
BS343428
BS3.45530
8S371363
BS230t>50
9 S 29 5 62 5
8S241599
BS304663
BS700430
BS 82 0290
A S9 93 73 9
AS889-900
AS993T93
AS923855
AS89090?
BS489650
BS473735
85 150910
BS04't<i54
AS8887OO
AS835880
BS486650
BS472735
BS485650
BS469735
AS8907OO
4S890370
AS983787
AS886900
AS987784
AS8849OO
AS999971
AS891920
AS 88 5 702
AS888880
BS353475
8S353547
UMCl.iSS I
�MISSIONS STARTING IN
DATF
«GN
6<?0627
680828
680828
630831
630831
680831
630831
681006
681006
631009
681009
690125
690125
o90125
690125
690125
690127
690127
690127
690127
690127
690127
690127
690201
690201
690201
690201
690201
690217
690217
690217
6^0217
690217
690217
690217
690217
690217
690217
690217
690317
690317
690317
690317
690317
690317
690317
690317
69031 /
690317
690317
0
0
W
W
B
B
3
B
3
GALS
0
3000
0
3000
0
0
0
2000
0
3000
0
165
0
0
0
0
165
0
0
0
0
0
0
55
0
0
0
0
110
0
0
0
0
0
TYP
liQ
P
D
D
3
o
0
0
0
1A
IB
1A
IB
2b
D
1A
D
1A
IB
IB
P
1A
IB
1C
ID
IE
P
1A
IB
1C
ID
IE
IF
1G
P
1A
IB
1C
ID
It
F
1A
IB
1C
ID
IE
IF
1A
IB
1C
ID
IE
0
110
0
0
0
0
0
110
LFG
1C
2A
0
0
0
B
PROV NO. =
QUANG NGAI
'P
1A
IB
1C
ID
IE
IF
P
1A
IB
1C
10
IE
UTM
BS305630
AS884704
AS883878
BS375430
BS356483
BS385486
8S358413
BS842270
B 572 840 8
3S815246
BS699384
BS749438
BS749415
BS740415
5S760415
BS749438
BS809398
BS809374
BS828374
SS820390
3S814390
BS814393
BS809298
8S865339
BS880339
3S880315
BS864315
BS865339
BS 80939 8
BS829374
BS828390
3S814390
BS814398
8S809298
BS927222
BS927219
BS931219
3S931222
BS927222
BS749438
6S749415
BS740415
BS76O41S
BS760433
BS749438
BS8b5539
8S38O339
BS880315
BS864315
BS865339
5
�IONS STATING IN
V I S5
O&TE
690317
690317
690317
690317
690317
690326
690326
690329
6'*032S
690401
69040 1
690416
690416
690421
690421
690421
690421
690422
A90422
690423
690423
690423
690427
690427
690427
690427
690427
690427
690430
690430
690430
690430
690430
690430
690430
690430
690430
690430
690430
690430
693430
690502
690502
690502
690506
690506
690506
690511
690511
690 "5 11
4GN
8
W
GALS
110
0
0
0
0
3000
QUANG NGAI
************
TYP
P
r
0
W
3000
0
0
3000
D
B
0
350
0
C
0
3000
o
0
0
0
2000
P
0
0
0
0
0
3000
0
0
495
0
0
0
0
0
50O
0
0
0
0
0
3000
C
3000
2700
1A
IB
1A
18
1A
IB
2A
2B
IA
IB
1A
IB
1A
IB
1C
F
D
0
0
0
W
ID
IE
IA
IB
1A
1C
E
0
0
0
0
IA
IB
1C
IB
*
W
LtG
0
0
0
0
2000
D
C
0
0
110
0
0
W
ID
IE
IF
1A
IB
1C
ID
IE
IF
1A
IB
2A
2B
1A
IB
1C
1A
IB
1C
1ft
IB
1C
1A
IB
1C
imi
BS927222
BS927219
BS931219
SS931222
BS927222
BS806239
BS687381
BS83D260
BS71Q400
HS836265
8S733390
8S70Q344
3S714330
AS9846SO
AS980755
AS95t>ai3
AS399855
BS 33 744 2
BS321610
3&401207
BS439223
BS53O246
SS914239
8S917239
BS914246
3S916256
BS912259
3S901259
BS914239
8S917239
359142*6
8S916256
BS91225S
BS901259
AS9S4696
AS984755
AS961816
AS901858
AS971702
8S'>49627
BS037563
BS659300
BS680273
BS760259
BS64-5300
BS674267
BS760251
BS927222
BS927219
BS931219
�fissions
STARTING IN
QUANG NGAI
X
OATF
690511
690511
690511
690511
690511
690528
690528
690528
69352S
690526
690528
690528
690528
690528
690528
690528
69052H
690528
69052G
69052?
690523
690528
690528
690529
690529
690529
690529
690529
690530
693530
690530
690530
690530
690530
690530
690603
69060 3
690603
690603
690603
690607
690607
690607
690607
690607
690607
690606
69060P
690608
690608
l^Gf4
GALS
*i &**!£ ****.*
TYP
0
0
e
220
0
0
0
no
W
v<
0
0
0
0
B
0
0
0
0
0
440
0
0
0
0
0
220
0
0
0
0
0
3000
0
0
0
0
33
0
0
0
0
0
0
3000
0
0
Vt
W
D
F
P
0
W
0
2000
0"
0
0
r
0
0
2000
0
2000
0
IF
1A
IB
1C
ID
IE
IF
1A
IB
2A
28
2C
1A
IB
1C
ID
IE
IF
1G
1A
IB
1C
10
IE
1A
IB
1C
1O
IE
0
0
LEG
ID
1A
IB
1C
ID
It
IB
1C
ID
It
IF
1A
IB
1C
ID
IE
IF
c
c
1A
IB
1A
16
UTM
BS931222
BS865339
BS880339
BS880315
BS364315
BS809393
BS809374
BS828374
BS828390
BS814390
BS814398
BS809396
BS809374
BS828374
BS828390
BK814390
BS814398
BS 74 943 8
BS749415
BS740415
SS760415
BS760438
BS749438
BS16049O
BS190420
BS16049Q
BS15051Q
BS100570
BS914239
BS917239
BS914246
3S916246
BS916256
3S912259
BS901259
BS636300
BS6843OQ
8S746307
BS673332
BS672400
3S520376
BS&OO376
BS5 5*430
5S5614G1
3S572394
3S600384
BS48068S
BS550683
RS6*>2330
8S652400
�UNCLASSIFIED
MISSIONS STARTING IN
IG
OUAMG MGAI
PROV NO.
&
OATF
6S0608
690608
690608
6S0610
690610
690610
690610
690610
690610
690610
690614
690614
690614
690615
690615
690615
690615
690615
690615
690616
690616
690616
690616
690616
690616
690617
690617
690617
690617
690619
690619
690619
690620
690620
690625
690625
690625
690625
690625
690628
690628
690628
690629
690629
69062<r
6907J1
690701
690702
69070?
690702
GALS
TYP
0
0
0
2000
C
0
0
0
0
0
3000
0
0
4000
0
0
3000
C
r>
p
0
0
0
0
0
3000
D
0
0
0
0
0
0
2500
c
0
0
3000
C
0
0
3000
D
0
0
0
3000
C
0
0
4000
C
0
0
0
0
4000
C
0
0
4000
C
0
0
4000
', 0
4000
0
0
c
c
LEG
1C
ID
IE
1A
IB
1C
10
IE
1A
IB
1A
IB
1C
1A
IB
1C
2A
2B
2C
1A
18
1C
2A
2B
2C
1A
18
1A
IB
1A
IB
1C
1A
IB
1A
IB
1C
ID
IE
1A
IB
1C
1A
IB
1C
1A
IB
1A
IB
1C
UTM
BS626319
BS670319
BS738329
RS628317
BS670317
BS738326
BS646330
BS646400
BS331443
BS312630
BS360472
SS3C8456
BS512432
BS300810
SS240800
BS221789
BS300810
5S383810
BS414796
3S30O800
BS242790
BS226780
BS3008GQ
BS373800
BS410780
BS420691
BS55069X
BS313432
BS30O658
BS651300
9S675269
BS760254
BS42O638
3S550638
8S739324
BS673315
BS628315
BS655330
BS655400
35550697
3S500695
BS420684
BS550697
•BS500695
BS420684
BS420700
BS550700
3S490680
3S433710
BS455770
�UNCLASSIFIED
MISSIONS
DATF
690703
690703
690703
690703
690703
690704
690704
690705
690705
690705
690705
690705
690707
690707
690708
690708
690708
690709
690709
690709
690714
690714
690714
690716
690716
690716
690716
690720
690720
690720
690720
690720
690720
690723
690723
690723
690723
690725
690725
690725
690727
690727
690727
690727
690731
690731
690731
690802
690802
690802
STARTING
4GN
0
0
0
0
0
0
0
0
0
. 0
0
0
0
n
IN
GALS
3000
0
0
0
0
3000
0
3000
0
0
0
0
4500
0
2000
0
0
3000
0
0
4000
0
0
2255
0
0
0
220
0
0
0
0
0
220
0
0
0
2000
0
0
2500
0
0
0
3000
0
'0
,
3000
0
0
PRCV NO,
NGAI
TYP
C
f
r
c
c
p
p
F
P
P
D
P
p
n
LEG
1A
IB
1C
ID
IE
1A
IB
1A
18
1C
2A
2B
1A
IB
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
ID
1A
IB
1C
ID
IE
IF
UTM
BS6323O8
BS674338
3S744318
BS64433Q
3S644400
BS477680
8S436770
3S625325
BS762325
BS740330
3 S6 5 8330
BS658400
BS550713
BS447728
BS740320
BS673312
BS630313
AS 96 7 6 7
,9
3S04462Q|
8SOa35>57
BSO49837
BS18Q80&
BS229779
BS92Q207
BS919202
BS914198
BS916208
BS8iQ9398
BS8O9374
SS82S374
BS 8 8 9
230
BS81439J
BS 81 4398
1A
BS&65339
BS38Q339
BS88Q315
65964315
AS9.886BO
AS988755
AS956818
BS470545
BS452595
B 54346,20
&S430650
BS1 0 . . 2
050
BS1336O5
«S225614
IB
1C
ID
1A
IB
1C
1A
IB
1C
ID
1A
IB
1C
1A
IB
1C
AS969699
BS04662B
BS086562
�DATF:
690802
690802
690802
690S03
690803
690803
690803
690803
690804
690804
690804
690804
690805
690605
690605
690811
690811
690811
690814
690814
690814
690815
690815
690815
690815
690815
690815
690815
690615
690815
690815
690815
690815
690815
690315
690815
690815
690815
690815
690815
690815
690815
690815
690815
690819
69J819
690819
690819
690819
690319
AGN
W
*
W '
0
Q
0
B
GiLS
2000
0
0
2000
0
0
0
0
2000
0
0
0
1800
0
0
3000
0
0
3000
0
, 0
10
0
0
TYP
D
n
n
C
n
D
C
0
B
B
B
0
20
0
0
0
0
0
5
0
10
0
0
0
0
2900
0
0
C
C
C
n
0
0
0
0
1650
0
0
0
0
0
p
LEG
1A
IB
1C
1A
IB
1C
ID
IE
IA
IB
1C
ID
1A
IB
1C
1A
IB
1C
1A
IB
1C
IA
2A
3A
4A
1A
2A
3A
4A
5A
6A
IA
2A
1A
2A
3A
46
5A
1A
IB
2A
26
3A
3B
1A
ie
1C
ID
IE
IF
UTM
SS04783J
BS183750
BS194728
BS032754
BS090741
BS100734
BS120T40
3S184716
BS461544
3S442593
BS423616
BS420547
3S52041S
RS558392
BS600378
AS967697
BS045624
BS083556
3S100563
BS132605
BS225615
BS660246
BS662247
BS667247
BS663245
BS637236
3S639262
8S637267
BS634273
BS636274
3S640266
BS616274
BS619277
BS633283
3S634288
BS637281
BS641234
BS64428Q
BS198514
3S212558
BS208614
B 5 22 063 7
BS222633
BS187718
3S809398
BS809374
BS828374
9S828390
BS814390
3S814398
|
�MISSIONS START IMG IN
QUA KG NGAI
i **£> *> ******
OiTF
690625
690825
690825
690825
690825
69Q325
690903
690903
690903
690904
690S04
690904
690904
690904
690904
690916
690916
690916
690916
690916
690916
690917
690917
690924
690924
690924
690926
690926
690926
690926
690926
690926
690926
690926
690926
690926
690926
690926
690926
690926
690926
690926
690926
690926
690926
690927 .
690927
690927
690927
690927
iSGN
GALS
0
1100
0
0
0
0
0
5100
0
0
330
0
0
0
0
0
5000
0
0
0
0
0
5400
0
5000
0
0
250
0
0
0
0
0
0
250
0
0
0
0
0
250
0
0
0
B
0
0
0
0
TYF
P
IB
1C
ID
IE
IF
n
U
0
1A
16
1C
P
n
1A
IB
1C
10
IE
If
IA
IB
1C
2A
2B
2C
C
1A
IB
D
1A
IB
1C
P
1A
IB
1C
ID
IP
IF
1G
P
e
1A
IB
1C
ID
IE
IF
IA
IB
1C
ID
IE
IF
0
0
0
0
0
270
'0
,
0
0
3000
L£G
iA
P
li
D
IB
1C
ID
1A
UTM
BS749436
BS749415
BS740415
BS760415
BS760438
BS749438
BS267530
6S24D630
BS215655
BS749438
BS749415
PS740415
BS760415
3S760438
BS749438
8S26354?
3S241631
BS223666
BS257543
BS23A627
BS222652
BS358435
BS333590
BS094568
BS130612
BS 22 4620
BT53802O
BT542022
BT54SOI18
8T556008
BT551006
BT54a006
BT541014
BS569969
SS575970
BS575961
BS570958
BS564957
BS563962
BS914239
BS917239
BS914246
3S916256
SS212259
3S901259
BS927222
BS927219
BS931219
3S931222
BS403203
�UNCLASSIFIED
M I S S I O N S STARTING IN
QUAMG NGAI
1GN
TYP
DATE
690927
640927
690927
690927
690927
690927
690927
690929
690929
690929
690929
690929
690929
691007
691007
691007
691007
691007
691007
691017
691017
691017
691017
691023
691023
691023
691023
691108
691108
691108
691108
691110
691110
691110
691110
691110
691110
691114
691114
691114
691114
691114
691122
691122
691122
691122
691122
691122
691202
GALS
0
0
2000
0
0
0
0
0
250
0
0
0
0
0
440
0
0
0
0
0
3000
0
0
0
400
0
0
0
600
0
0
0
155
0
0
0
0
0
110
0
0
0
0
330
0
0
0
0
0
110
PROV
LEG
16
1C
1A
IB
1C
2A
2B
2C
1A
IB
1C
ID
IE
IF
1A
18
1C
10
IE
IF
IA
18
1C
ID
1A
IB
1C
ID
1A
IB
1C
ID
1A
IB
1C
ID
IE
IF
Id
IB
1C
ID
IE
1A
IS
1C
ID
IE
IF
IA
UTM
3S440220
8S532243
BS199514
BS214558
BS210616
BS220637
BS224689
BS195717
BS914239
8S917239
BS914246
8S916256
BS912259
BS901259
BS809398
BS809374
BS828374
BS828J90
BS814390
BS814398
AS989696
AS969755
AS965318
AS903861
BS536822
BS536830
BS543832
BS543830
SS865339
BS88O339
BSS8Q315
BS864315
BS518773
BS51178Q
8S512785
8S516786
BS52Q78«
BS520775
BS749436
8S74941"5
BS74Q415
BS760415
BS76O436
BStt09393
BS809374
BS828374
BS 82 8 390
BS814390
BS814393
6S749433
NO.
�MISS IONS STARTING IN
DtTc
691202
691202
691202
691202
691202
691208
691208
69120G
691208
691208
691208
691226
691226
691226
691226
4GN
0
0
691226
691226
691226
691226
691226
691226
691226
691226
691227
691227
691227
691227
691227
691227
691227
691227
700109
700109
700109
700109
700117
700117
700117
700117
700123
700123
700123
700128
700123
700123
700128
700128
700129
700129
700129
0
0
0
0
0
0
B
0
QU&NG MGAI
************
TYP
GALS
LEG
IB
0
0
1C
0
ID
0
IE
IF
0
r1A
220
0
IB
0
1C
0
10
0
IE
0
IF
p
U
150
' 0
IB
0
1C
0
ID
0
IF
0
IF
100
p
1A
0
IB
0
1C
0
ID
0
IE
0
IF
p
220
1A
0
IB
0
1C
0
ID
p
220
1A
0
IB
0
1C
0
ID
p
330
1A
0
1C
0
ID
0
IN
p
1A
55
0
IB
0
1C
0
ID
c
1A
470
0
16
0
1C
0
ID
c
1650
1A
0
IB
0
1C
0
ID
p
150
li
IB
0
0
1C
UTM
BS749412
8S740412
BS760415
8S760438
BS749438
BS809398
BS809374
BS82S374
BS82839O
85814390
BSS1439S
BT431081
BT43807S
BT439075
BT437073
BT434073
BT433077
BS518773
8S511730
BS512785
BS516766
BS 52 0780
BS520775
BS865339
BS880339
BS88O315
BS864315
BS927222
BS927219
BS931219
BS931222
3S760415
BS758438
BS758415
BS76043S
BS365339
3S864315
BS368315
BS869339
3S520380
' BS560520
BS560430
BS520430
BS520380
BS560520
BS560430
BS520430
3S749438
BS749413
BS751418
,
�MISS I"NS STAPTING IN
QU&NG NGAI
Tf Jj •£ *****
TYP
G4LS
LEG
0
10
P
250
IA
0
IB
0
1C
0
10
0
IE
170
C
14
0
2A
3A
0
4A
0
0
54
0
6A
0
7A
0
8A
110
C
1A
0
2A
0
3£
4A
0
4700
C
IA
0
IB
0
1C
0
2ft
0
2B
IA
2000
c
IB
0
0
2A
0
2B
P
1A
400
0
IB
0
1C
0
ID
P
100
IA
0
IB
0
1C
0
10
E
IA
200
0
IB
0
1C
0
ID
s
200
1A
0
IP
0
1C
0
10
50
F
1A
0
IB
0
1C
0
10
250
F
1A
0
IB
0
1C
3£#$*
r
OAT :
700129
&GN
700325
700325
700325
700325
700325
700329
700329
700329
700329
700329
700329
700329
700329
70033 L
700331
700331
700331
700410
700410
700410
700410
700410
700410
700410
700410
700410
700419
700419
700419
700419
700420
700420
700420
700420
700728
700728
700728
70072S
700728
700728
700728
700728
700729
700729
700729
700729
700729
700729
700729
0
;
J
0
B
B
ri
W
W
W
*
W
UTM
BS751438
8S813398
BS316392
BS825337
8S823379
BS312378
BS620263
8S625265
8S630253
BS625249
BS630268
8S635256
BS640260
BS635271
8S604250
BS617245
8S620250
BS6O6255
BS369542
3S374600
85386621
BS3Q0620
BS339540
BS 36454 3
BS3-60619
BS304620
BS345540
BS753437
BS753433
BS751435
BS754435
BS633377
35634380
BS636381
BS635378
BS666340
BS666338
BS657317
BT65431&
BS673333
BS676332
BS66831t.
BS666316
BS666372
BS670372
HS670368
BS666368
HS640390
BS650390
BS650380
|
�UNCLASSIFIED
DATE
700729
700809
700809
700611
700811
700912
700912
700912
700912
700913
700913
700913
700913
700914
700915
700915
700T15
700915
700916 700916
7C0916
700916
700917
700917
70J917
700^17
700919
700919
70091S
700919
700921
700921
700921
700921
701010
701010
701010
701015
701015
701015
701015
701015
AGN
a
%
B
B
B
B
8
B
B
B
B
B
B
W
Qt'ANG NGAI
************
TVP
LEG
GALS
ID
0
1A
3000
C
18
0
1A
C
2400
IB
0
1A
720
C
IB
0
1C
0
ID
0
1A
480
C
0
IB
1C
0
0
ID
1A
200
C
1A
480
C
18
0
1C
0
ID
0
1A
C
490
IB
0
0
1C
ID
0
1A
200
C
18
0
0
1C
0
ID
1A
240
C
IB
0
0
1C
0
ID
600
C
. 1A
IB
0
1C
0
ID
0
p
1A
77
p
1A
77
p
1A
95
1A
220
C
0
16
1C
0
2A
0
26
0
PROV NO. =
MISSIONS STARTING IN
UTM
BS640382
8S362410
8S337560
6S520430
8S600410
3S240640
3S240600
BS260600
BS260640
8S230610
BS200610
BS200640
" BS230660
BS230650
BS260640
BS280640
BS280610
BS260610
BS280610
BS32Q610
BS320580
BS280580
BS330560
BS350560
BS35O470
BS330470
BS340460
BS360460
BS360410
BS340410
BS350410
8S380410
BS380370
BS350370
3S474863
BS474863
BS538S24
BS203772
BS17575Q
BS184740
BS193756
BS200745
UNCLAS'il
�T
!MREC=
NREC=
17398
17398
\'P*OV =
MP^OV=
197
197
NZREC=
545
UMCLISSIFI.D
UNCLASSIFIED
�M I S S I O N S STARTING
06TE
AGN
IN
HUH
GALS ************
TYP
LEG
PROV NO. =
UTM
UNCIASS i
91
�NREC= 13140
NREC= 13140
I\!PROV =
NPPOV=
0
0
NZPEC=
NZR:C=
0
0
UNCLASSIFIED
!FIEO
�M I S S I O N S STiRTI?-4G IN
DATf:
AGK
DA KtNG
G A L S ************
TYP
LrG
PROV NO. = 92
UTM
UNCLASSIFIED
�NREC=
NREC=
18140
0
0
0
0
UNCLASSIFIiO
! FI-.0
�MISSION'S START ING IN
KQNTUM
************
D.iTE
650802
650802
I>GN
0
650804
0
650804
650806
650806
650815
650815
650815
650815
650318
650818
650818
650818
650917
650919
660711
660711
660721
660721
660722
0
0
0
0
0
0
0
0
660722
660727
660727
660728
660728
660820
660820
660820
66J823
660823
661015
661015
661015
661015
661123
661123
661207
661207
661209
661209
670112
670112
670112
670112
670120
670120
670121
670121
670122
0
0
0
0
w
G
w
w
w
w
w
0
GALS
1000
0
600
0
400
0
1300
0
0
0
2000
0
0
0
1SOO
850
2000
0
2000
0
1200
0
2000
0
1500
0
1000
0
0
1900
0
1800
0
0
0
1800
0
2700
0
1400
0
1800
0
0
0
1200
'0
,
900
0
1300
TYP
C
C
C
LSG
1A
IB
1ft
IB
1A
IB
C
c
c
c
c
c
c
c
c
c
c
c
c
cD
1
D
r
D
r
1A
IB
1C
JO
1A
IB
2A
2B
IA
1A
IA
IB
1A
IB
1A
IB
1A
16
1A
IB
1A
IB
1C
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1C
ID
1A
IB
1A
2A
1A
UTM
AS 89 025 5
AS94O140
AS 92 520 5
AS97O065
BS290320
BS275298
BS265290
BS251255
3S271268
BS258248
BS310340
6S27025O
BS270330
3S26028O
YB940520
Z 6065 580
AS845323
AS8T3235
8S 16 5480
3S2104O4
BS19-0330
BS2O03S5
9R130990
3R120810
AS920250
AS930130
YAS9.074Q
YA85065Q
YA790690
YA860600
YA79Q540
ZB14067O
2B17067Q
ZB15076O
ZB2O076O
YB925637
YB94066O
YB920660
YB9507ZO
YB913720
YB945728
YB912713
YB900713
YB920740
Y8944730
YB910692
YB910650
YB910700
YB910740
YB900720
�DATE
670122
670123
670123
670124
670124
670202
670202
670203
670203
670213
670218
670221
670221
670223
670223
670226
670226
670302
670302
670304
670304
670304
670304
670312
670312
670316
670316
670316
670316
670317
670317
670324
670324
670324
670327
670327
670327
670331
670331
670401
670401
670403
670403
67040?
670405
670407
670407
670408
6 7040 C
6 7040 S
AGN
n
n
0
GALS
0
1800
0
1800
0
1500
0
rj
0
(}
w
0
0
0
0
0
a
3
ft
n
0
0
o
n '
3
B
0
n
900
0
%00
0
2400
0
2700
0
1800
0
2700
0
1800
0
1800
0
2700
0
700
0
700
0
2700
0
2700
0
0
279(3
0
0
2790
0
1860
0
1800
0
1360
0
1800
'0
2790
0
1800
TYP
D
D
C
r>
c
D
D
D
r
0
c
0
D
D
D
D
D
D
D
D
o
C
LEG
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
IA
18
IA
18
1A
18
1A
IB
1C
IA
IB
1C
1A
IB
1A
18
IA
IB
1A
18
D
1A
16
IA
r
IB
1A
UTH
YB900650
YB910713
YB948625
YB91771Q
YB935623
YS913730
YB903670
Y8920725
'
YB910700
YA672542
YA730505
YB800250
YB870250
YB930620
YB95066Q
YA662700
YA642534
YA670555
YA730505
YA711860
YA660700
YB98067Q
Y9980710
|
YA640700
YA6 10540
YA660700
YA640540
YA660700
YA64Q540
YA767697
YA754520
YA76Q610
Yfc870620
YA792615
YA630700
YA60Q627
YA624560
YA903730
YA83556O
YA655700 _
YA643540
YA76&696
YA754518
YA650630
YA751503
YA75851S
YA770697
YA690540
YA64O580
Yf 760606
�MISS IONS START ING IN
D.1T =
670408
570408
670408
670408
670408
670410
670410
670411
670411
670414
670414
670415
670415
670415
670415
670416
670416
670416
670416
670416
670416
670416
670416
670416
670416
670417
670417
670425
670425
670426
670426
670501
670501
670503
670503
670503
670503
670504
670504
670504
670504
670505
670505
670505
670505
670508
670508
670510
670510
670510
AGN
GALS
0
1800
0
1860
0
2790
3
n
0
0
0
0
0
0
w
w
n
w
0
Q
0
0
n
Q
0
0
n
o
0
'
1860
0
1700
0
1860
0
1800
0
1860
0
0
0
2790
0
0
0
1860
0
1560
0
1840
0
1860
0
1860
0
1860
0
2790
0
2290
0
1860
0
4650
0
0
0
930
0
1800
0
1860
KONTUM
************
• TYP
LEG
16
D
1A
IB
n
1A
IB
p
1A
IB
1A
0
IB
D
1A
18
1A
D
D
D
D
D
D
0
D
D
n
n
D
r
r
D
D
(>
IB
1A
IB
1A
IB
2A
2B
1A
18
2A
2B
1A
IB
1A
IB
1A
18
1A
IB
IA
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
2A
28
1A
16
1A
IB
1A
UT.M
YA87367Q
YA 760606
YAG7367O
YA662693
YA650539
YA89070Q
YA830560
YA775695
YA760520
Yft770700
YA760520
YB796270
YB910270
YA840550
YA72O500
YA712689
YA620678
YA71368T
YA619670
¥A64a63O
YA685588
YAT35603
YA755497
Y A 97 0590
YAT2049O
YA6Z9S54
YA707457
YA89O700
YA85055O
YA710862
YA653717
YA710860
YA650700
YA630700
YA625550
YA67044O
Y&760520
YB752272
YB869260
YA650680
YA650520
YA73C704
YA628677
Y4711705
YA630693
YA710860
YA650720
YA650630
Y A 73 0470
YB760270
�DATE
670510
670512
670512
670513
670513
670513
670513
670513
670513
670514
670514
670514
670514
670704
670704
670716
670716
670716
670716
670716
670716
670717
670717
670720
670720
670720
670720
670720
670720
670825
670825 •
670825
670825
670825
670916
670916
671226
671226
671229
671229
671231
671231
680108
680108
630 1 1 I
680111
680113
680118
680409
630409
AGN
0
n
n
n
0
0
0
0
1
0
0
3
0
0
Q
0
G
0
0
0
GALS
0
2790
0
1730
0
0
0
1860
0
2400
0
1860
0
2790
0
2750
0
3000
0
0
0
3000
0
3925
0
0
0
2800
0
2300
0
0
0
0
2700
0
2300
0
2700
0
2900
0
2900
0
2600
0
30^00
0
2900
0
TYP
D
D
D
D
D
D
C
C
t
C
tec
18
14
IB
IA
IB
2A
28
14
IB
1A
IB
1A
18
1A
18
1A
IB
14
IB
2A
2B
1A
IB
1A
18
2A
C
2B
1A
18
iA
IB
2A
28
2C
C
1A
C
0
D
D
0
0
D
D
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
14
IB
1A
IB
UTM
YB880270I
YA660730
YA71Q850
YA730430
YA64Q550
YA710470
YA660700
YA650543
YS627557
YA7104&0
YA370&03
YA747498
YA6347OO
YA6Z6553
BR12083Q
BR14099Q
Z9155565
ZB214A9?
AS79O54Q
ZB215502
8S86O30Q
BS960080
Z909052Q
ZB14045Q
ZB1O040Q
BS19Q240
BS3A034Q
ZB102472
ZFM15390
YB86O270
Y887025Q
¥8850260
AS883705
Assaassa
¥6785120
¥8875203
¥8785113
YBe»O200
YB79011O
YB883196
YB786118
YB878202
YB792116
YB792108
YB887194
YA726842
YA658718
�DATE
630414
630414
680418
680418
680422
680422
680425
630425
680426
680426
680426
630524
680524
680716
680716
680806
680806
680806
680806
680806
630806
680927
680930
681003
681003
681003
681003
631006
681006
681007
631007
681008
681008
681008
681012
631012
631012
681012
631013
631013
631013
681013
681013
681013
681014
631023
681024
681025
681025
681101
&GN
0
0
0
0
0
0
0
w
w
w
w
w
w
w
w
w
w
w
w
w
w
w
w
w
w
n
GALS
3000
0
3000
0
2700
0
2900
. 0
2900
0
0
3000
0
3000
0
200
0
800
0
0
0
100
100
100
0
100
0
250
0
200
0
200
0
100
4000
0
0
0
200
0
3000
0
0
0
100
200
100
250
100
3000
TYP
t
D
D
p
0
C
D
P
S
C
C
C
P
S
C
C
C
D
C
D
P
C
P
C
P
P
LEG
1A
IB
1A
IB
1A
1R
1A
13
1A
13
1C
1A
IB
1A
IB
1A
IB
1A
18
1C
ID
1A
1A
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
1A
IB
2A
28
1A
IB
1A
IB
2A
28
1A
1A
It
1A
1A
1A
UTM
YT720850
YA650720
YA720840
YA650710
YB743043
YA743373
YB743043
YA743870
YB747043
YA747904
YA735385
YB750043
YA710854
YR770045
YB950065
ZB001215
ZB01021Q
ZB023259
ZP023258
Z8025252
ZB030254
ZB214495
ZB213502
ZB213510
ZB196518
ZB001211
ZB010210
ZA225808
ZA227783
AS920200
AS900230
ZB186528
ZB156560
YA763824
YB760042
YB8 13042
YB854072
YB950072
ZB18053Q
Z6155562
YB778030
YB820030
YB827055
YB950055
ZBOG2212
YA915745
ZB010141
ZB170730
ZB010141
Y678CG29
'
,
�PROV NO.
MISSIONS STARTING IN
Q5Tt
681101
681101
661101
681103
681103
681103
681104
631104
681105
631105
631105
681105
681105
631105
681105
631105
631106
631106
681106
681106
631109
681109
681109
681109
681109
631109
681109
631109
681109
681116
681116
681116
631116
681117
631117
681117
681117
631117
681117
681117
631117
631118
681118
681118
631119
631119
681119
631119
681119
681120
AGN
0
B
B
0
0
0
B
0
B
8
0
M
B
0
GALS
0
0
0
4000
0
0
3000
0
3000
0
0
0
3000
0
0
0
2600
0
0
0
3000
0
0
0
2800
0
0
0
0
3000
0
0
0
3000
0
0
0
3000
0
0
0
3000
0
0
100
3000
0
0
0
3000
TYP
D
e
c
D
r
LFG
18
2A
28
1A
18
1C
1A
IB
IA
18
2A
2B
1A
IB
2A
26
1A
IB
2A
D
D
D
D
0
n
p
P
D
28
1A
IB
2A
2B
1A
IB
1C
2A
28
1A
IB
2A
28
1A
IB
2A
2B
LA
IB
2A
2B
1A
IB
1C
1A
1A
IB
2A
2B
14
UTH
Y8819O29
YB851O58
YB950O59
YB786050
YB829170
YB829220
Z8142638
A3-156760
AS042638
AS&83271
AS89024B
AS93313Q
YB770261
YB8322O9
YB360238
YB888267
YB783047
YB81S047
YB8483/76
YB950O76
Y&760000
YB813039
YB853068
Y89&OOI&8
YB775260
YS819224
YB842262
YB871252
Y9890272
YA639734
YA654780
YA649812
YA73O869
YB770265
Y3819227
YB&60276
YB887276
YB7 70258
YB319218
YB844247
YB874247
Y* 63 0750
YA632313
YA7108a5
YA830920
YB780034
YB817034
YB853061
YB950061
YR733044
�MISSIONS START ING IN
nftTF
681120
681124
631125
631125
681125
631125
681207
681207
631207
681207
681207
631207
681203
681208
681203
68120S
681208
631210
681210
681210
681210
631213
681213
631213
681213
631213
681213
681214
681214
681214
681214
681216
681216
681216
681216
681219
631219
681219
681219
681219
681221
681221
681221
681226
681226
681226
681226
681227
631227
681227
AGN
W
0
GALS
0
100
3000
0
KONTUH
**:t** *******
TYP
P
P
0
3
L)
3
0
0
0
0
0
6
0
0
3000
0
0
3000
0
0
3000
0
0
0
0
3000
0
0
0
3000
0
0
3000
0
0
3000
0
0
0
3000
0
0
0
1400
0
0
0
0
3000
0
D
D
C
D
D
D
0
D
D
D
0
W
M
3000
0
0
'0
,
3000
0
0
D
D
L EG
IB
1A
1A
13
2A
23
1A
IB
1C
IA
IB
1C
IA
IB
2A
28
2C
1A
IB
2A
2B
IA
IB
1C
IA
16
1C
1A
IB
2A
28
1A
IB
2A
26
1A
IB
1C
2A
2B
1A
IB
1C
1A
IB
2A
28
1A
18
1C
UTM
YB793212
YA830960
YB782037
YB820033
YE354063
YB935062
YA691730
YA653629
YA653550
Y.»630/30
YA598642
YA598550
YB770270
YB825225
YB842249
YB377249
YB894270
YA646722
YA628815
YA651888
YA678890
YA685730
YA657629
YA65T550
YB738045
YB786183
YB786235
YA627727
YA650780
YA645813
YA7 13859
YBa82072
¥8826005
YA825942
YA8.08916
YB770274
YB822233
YB&48254
YBS73255
YB.8&8275
¥6753045
YA7549O5
YA726B69
YA64Q730
YA652765
VA639613
YA715865
YA623720
YA592644
YA592550
�KONTUM
************
GALS
TYP
LEG
3000
D
1A
IB
0
2A
0
26
0
IA
3000
D
IB
0
2A
0
26
0
D
1A
3000
16
0
1A
3000
D
IB
0
0
1C
1A
0
3000
IB
0
1C
0
10
0
2A
0
26
0
0
2C
20
0
D
1A
2000
IB
0
0
1C
1A
3000
D
IB
0
1C
0
1A
3000
D
0
IB
0
1C
2000
0
1A
IB
0
0
1C
1A
3000
c
IB
0
3000
D
1A
IB
3
3000
0
IA
IB
.0
0
1C
D
1A
3000
0
IB
0
ie
1A
2800
D
0
18
1A
2500
D
0
IB
2A
0
2B
0
1A
D
2700
MISSIONS STARTING IN
DATE
681226
681228
681226
631228
681228
68122P
681228
681229
631231
681231
690101
690101
690101
690102
690102
690102
690102
690102
690102
690102
690102
690105
690105
690105
690108
690108
690108
690109
690109
690109
690111
690111
690111
690112
690112
690113
690113
690114
690114
690114
690114
690114
693114
690115
690115
690118
690118
690118
69011&
690119
AGN
«
W
n
0
n
0
W
W
fi
W
W
W
'ft
W
W
W
UTM
YA&28733
YA646777
YA636814
YA72C870
YB87&086
YB811010
YA8 11948
YA7889-14
Y&a80620
YB8404&Q
YB737044
YA739893
YA723380
YB726O45
YA635815
YA790882
YA726905
YA653837
YA635815
YA613730
YA635815
YA641740
YA606640
YA606570
YB758045
Y8758095
YA731870
Y8872088
YB309011
YA795926
YB755045
YA755905
Y6 72 6 870
YA656887
YA615730
YB837&20
YB300458
Y8736040
YA736902
YA710870
YB7&9443
YB782415
YB782270
Y8852620
YB814454
YB751045
YB760000
YA761905
Y*731863
YB768045
J
�n,\TP
690119
690119
690119
690119
690120
690120
690120
690120
690120
690120
690121
690121
690121
690122
690122
690123
690123
690123
690123
690123
690124
690124
690124
690124
690124
690124
690125
690125
690126
690126
690123
690128
690128
690128
690128
690129
690129
690129
690131
690131
690131
690131
690131
690131
690201
690201
690201
690203
690203
690203
a.GN
GALS
TYP
0
0
W
3000
D
0
•A
3000
0
0
0
VJ
3000
D
0
0
X
3000
IB
D
0
0
fl
o
3000
D
0
3000
C
0
0
0
2750
D
0
0
2500
D
0
0
3000
D
0
0
0
0
3000
P
0
0
2900
D
3000
D
0
0
3000
3000
0
0
0
2100
•
0
D
n
o
0
0
3000
P
0
0
Q
ri
3000
0
0
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
C
IA
D
IB
1C
1A
IB
2A
0
0
3000
IA
IB
0
0
0
1C
14
IB
1C
1A
IB
IA
IB
1C
IA
IB
1A
IB
1A
IB
2A
28
IA
IB
1A
IB
0
0
LEG
IB
1C
IA
IB
1A
IB
1C
IA
UTM
YB816176
YB816212
YA68Q887
YA640730
YB740444
YB790180
YB790233
YB740044
YB792180
YB792231
YB774045
YA774886
YA760369
Y6862620,
YB825463
YA640730
YA609648
YA&a955Q
YB 8 3 780
6
YB83162O
YB841620
YB8G4451
YB864J96
¥8802024
Y/802959
YA777922
¥ A 7 2 890
0
YA6.6.273Q
YB877620
Y 683 846 2
Y&a6O&20
VB825465
Y381O450
YB798410
YB798380
YA63373O
Y £60 0 4 2
6
YA&00550
YB328215.
YB82817Q
¥6793070
YA62673O
YA 7 6 4
9 6 0
YA593550
YH770045
YA77083V
YA75386S
Y6885030
YB822005
YA822942
�UNCLASSIFIED
MISSICNS STARTING
'JATF
590203
690205
690205
690205
690207
690207
690207
690209
690209
690209
690209
690211
690211
690212
6C0212
690212
690214
690214
690214
690214
690215
690215
690215
690216
690216
690216
690225
690225
690225
690225
690225
690225
690228
690228
690228
690228
690228
690228
690301
690301
69U301
690307
690307
690307
690308
690303
690303
690309
690309
690312
4GN
0
0
T
0
0
0
0
0
0
0
0
0
0
fJ
0
n
0
PROV NO.
IN
GALS
0
2750
0
0
3000
0
0
3000
0
0
0
3000
0
3000
0
0
3000
0
0
0
3000
0
0
3000
0
0
3000
0
0
3000
0
0
3000
0
0
3000
0
0
3000
0
0
3000
0
0
3000
0
0
3000
0
3000
TYP
P
D
r
D
D
D
0
D
D
D
D
D
D
n
p
n
0
LEG
2B
IA
IB
1C
1A
IB
1C
14
IB
2A
2B
1A
IB
1A
IB
1C
IA
IB
2A
2B
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
IA
IB
1C
1<\
IB
1A
UTM
YA792912
Y3729000
YA72S903
YA701869
YA698730
YA663634
YA663550
YB88108Q
YB820005
YA820939
YA799907
YB850620
YB815465
YB921450
YB311410
YR811270
YB871089
YB806013
YA806947
YA784917
YA685730
YA650635
YA650550
YB797050
YB83U63
YB831210
YA615730
YA584646
YA584550
YA687730
YA&50,630
YA650560
YA612730
YA583645
YA5e3550
YB836450
YB826410
YB82fe270
YB771045
YB81817&
Y6S18210
YA&93733
YA655624
YA655550
YA6SJ730
YA643630
YA&43550
YA690S87
YA645725
Y.ft663887
�•DATE
690312
690312
690312
690312
690313
690313
690313
690315
690315
690315
69J315
690315
690316
690316
690316
690316
690317
690317
690317
690317
690317
690317
690318
690318
690313
690319
690319
690319
690320
690320
690320
690322
690322
690323
690323
690323
690323
690323
690323
690324
690324
69032-t
690324
690325
690325
690325
690325
690325
690326
690326
4GN
GALS
0
0
-,
3000
r
0
3000
c
o'
0
0
0
0
TYP
•
3000
n
0
0
.
0
3000
D
0
o
3000
D
0
0
1500
0
D
0
3000
D
0
0
0
3000
O
0
0
G
3000
D
0
0
--I
3000
0
0
0
0
3000
0
0
0
w
2000
D
0
w
w
3000
D
0
0 •
3000
P
0
0
w
3000
w
3000
D
0
3000
D
'. 0
0
w
3000
0
U
IB
1A
10
IA
18
1C
IA
18
1C
1A
IB
1C
iA
IB
1C
1A
IB
1C
IA
IB
IA
IB
1C
1A
18
ic
0
0
0
0
•ft
LF.G
18
1A
IB
1C
1A
16
1C
1A
16
1C
IA
IB
D
IA
IB
2A
26
1A
IB
IA
18
1C
IA
IB
UTH
Y/S662iT3q
YA702730
YA666632
YA66655O
Y*62073Q
YA589645
Y4589550
YB838450
YB82941O
YB829265
YA66088?
YA61773Q
YA683888
YA660729
YA627640
YB760044
YB8Q92ia
YA763906
YA736869
YA645730
YA614643
YA61455O
YB767Q45
YAT6TS9O
Y-A 75 0869
YA618642
YA6.1 8550
YA668385
YA626730
YA639735
YA606645
YA60655Q
YB792447
YB785414
YB785270
YB862080
YB305013
YC804947
YC792925
YA675383
Y4632730
Yi664730
YA63055O
YB731045
YA731905
�M I S S I O N S S T A R T I N G IN
HATE
69J326
690328
690328
6 903 2 S
690331
690331
690404
690404
690405
6904J5
690405
690409
690409
690409
690409
690417
690417
690417
690418
690418
69041S
690418
690419
690419
690420
690420
6"0420
690420
690423
690423
690423
690507
690507
690507
690509
690509
690509
690509
690510
690510
690510
690526
690823
690921
69 OS 21
690921
690922
690929
691006
691010
AGN
w
w
w
0
0
r\
0
ft
0
0
w
GALS
0
3000
0
0
3000
0
TYP
n
0
3000
0
2000
0
0
2000
0
0
0
3000
0
0
3000
0
3000
0
3000
0
3000
0
0
0
3000
0
r>
2000
0
0
3000
0
0
0
660
0
165
D
n
D
D
P
D
0
0
0
• o
0
tf
W
W
w
w
w
w
v-J
w
w
w
w
110
160
100
350
200
500
300
945
100
PROV NO.
KONTUM
D
P
P
P
P
C
r
c
c
P
P
f
LEG
1C
1A
13
1C
1A
IB
1A
IB
1A
13
1C
1A
18
2A
2B
1A
IB
1C
1A
IB
IA
16
1A
IB
1A
IB
2A
2B
14
IB
1C
IA
IB
1C
1A
11?
1C
ID
IA
IB
1A
1A
1A
1A
1A
1A
1A
1A
1A
1A
JTM
YA703868
YB815450
YB806410
YB30627Q
YA695890
YA64S710
YA696887
YA655730
YA652730
Y4620640
YA620550
YB782081
YB818005
YA319939
YA810925
YB766045
Y6314177
YB814213
YB8 70620
YB836460
YB866620
Y8831460
Y3866620
YB8314&0
YB762045
YA766995
YA766905
YA74O869
YB791020
Y8824164
YB824210
YA658730
YA625&3^
YA625550
YB86O097
Y5795015
YB7 95950
YS775920
YA98Q964
ZAQ08964
/A22O840
YA98393Q
YBS66251
YA640880
YA6803aO
YA830330
YA8&0620
YP870256
YB87S255
YA760dlO
�UNCLASSIFIED
MISSIONS
D*TP
691022
691031
691031
691108
691108
691108
691108
691108
691108
691109
691109
691109
691110
691110
691110
691110
691110
691110
691111
691111
691111
691114
691114
691114
691115
691115
691115
691115
691116
691116
691116
691116
691116
691116
691116
691119
691119
691119
691119
69111<5
691119
691120
691120
691120
691121
691121
691121
691124
691124
691124
S T A R T I NIG
G
AGN
W
B
B
B
IN
IN
GALS
130
2603
0
1700
0
0
2000
KOKTUM
************
TYP
LEG
1A
C
1A
C
18
C
1A
ie
D
0
0
8
B
0
B
0
B
B
B
0
2000
0
0
1600
0
0
2000
0
0
3000
0
0
2300
0
0
1900
0
0
0
2300
0
0
3000
0
0
0
3000
D
D
r>
0
0
D
D
C
D
0
B
n
b
P
0
1700
0
0
3000
0
0
3000
0
'. 0
3000
0
0
C
0
D
D
1C
IA
13
1C
1A
18
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
18
1C
1A
IB
1C
ID
1A
IB
1C
1A
IB
1C
ID
1A
IB
1C
1A
IB
1C
1A
18
1C
1A
IB
1C
1A
IB
1C
PROV NO. =
UTM
YA740810
AS88827Q
AS968060
YR93414S
YB9Q1191
YB866298
Y8834217
Y6914254
YB 89 929 8
YB755110
YB787186
Y6786279
Y8833221
YB907253
Y6891298
Y3938153
Y8906193
YB872293
YB758110
YB789187
Y8789278
YB833218
YB913253
YB89629S
YB98005 1
YB880051
YB8OG014
YB770014
YB936151
YB903192
YB878269
YB818217
YB914259
YB821222
¥8390254
YS874298
YB908194
YB950140.
YB813221
YB910206
Y3898298
YB980053
YB906053
YB795015
YB883298
YB901264
YB833233
YB9fj0088
YB870088
Y0830070
�MISSIONS
S T A R T ING
IN
KONTUM
£#*$*£?*****
DATE
691124
691128
691128
691128
691130
691130
691130
691130
691130
691130
691201
691201
691201
691202
691202
691202
691202
691202
691202
691204
691204
691204
691205
69120?
691205
691205
691205
691205
691207
691207
691207
691208
691208
691208
691210
691210
691210
691211
691211
691211
691211
691211
691211
691211
691212
691212
691212
691213
691214
691214
AGN
0
0
0
0
0
0
0
0
0
n
n
0
a
3
0
0
0
GALS
0
2000
0
0
2800
0
0
2000
0
0
2900
J
0
3000
0
0
2000
0
0
3000
0
0
3000
0
0
2000
0
0
3000
0
0
2000
0
0
3300
0
0
700
0
0
0
3000
0
0
3000
0
'. 0
goo
2800
0
TYP
I)
D
D
D
C
rD
D
LEG
10
1A
IB
1C
1A
IB
1C
IA
IB
1C
tA
IB
1C
1A
IB
1C
tA
IB
1C
IA
IB
1C
iA
IB
tc
0
1A
ie
c
c
D
0
D
r*
p
n
1C
1A
IB
1C
16
IB
1C
IA
IB
1C
1A
IB
1C
ID
1A
IB
1C
1A
IB
1C
IA
1A
IB
UTM
YB780O43
YB793UO
YP822188
YB820a79
YB98614Q
Y393T193
YE9 17251
Y6760UO
YB792187
YB793279
YB776110
YB806188
YS806Z73
YB983136
YB935187
YB903270
Y8786110
YB814190
YB8i4;2£3
Y8?68iUO
Y8799186
YB 799273
Y6980Q&8
YB875O67
YB758O2A
Y&79511Q
YB8241»8
YB8242aO
Y677911Q
Y880I9184
Y8&0.9279
Y876&11Q
YB7951S3
YB795279
YA705801
YA675753
YA67064-O
YB897298
YB9122&3
YB9O2250
Y88S5296
YB6 76298
YB91 0.195
YS9&6125
Y/ 1 73 1481
YA641560
YA642640
YB852250
YA654756
YA653640
�MISSIONS
r>4TF
691214
691214
691214
691214
691215
691215
691215
691216
691216
691216
691216
691216
691216
691216
691217
691217
691217
691218
691210
691218
691218
691218
691218
691219
69121?
691219
691222
691222
691222
691224
AGN
n
G
B
B
0
n
0
n
0
0
6<n 22 4
691224
691224
691224
691224
691226
691226
691226
691226
691226
691226
691227
b91227
691227
691227
691227
0
0
0
13
601 £ f ~7
v L "5 *? i
691230
691230
691230
GALS
0
3000
0
0
2000
0
0
2500
0
0
0
3000
0
0
2000
0
0
2600
0
0
2900
0
0
TYP
2100
D
D
D
D
t>
0
D
T
0
0
3000
0
0
2900
0
0
u
2000
0
0
3000
0
0
3000
0
0
2000
0
0
3000
0
D
' D
.
V
P
0
D
D
D
',-0
B
PROV f4Q,
KONTUM
STARTING
3000
0
0
r
LEG
1C
1A
IB
1C
1A
18
1C
1A
IB
2A
2B
1A
IB
1C
14
IB
1C
1A
IB
1C
14
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
13
1C
14
IB
1C
14
IB
1C
x
UTM
YA653510
YA656640
YA657564
YA738492
YB933153
ZB000090
ZB000014
YB886293
YB9Q5247
YB9U268
Y6833236
YB879298
YB912195
YB968127
YB981135
YB932187
YB9 10249
YB984138
YB936190
YB907270
YB781UO
YB812185
YB812278
YB983137
YB936188
YB910249
Y8800UO
YS829188
YB328279
YB803UO
YB832188
YB331278
YB970128
YB915197
YB881293
YA70779a
YA678750
YA6 74640
YA672640
YA672570
YA74350Q
YB972129
YB915199
YB900245
YB773110
YB804185
YB804279
Y8S65293
Y688623-'?
YB916253
'.INC Lt
1
�OATF
691230
69 I 23 I
691231
691231
691231
691231
691231
700102
700102
700102
700102
700102
700102
700,104
700104
700104
700105
700105
700105
700 10 5
700105
700105
700106
700106
700106
700107
700107
700107
700108
700108
700108
700108
700108
700108
700109
700109
700109
700109
700109
700109
700110
700110
700110
700111
700111
700111
700111
700111
700111
700111
AGN
GALS
TYP
2000
2000
0
D
2900
D
3000
3000
c
2000
1A
1C
IB
1C
D
3000
F)
1A
IB
C .
1A
1C
0
0
0
2000
18
1C
0
0
0
a,
3000
3000
0
2800
0
2000
C
2000
C
0
0
3000
0
0
1A
IB
1C
D
0
0
0
0
1A
IB
1C
0
0
3000
1A
IB
1C
0
0
0
1A
IB
1C
0
0
D
1A
IB
1C
0
0
0
1A
IB
1C
0
0
Q
IA
IB
1C
0
0
0
IA
0
0
0
2000
1A
IA
IB
0
0
0
YB930185
YB9Q524 ?
¥6978133
YB923185
YP905246
YS77U10
¥9801186
YB801279
YA649640
¥£648562
YA734486
YA64564Q
YA643559
YA733484
YR980056
Y6880055
YB790015
Y A 74 4503
YA67457Q
YA674640
¥4679817 |
Y A 64 3 760
YA642640
YB980081
Y 886 6 031
YB795043
YA685814
YA728882
YA810945
YA68564Q
YA657566
YA739498
¥4712797
YA682T50
YA677640
Y398OO66
YB865065
YB803030
YA67O640
YA670568
YA737503
YA682815
Y/>725883
YA812945
YP850235
YR339446
¥8829400
YB83127?
P
0
0
0
YB978U4
IB
1C
0
0
0
1«
IB
1C
0
0
YB90029S
IB
1C
t
0
0
0
UTM
ID
0
'J
L-:G
1A
IB
1C
ID
D
1A
IB
1C
�O&TL'
700111
700112
700112
700112
700112
700112
700112
700112
700113
700113
700113
700113
70J113
700113
700114
700114
700114
700115
700115
700115
700115
700115
700115
700116
700116
700116
700116
700116
700116
700117
700117
700117
700117
700117
700117
700117
700117
700118
700116
700118
700118
700118
700118
700119
700119
70J119
700119
700119
700119
700120
AGN
n
0
0
n
0
0
0
0
0
0
0
0
0
0
Q
0
GALS
0
3000
0
0
0
2900
0
0
2000
0
0
3000
0
0
3000
0
0
1900
0
0
2800
0
0
2900
0
0
3000
0
0
2400
0
0
0
0
3000
0
0
2650
0
0
3000
0
0
2900
0
0
2000
0
0
3000
TYP
L. ^ G
UTM
n
1A
13
1C
ID
YB850235
YB980071
YB867071
YB792030
YB786015
D
1A
IB
YA661640
Y A 66 5660
1C
1A
IB
1C
1A
IB
1C
YA735503
YB974130
YB918200
YB382298
YA81945?
YA78MOO
YA786279
YB980056
YB876057
Y8805025
YA662640
YA662561
YA728494
YB980084
YB 86 9084
YB790046
YB833449
YB820400
YB323279
YB764UO
YB796185
YB796279
YB963138
YB94613S
YB915250
YB936189
YB96817Q
YBS29453
Y38104QO
YB813279
Y6791UO
YB82C1187
YB819238
YB98Q077
YB871077
Y6785Q35
Ye98OQ65
YBa660«4
YP800027
YA727501
YA648566
YA650640
YB9JJOU75
ID
n
D
D
D
1A
18
1C
1A
IB
1C
D
D
0
D
D
n
0
D
1A
IB
1C
1A
IB
1C
1A
18
1C
IA
IB
1C
2A
28
1A
IB
1C
1A
IB
1C
1A
IB
1C
: 16
IB
1C
D
1A
16
1C
r.
14
}
�UNCLASSIFIED
MISSIONS
'JG
IN
KPNTUM
PROV NO.
**55 *< 11 * * *
* * *
700120
700120
700121
700121
700121
700121
700121
700121
700122
700122
700122
700122
700122
700122
700122
700122
700123
700123
700123
700123
700123
700123
700123
700124
700124
700124
700124
700124
700124
700125
700125
700125
700125
700125
700125
700126
700126
70012&
700126
700126
700126.
700127
700127
700127
700127
700127
700127
700128
700128
70012C
GALS
0
0
3000
0
0
3000
0
0
2900
0
0
0
3000
0
0
0
3000
0
0
0
3000
0
0
2000
0
0
2000
0
0
2900
0
0
3000
0
0
1900
0
0
1900
0
0
3000
0
0
3000
0
0
3000
0
0
TYP
D
D
D
D
D
C
D
D
D
0
D
D
D
p
C
LEG
IB
1C
1A
18
1C
1A
IB
1C
1A
IB
1C
ID
IA
IB
1C
ID
1A
IB
1C
10
1A
IB
1C.
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1«
IB
1C
UTM
YB86407o
Y6795345
YA702B02
YA671752
YA6&964G
YS980Q87
¥8865037
YB779Q<tO
YB865298
Y6855257
YB833250
Y8870282
Y£&87813
YA811970
YA719880
YA802939
YB831451
Y8818400
YB821279
YB837250
YB799110
YB82&188
YB825279
YB98006Q
YB876060
YB800025
YB837447
YB827401
YB829279
YB821458
YB797389
YB822279
YA690810
YA656756
YA655640
YB980073
YB865O72
YB774027
YA647640
YA&4&5&2
YA734485
YA682815
YA647759
YA643640
YA666640
YA665555
YA728498
YB930O60
Y3S77060
YA777J16
�UNCLASSIFIED
MISSIONS ST*
DATE
7QOl2ci
700129
700129
70012?
700129
700129
700130
700130
700130
700130
700130
700130
700131
700131
700131
700131
700131
700131
700131
700131
700201
700201
700201
700202
700202
700202
700202
700202
700202
700202
700202
700203
700203
700203
700204
700204
700204
700204
700204
700204
700204
700204
700210
700210
700210
700210
700210
700211
700211
700211
AGN
n
0
n
0
0
0
a
0
0
0
0
0
0
0
G
IN
PROV
KGNTUK
************
TYP
LEG
GALS
D
1A
3000
IB
0
1C
0
0
1A
3000
IB
0
1C
0
D
1A
3000
IB
0
1C
0
D
1A
3000
IB
0
1C
0
L
1A
3000
IB
0
1C
0
D
1A
3000
IB
0
1C
0
2A
0
28
0
P
If.
3000
18
0
1C
0
D
|A
3000
IB
0
1C
0
0
10
IE
0
D
iA
3000
IB
0
1C
0
0
14
3000
IB
0
1C
0
C
1A
30OO
18
0
1C
0
C
1A
3000
18
0
1C
0
2A
0
2B
0
D
1A
2900
18
0
1C
0
2A
0
28
• 0
0
1A
3000
IB
0
1C
0
UTM
YB821458
Y6784399
YB79026Q
YB788110
YB81719Q
YB81729Q
YA684814
YA649759
YA647640
YB783UO
YB813184
¥8813279
YB82245'->
YB7884OQ
YB7922?9
YA66764Q
YA667569
YA705530
YA725498
YA64Z563
Y*693S08
YA658753
YA65861Q
YA6 78818
YA717387
YAaO395Q
YA334163
YA803.19Q
YA686811
VA651751
YA650640
YA694807
YA&60753
YA&61640
YS83a452
Y891439O
¥581^278
YB965125
YB997O9O
Y 399701 3
ZB002013
ZBOO2U5
YB987133
YB993013
1 BO 16.01 3
ZB016098
YB993U77
YA676819
VA 716887
YA8Q5<?54
NO.
�OSTP
700211
700211
700211
700211
700211
700212
700212
700212
700212
700212
700212
700213
700213
700213
700214
700214
7C0214
700215
700215
700215
700215
700215
700215
700215
700215
700215
700216
700216
700216
700216
700216
700216
700217
700217
700217
700217
700217
700217
700217
700217
700217
700217
700218
700218
70J218 .
700228
700228
700228
700228
700301
4GN
0
GALS
3000
0
TYP
D
0
0
0
0
0
0
0
0
0
0
rt
0
0
0
0
3000
0
0
3000
0
0
2900
0
0
3000
0
0
2000
0
0
3000
0
0
0
0
0
3000
0
0
0
0
0
3000
0
9
0
0
0
.0
3000
0
0
2000
0
0
3000
0
0
0
3000
r
D
D
D
0
D
D
D
0
D
0
r
LEG
1A
IB
1C
2A
2B
1A
IB
1C
1A
IB
1C
IA
IB
1C
IA
IB
1C
IA
IB
1C
1A
IB
1C
2A
2B
2C
1A
16
1C
2A
2B
2C
1A
IB
1C
2A
2B
2C
20
1A
18
1C
1A
IB
1C
IA
IB
1C
ID
1A
UTM
YB968126
ZB005081;
ZB005013
ZB034013
ZB041033
YA7018J4
YA671754
YA667640
YA665825
YA712890
YA810963
YB827454
Y3807400
YA811278
YA698805
YA666753
YA663640
YB824455
YB790400
YB7S4279
YB971128
ZB007O90
ZB007013
Z8031013
ZB03803Q
Y6997148
YB980135
ZB018099
ZB019013
Z5028013
ZB030079
YB9S7129
YB984013
YB981090
Y8954115
Y8998149
ZB027103
Z8023070
ZB023032
YA690811
YA72S879
Y,A-313934
YA697306
YA665752
YA662640
YA637S21
YA714339
YA30S359
YA810982
YA7117S8
�OATF:
700301
700301
700301
700301
7J0301
/0030 1
703301
703302
700302
700302
700302
700305
700305
700305
700305
700305
7J0335
700305
700306
700306
700306
700306
700306
700306
700307
700307
700307
700307
700308
70030R
700308
700308
700308
703308
700308
700308
700311
700311
7U0312
700312
700312
700320
700320
700320
700321
700321
700321
700321
700321
700321
ar,N
GALS
TYP
0
0
0
0
n
3000
D
0
0
0
3000
0
0
0
0
0
3000
D
0
0
0
0
3000
D
0
0
0
a
2800
P
0
0
0
0
0
3000
2C
D
0
0
0
0
3000
0
0
0
u
0
0
3000
0
0
0
0
500
0
3000
0
D
D
0
0
0
300O
0
0
0
0
3000
r»
0
0
0
3000
0
0
LEG
IB
1C
10
1ft
IB
1C
10
1A
IB
1C
10
IA
IB
1C
10
1A
IB
1C
1A
IB
1C
2A
2B
pi
1A
18
1C
10
IA
IB
1C
1A
IB
1C
ID
IE
1A
IB
IA
IB
1C
1A
IB
1C
14
IB
1C
IA
IB
1C
UTM
YA769891
Y A3 1293 I
YA82397Q
YB82245Q
YB80145O
YB801400
YB8022T9
YA670823
YA712S90
Y A 76 893 5
YA 7 4 6
896
YA671322
YA717895
YA765926
Y8804005
YB754110
Y572604Q
YA721915
YB976132
ZB012O97
ZB020013
Y8994146
26023088
Z8030O13
YA6918O9
YA732S78
YA8 12930
YA 81 7944
Y6773UO
YS745032
YA74092J
YA6948O8
YA733376
YA300918
YA313948
YA827OOQ
YB786110
YB774O80
YB758HO
YB732045
YA728920
YB797110
YB762015
YA762933
Y877Q110
YB739033
YA737920
Y8985013
YB982077
Y^993077
�UNCLASSIFIED
MISSIONS STftPTING IN
OATF
700321
700322
T00322
700322
700322
700322
700322
700322
700323
700323
700323
700325
700325
700325
700326
700326
700326
700326
700328
700328
700328
700323
700914
700914
700920
700920
700920
700920
AGN
0
0
0
0
0
0
B
B
GALS
0
3000
0
0
3000
0
0
0
3000
0
0
3000
0
0
2000
0
0
0
3000
0
0
0
1200
0
3000
0
0
0
P R O V NO. =
KQNTUM
ft*?-***
f^Jf.ii=**
TYP
D
n
D
n
P
r>
C
C
LEG
ID
1A
IB
1C
1A
IB
1C
ID
1A
IB
1C
1A
IB
1C
1A
IB
2A
28
IA
IB
1C
ID
IA
IB
1A
IB
1C
ID
UTM
YB993013
YR78311G
YB750013
YA750910
YA703802
YA758895
YS815947
YB340043
YR761110
YB729034
YA726910
Y8800110
Y8766017
YA765920
YA786943
YB815021
YB818022
YA779945
YA780943
YB322023
YB825023
YA767910
ZB150660
ZB150760
YS960600
IB 100600
ZB10047O
YS9604TO
U'-ICL'.S-JT
�17062
17062
,\iPPOV=
-MPP.OV=
380
330
NZREC=
NZREC=
698
U N C U S S I F I £P
U'JCLASSTFl-0
�DAT?
650906
650906
650907
650907
650923
650924
650S25
650926
600927
650929
650930
650930
651001
651001
651002
651002
651003
651003
651004
651004
651005
651005
651005
651010
651010
651111
651111
651112
651112
551115
651115
651116
651116
660313
660313
660313
660313
660316
660316
660321
660321
660322
660322
660324
660324
660324
660324
660326
660326
660326
A6N
0
0
0
0
0
0
0
0
0
3
0
0
0
0
0
0
0
0
0
0
0
0
o
0
0
GALS
TYP
D
1000
0
2000
0
3000
D
C
C
C
C
C
C
C
1000
2800
1200
1000
2450
2000
0
3000
0
2000
0
2000
0
2000
0
C
C
D
C
C
1750
0
0
2500
0
2000
0
3000
0
2000
0
2000
0
2000
0
0
0
2000
O
5000
0
1800
0
2500
0
0
0
2600
0
0
C
0
0
0
D
0
D
•
0
C
C
C
LEG
IA
IB
1A
16
1A
tA
1A
|A
1A
1A
IA
IB
1A
IB
IA
13
u
IB
1A
1.6
IA
IB
1C
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
1A
18
IA
IB
1A
IB
1A
IB
1C
I
D
LA
IB
1C
UTM
BR570450
BR625650
3R570450
6P62565Q
BR678855
63684720
BR800<i6Q
BR6007UO
BR670850
8R675740
BP 74 0760
BR700B40
BR710770
BR815650
BS62016Q
BS74016U
8R 570450
8R625650
68470970
8R59O67Q
BS620170
RS670220
BS735170
BS72520O
3S712020
BR30O454
BR39O447
BS30O455
BS39O447
BR26O465
BK360454
8rH2^Gl445
B>R36O445
8R885945
BR9«0:a75
8A95OS8O
BR95T91 8
BR394383
5R3 19258
&R33;546O
3R2 45.494
BS61516.0
BS7J5170
&R673849
BR722;813
8R74773Q
9 ''.734 77^9
BP.6&0717
BP 73 7 795
BP.730aO8
'
|
�MISSIONS START ING IN
DATE
660326
660330
660330
660403
660403
660403
660403
660405
660405
6604Q5
660405
660407
660407
660409
660409
660409
660409
660409
660409
660409
660409
660409
660409
660410
660410
660412
660412
660412
660413
660413
660414
660414
660414
66Q414
660414
660414
660414
660414
660415
660415
660423
660423
660502
660502
660502
660502
660513
660513
660517
660517
AGN
0
0
0
0
0
0
<3
0
0
0
0
0
Q
0
0
8INH DINH
******
******
TYP
LEG
GALS
ID
0
1A
3000
D
IB
0
1A
4000
C
18
0
2A
0
2B
0
1A
C
3000
IB
0
2A
0
28
0
1A
2500
C
13
0
IA
3000
C
IB
0
2000
D
IA
IB
0
2A
0
28
0
3A
0
3B
0
4A
0
4B
0
1750
C
IA
IB
0
1A
1950
C.
0
2-A
0
3A
IA
2000
D
0
18
IA
2000
D
O
IB
2A
0
0
2B
0
3A
0
3B
4A
0
Q
48
2000
D
1A
0
IB
3000
1A
D
0
IB
3000
C
IA
0
IB
0
1C
0
10
n
2000
1A
0
IB
2000
D
It.
0
IB
UTM
BR681317
BP395382
B3321255
BR680738
BR732783
BR823700
BP810620
8S665200
8S735160
BS715230
85730160
BP665785
BR740770
BS210030
3P400670
BS753070
BS763042
BR873950
BF900869
BR894-359
BR870894
BR830920
3R838891
8R54Q990
BR615620
BS 75420Q
3R7Q075Q
BR80065O
BR425627
BR4-S0590
BR840890
BB 83 5920
SP,S759tt,0
BR39O860
BR9O2870
5R8789S2
85756070
85765041
BR425.628
BR48a590
6R57O445
5*625465
eC8;6O972
BR 83 605 2
3P85OO70
&P86OIOO
B0870970
SR 84 50 5 5
B" 8 7 895 3
8Fs87494O
�UNCLASSIFIED
MISSIONS
DATE
660517
660517
660517
660517
660517
660517
660517
660519
660519
660519
660519
660519
660519
660519
660519
660522
660522
660522
660522
660524
660524
660524
660524
660528
660528
66060C
660608
660608
66060S
660610
660610
660610
660623
660623
660703
660708
660708
660708
660719
660719
660720
660720
660813
660813
660813
660813
670224
670224
670226
670226
STARTING
AGN
IN
GALS
BINH OINH
TYP
0
0
0
0
0
0
0
0
3000
D
0
0
0
0
0
0
0
0
2000
D
0
0
0 '
0
3000
D
0
0
0
0
2900
D
0
0
2000
C
0
0
0
0
2000
P
0
0
0
n
2000
D
0
2000
D
0
0
0
PPOV
LEG
1C
2A
28
3A
38
4A
46
1A
18
1C
ID
2A
2B
3A
36
1A
IB
1C
ID
1A
IB
1C
ID
1A
IB
1A
IB
1C
ID
1A
IB
1C
1A
IB
1A
IB
2A
26
1A
IB
1A
IB
D
90
.0
D
n
0
850
0
D
1700
C
1A.
C
IB
1C
ID
1A
IB
1A
IB
9
0
0
0
0
n
27BO
0
1800
0
C
UTM
BR9Q0670
BS762Q30
BS756070
BR888860
BR870896
BR350890
8R35092G
BR863765
BP880745
BR875737
BR860755
BR861772
BR864781
BR861762
BR880755
BR850626
BR853577
BR84658O
BR841626
BP.960575
BP911556
BR920547
8R962566
CPO35131
CR010187
CR030130
CR010185
CR020185
CR045155
BR870&20
BR845625
BR850580
CR043154
CR034187
BP840630
3R843577
3P912556
8F960570
CR015167
CP023132
BR960570
BP915555
CR010185
CR040187
CR030132
CR040132
3P570770
BR620610
BR680720
3R760830
NO.
�UNCLASSIFIED
MISSIONS STARTING IN
PAT?
670303
670303
670305
670305
670312
670312
670314
670314
670314
670314
670409
670409
670409
67040^
670410
670410
670410
670413
670413
670415
670415
670416
670416
670417 '
670417
670422
670422
670422
670422
670424
670424
670424
670424
670425
670426
670426
670426
670426
670428
670428
670429
670429
670502
670502
670502
670502
670518
67051H
670520
670520
AGN
0
0
B
B
3
0
3
3
8
S
B
0
0
0
0
0
n
0
0
GALS
1800
0
900
0
1600
0
1800
0
0
0
2790
0
0
0
2550
0
0
2790
0
1700
0
1800
0
1860
0
2790
0
0
0
1860
0
0
0
2790
2790
0
0
0
5580
0
1300
0
1000
0
0
0
3720
0
5580
0
P?,OV NO. =
BINH OINH
TYP
C
C
C
c
c
c
c
c
c
c
c
c
c
c
c
r
c
r
r
LEG
1A
IB
IA
is
IA
IB
1A
IB
2A
28
1A
IB
2A
28
IA
16
1C
IA
18
1A
18
XA
IB
1A
IB
1A
IB
2A
26
IA
IB
2A
2B
1A
1A
IB
1C
ID
1A
IB
1A
IB
IA
IB
1C
ID
1A
IB
1A
IB
UTH
BS64Q200
8S73016Q
Be767964
BP772913
3S735049
8S725O98
BR675652
BR69873Q
BR762836
8S&2Q160
8 $74018,0
8S74Q19O
BS75O210
BR3.OQ820
6R250790
8R77O9S6Q
SR79Q9OO
S#270900
&R30O760
SR34067Q
&S62O16O
BR18097O
BK21080Q
BR26G88Q
BR260990
BK350690
6*400690
B.R2 90,860
BR330870
Bf320770
BS320180
BS820230
BS870230
B.S91G16O
BR5OO450
BP.6007OO
BS860233
8S902160
BS81Q190
8S81024O
PS9OO19O
3S880240
3S788160
8R786993
B 577716,0
6 P. 78 298 2
7
�D£Tc
670521
670521
670526
670526
670526
670526
670526
670526
670526
670526
670526
670526
670526
670526
670530
670530
670530
670530
670601
670601
670601
670601
670602
670602
670603
670603
670604
670604
670605
670605
670605
670605
670608
670608
670613
670613
670614
670614
670615
670615
67061?
670617
670620
670620
670623
670623
670626
670626
670626
670626
£GN
0
0
3
0
n
0
0
0
0
0
w
0
0
0
0
0
0
0
0
1
GALS
3550
0
2710
0
0
0
0
0
2360
0
0
0
0
0
4180
0
4650
0
1940
0
2790
0
5580
0
5580
0
5105
0
1860
0
0
0
2790
0
2790
0
1395
0
2390
0
2790
0
2440
0
2740
0
2790
0
0
1500
TYP
C
C
C
C
D
0
D
C
r-
D
D
0
C
C
C
C
D
C
C
ri
LEG
1A
IB
1A
18
2A
2B
3A
36
1A
IB
2A
28
3A
3B
IA
IB
1A
IB
1A
IB
IA
IB
IA
IB
IA
IB
IA
IB
IA
tB
2A
28
1A
IB
IA
IB
1A
IB
IA
IB
1A
IB
1A
13
1A
IB
1A
IB
1C
14
UTM
BS 75 005 0
BS780950
BS735160
BS755005
BR28080Q
8R290670
BR280700
BR27080Q
'
BS735160
BS755005
BR280800
8R290670
8R280700
8R270800
8S793160
3S740050
3S79316Q
BR800990
8S830160
3S8303OO
BS785160
BP782983
BS772160 |
BR786980
BS793160
8R789980
BS798160
BR813988
BS&63223
9S734150
BS715230
BS746230
BR880770
BR87Q820
BS630120
BS74Q150
BR590950
BR60.0720
BR280950
8R26Qa50
9Sdl0190
8S300OOO
BR 86 5 340
8P878766
BR480970
SR6 10710
BR36Q650
BR270740
8R300800
?F.&14160
L
�DITfc
670626
AGN
670623
670623
670629
670629
670629
670629
670701
670701
670701
0
670701
670702
670702
670702
670702
670703
670703
670705
670705
6 70 70S
670708
670708
670708
670708
670708
670712
670712
670713
670713
670717
670717
670718
670718
670719
670719
670723
670723
670728
670728
670729
670729
670730
670730
670731
670731
670803
670803
670806
670806
6 7080?
GALS
TYP
0
1860
D
0
0
1780
C
0
0
0
0
2790
C
0
0
0
0
0
2790
0
0
0
400
0
0
1300
0
1300
C
C
0
0
C
0
0
0
0
2500
0
1800
C
0
0
814
0
0
0
3000
C
C
0
0
0
2400
C
0
0
3000
D
0
0
2000
C
0
0
2000
C
0
0
o
1750
C
0
2000
C
0
0
2000
C
0
0
1600
C
'0
n
2900
D
n
0
250
C
LEG
18
IA
IB
IA
18
2A
26
1A
IB
2A
2B
1A
IB
2t
2B
1A
IB
1A
IB
1A
IB
2A
2B
1A
18
IA
IB
1A
IB
IA
IB
IA
IB
IA
IB
IA
16
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
1£
UTM
BR825785
BP32Q270
BR39O390
BS40O080
BS54010O
BR4Q0950
6R 5 0 5
4 9 0
BR68086G
BR 72 0810
BR690S8O
SR76082O
BR 4 0 3 0
0 0
8R310780
6R290660
BR42O730
BP, 4 0 9 0
9*8
BP,58Q380
BS84Q160
BR85099O
BS66O22O
BS730170
BS 75 0 6
0 0
SS760GOQ
BS766063
8S764196
BR73070Q
BR75082O
BR938925
SR92197Q
BR665735
BR735792
BR4QQ6TO
BR330600
BS782160
BS783QOO
BS761180
BS768045
BS725160
BR755935
BR672847
BR770838
BS630120
BS740110
8S665220
3S740100
5P771640
OP327618
BS788168
3S7e- 1004
BS415U15
'
1
�UNCLASSIFIED
MISSIONS ST*RTJMG IN
P*7r
670B08
670808
670806
670813
670013
670813
670813
670813
670813
670E18
670818
670820
6 70 820
670820
670820
670C21
670«21
670824
670824
670910
670910
670914
670914
670918
670918
670918
670919
670919
670920
670920
670920
670920
670920
670920
670920
670920
670921
670921
670925
670925
671009
671009
671009
671009
671010
671010
671010
671010
671017
671017
A
GN
R
3
G»LS
0
500
0
TYP
1150
C
C
0
0
0
0
0
B
B
B
p,
n
0
0
0
0
1800
0
2350
0
0
0
1800
0
2825
0
2650
0
2800
0
2900
0
Q
2550
0
1000
C
C
C
C
D
0
C
p
C
0
0
0
E>,
8
B
r>
n
1800
0
0
0
2400
0
3000
0
2800
0
0
0
2000
0
C
C
C
D
C
• o
W
0
3000
0
PSDV NO. =
BINH DINH
0
LEG
18
1A
IB
1A
IB
2A
28
3A
3B
1A
IB
1A
IB
1C
ID
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1C
1A
IB
iA
18
2A
2B
IA
IB
2A
2B
IA
1©
IA
IB
1A
IB
2A
28
14
IB
2A
20
1A
IB
UTM
BS432018
BS415015
BS432018
BR365980
BP379953
BR500&47
BP 50 5 802
BR525792
BR527844
BS660220
85740.980
BR38Q948
BR48095O
BR493965
8R493t045
3S490970
BS590.770
BS340O40
BS573081
as 7581 80
BS758040
BR250483
Bfi310A.5-5
BS 66 7268
BS760250
BS735170
BR 581450
BR&l 6.475
&!?59O953
9R590S46
8ft 61 0'36O
B^5.^Oi8t 2
3R59O953
BR590846
BR6 10860
BR59081H
&fi.52 034-O
B.R585712
BR402951
3R58873O
3S83002O
BS780020
BS330013
QS786013
&S830U03
BS780(K)l
BR830993
BR 78 099 4
B>213523
BP2604o8
�OtTr
671017
671018
671018
671228
671228
6SJ323
630323
6P.G323
630326
680326
680405
6304J5
630413
630413
680420
680420
680421
630421
630422
680422
680423
680423
680506
680506
680507
680507
680507
630507
680703
630703
680706
680706
680713
680713
680?13
630716
680716
530719
680719
680719
680719
680728
68072S
680801
680801
680803
6SOS03
630805
630805
680P05
iGN
0
0
0
0
0
0
g
0
0
0
n
0
0
n
0
0
0
n
B
0
o
0
n
0
GALS
0
4000
0
2800
0
2300
0
0
1500
0
3000
0
3000
0
3000
0
3000
0
3000
0
2900
0
2550
0
3000
0
2700
0
2000
0
3000
0
3000
0
0
3000
0
2600
0
3000
0
2900
0
2900
0
27*00
'•0
1200
0
3000
TYP
L3G
1C
0
1A
IB
C
IA
IB
1A
18
1C
14
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
iA
IB
1A
IB
1A
IB
If
IB
1A
18
1A
IB
1A
2A
o
r>
C'
D
D
D
0
C
D
D
n
D
D
D
D
C
C
n
c
c
s
c
1A
UTH
BR285454
8R220525
BR310460
VS290070
BR365945
BR216526
BR290453
BR310453
BR580440
BR620470
BR930890
8R950970
BR930690
SR950970
3R94Q390
BP950970
BR213523
BR280455
BR213523
6R280455
BR919a86
3P922970
BR218529
BR3 10460
BR573445
BR623470
3R573445
BR623470
BR995890
BR949970
CR093440
CR0914-70
CR094440
CRO88051
CR002583
BR951890
BR955976
BP.606180
BR.606030
BR927890
BR927970
BR910874
8R960874
BR939890
BR939970
3S34111 I
BR428960
BF-980240
3R990200
CR100442
�P3TP
680805
680806
630806
68J807
680807
680808
680b03
680818
6 303 IS
680818
600819
680819
630819
630819
680822
630822
680822
630822
680826
630826
630326
630826
680913
680913
630913
680916
680916
680916
630918
680918
68091S"
680919
630920
630920
680920
680920
680920
680920
680920
6SQ<?20
630920
680920
680920
680920
680920
680921
680921
680921
680921
680923
AGN
0
Q
0
0
S
8
B
GALS
0
3000
0
200
0
1750
0
2800
0
0
110
0
0
0
110
0
0
0
110
TYP
f
F
F
ie
P
F
P
P
0
0
0
0
0
W
W
W
w
w
3
B
0
'
B
5000
0
0
6000
0
0
3000
0
2400
. 0
600
0
0
1800
0
0
0
1800
0
3000
0
0
0
3000
'0
3000
0
2000
LEG
18
IA
IB
IA
2A
IA
D
IA
IP
1C
1A
IB
1C
10
1A
IB
1C
IP
IA
IB
1C
10
1A
IB
UTM
CRQ05590
65390140
8R445954
BR833060
8S876030
BQS5OOOO
BQ843G30
CR083440
CR088493
6R985587
BR476486
BR465496
BR44547Q
BP.47&48I6
8R46S496
BR45Q484
B5657000
6S657026
BS6800OQ
BS68Q026
CR08144Q
CP078494
1C
0
F
F
1A
IB
1C
1A
IB
1A
IB
P
IA
IB
P
F
C
C
n
c
1C
iA
IB
2A
28
1A
13
IA
IB
2A
28
1A
IB
1A
IB
1A
CPQ90440
CROS05GQ)
8R99059Q
BR390448
BR290454
BR580450
BR61046Q
&R48T455
BR4&4470
BR465496
BR4&0434
BF445470
8R445455
BR450450
3K290454
BS620120
BS620190
BS670220
BS720180
3S629104
BS732160
3P.3T0459
BP.279468
�MISS IONS STiRT ING IN
BINH DINH
* *#.-!=*>!; * * *
* * *
DATE
680923
680923
680923
680927
630927
630927
680927
680929
681003
681006
681006
681006
681006
681006
681009
681009
681010
681011
631011
631011
681011
681012
681012
681012
681012
681023
681023
681024
681024
681025
631025
631025
681025
681025
681025
681025
631025
681027
681027
681028
681023
681028
681029
631029
681029
631029
681030
681030
681102
631106
AGN
W
0
0
w
0
0
0
rl
0
0
0
0
8
B
0
0
0
0
0
B
0
p
W
o
w
w
w
GALS
0
0
0
9000
0
0
0
330
385
1800
0
0
0
0
330
330
330
5000
0
0
0
440
440
440
440
2000
0
3000
0
660
550
110
165
3000
0
0
0
4000
0
700
0
0
1200
0
2100
0
440
330
55
440
TYP
D
P
P
P
P
P
P
P
P
P
P
P
C
C
P
P
P
P
D
C
F
LEG
IB
2A
2B
1A
IB
2A
28
IA
1A
1A
IB
1C
ID
IE
1A
1A
1A
1A
IB
2A
2B
1A
1A
1A
1A
1A
IB
1A
IB
1A
1A
iA
1A
iA
IB
2A
26
IA
IB
1A
iB
F
F
F
c
P
F
1C
1A
13
IA
IB
IA
1A
IA
1A
UTM
BR7Q9170
6R750180
6R735070
CR031423
BR929555
BR 98349 7
CRQ18465
CR091433
'
BR880580
CR055180
CR070185
CR050115
CR038227
CR030221
CR085437
CR085437
CR080444
CP.032467
BR930055
BR980490
CR001469
BR68042Q
BR66138Q
I
8R644481
BR660383
BS731167
BS756020
fiS733l68
BS759020
8R780445
3P805355
BR702435
?P.893323
BR3 70451
BR282455
BRZ81452
3R370441
&S 72 9 16 8
BS75002D
BP348453
BR288455
BR333460
3P266470
BP-364460
RP266470
9R364460
3R383125
BR 85 798 8
BP988853
3 P 66 795 5
�UNCLASSIFIED
MISSIONS
DATF
681106
681109
681109
681109
681109
681118
STARTING
AGN
0
g
0
68U18
681118
681118
681127
631127
631127
681127
681129
681129
681129
631129
681202
681204
681205
681206
681207
681207
681207
681207
681208
681211
681211
681211
681211
681211
681211
681211
681212
681219
681219
681220
681220
681220
681220
681220
631220
631220
681230
631230
681230
681230
681230
681230
681231
0
0
0
0
w
0
0
n
B
GALS
220
55
0
0
0
2000
0
0
0
3000
0
0
0
3000
0
0
0
550
275
385
385
3000
0
0
0
550
600
0
0
0
0
0
,
0
B
0
o
5
6
IN
TYP
E
C
D
0
D
P
F
F
P
D
P
P
0:
385
3000
0
3000
0
0
3000
0
0
0
2000
0
0
0
0
0
600
PROV NO.
BINH DINH
P
C
0
D
C
F
LEG
1A
1A
IB
2A
28
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
2A
2B
IA
IA
1A
1A
1A
IB
2A
28
1A
IA
IB
1C
10
IE
IF
1G
1A
1A
IB
1A
Id
1C
1A
IB
2A
2B
1A
IB
1C
2A
2B
2C
1A
UTM
BR86-5921
BR676594
BR677505
BR715603
BR715591
8R390448
BR325446
3R283453
BR34Q45Q
8R390448
BP280460
BP282458
PR340454
BR933557
CR023610
CR0246O5
BR935555
CR024615
BR913465
BR913465
BR988594
BR369453
SR278475
8R260451
BR330456
BR901548
BR455462
BR459462
BR448455
BR445470
BR450490
BR480490
BR486450
BR876574
CR091440
CR08749S
CR.046560
CR048510
CR05846O
8R550820
BR585785
BR5807SO
BR580850
RR580350
8R58078O
3&57077J
8P53Q830
3R530ti70
BF550b70
R 931 5460
=
�OATE
681231
690101
690101
690101
690101
690102
690102
690102
690102
690102
690102
690102
690103
690103
690120
690120
690126
690126
690126
690126
690130
690130
690131
690131
690131
690131 .
690202
690202
690203
690203
690203
690203
690207
690207
690207
690207
690213
690213
690214
690214
690214
690214
690214
690214
690214
690214
690213
690218
690218
690213
4GN
B
GALS
0
4200
0
TYP
F
0
8
3
O
13
0
0
0
w
0
w
Q
vt
a
w
0
0
0
D
0
3000
0
0
0
0
0
0
3000
0
200
220
2000
0
0
0
3000
0
165
0
495
0
440
440
550
0
660
0
330
0
330
0
3000
0
3000
0
0
0
0
3000
0
0
3000
0
0
0
F
C
P
P
D
D
S
S
P
P
P
P
P
P
LEG
IB
1A
IB
2A
2B
1A
IB
1C
10
IE
IF
1G
1A
IB
1*
IA
iA
IB
2A
2B
IA
IB
U
IB
IA
IB
U
1A
1A
18
IA
IB
1A
IB
iA
C
IB
l&
0
iA
0
r<
ta
IB
1C
2A
26
IA
IB
1C
14
IB
2A
26
UTM
BR24O500
BR345450
8R325465
8P3 1.0450
8R275470
BR267468
BR274475
8^291457
BR305458
BR305454
BR291452
BR28U462
BR555860
BR555815
BR92476Q
PR92476O
BR964558
CP030499
BP966560
CR03<X501
BR961555
CRO28495
BR62747O
BR590A45
BR62747O
8R590445
BR660470
3R66O47O
8R634438
8 P6 2 7 45 3
BP634438
BR6.27,453
BR 92 4 530
BR94053O
BR 92 4 5 0
.3
BP94O530
8S353118
&R43S972
BR394393
aR3S8368
BR341320
8 R 3 4 1 2^? 3
BR317267
CR086456
C&083A59
3^9955:92
1R36O457
8R282460
BR280466
BR335456
�BINH OINH
************
TYP
LEG
GALS
1A
2500
C
IB
0
1C
0
2A
0
2B
0
2C
0
1A
3000
V
IB
0
P
1A
660
IB
0
P
1A
330
0
IB
P
1A
495
IB
0
P
1A
138
1A
P
1375
0
IB
0
1C
0
ID
0
IE
P
1A
165
IB
0
1C
0
ID
0
IE
0
1A
3000
C
0
IB
1A
3000
C
0
IB
1A
3000
D
IB
0
2A
0
0
28
P
1A
3000
IB
0
1800
F
1A
0
IB
0
1C
0
10
F
1A
800
0
IB
0
1C
0
10
P
200
1A
0
IB
0
1C
0
ID
P
1A
200
0
IB
0
1C
MISSIONS START ING IN
DATE
690218
690218
690213
690213
690218
690218
690218
690218
690220
690220
690221
690221
690221
690221
690223
690228
690223
690228
690228
690223
690228
690228
690228
690228
690228
690308
690308
(S9030<?
690309
690309
690309
690309
690309
690311
690311
690318
690316
690318
690318
690318
69031S
690318
690318
690313
690318
690318
690318
690318
690318
690318
AGN
0
0
0
0
W
0
3
0
0
0
0
0
S
W
B
*i
UTM
CP038132
CR013180
CP041133
CR016180
CP042134
CR019180
QS355159
BP424999
BR916560
BP930560
BR947565
BR930550
BR947565
BR930550
BR610410
CR038153
CR033140
CR033130
CR038122
Cr.038140
CR033153
CR033140
CP033130
CR038122
CR038140
BS340UO
BR436940
BP969562
CR 04 0 9 8
4
BR576440
BP606446
6R574442
BR619471
3R978568
CR042510
BR570455
BR570445
BR 62 047 5
BR620465
SR57O455
BR570445
SR62 0 7 5
4.
PP620.465
BR43O465
BR44547O
BR465505
3R478465
BF430465
3R4^5470
BP465505
�UNCLASSIFIED
BINH OINH
#***#*******
TYP
GALS
tea
0
10
D
3000
1A
0
IB
2A
0
0
2B
D
3000
1A
IB
0
2A
0
2B
0
n
1A
2000
IB
0
0
1C
p
275
IA
2A
0
0
3A
4A
0
5A
0
0
6A
p
1A
110
0
2A
0
3A
0
4A
3000
c
1A
0
IB
r
1A
275
IB
0
2750
t
1A
IB
0
0
2A
0
28
C
1A
3000
0
18
0
1C
1A
3000
D
0
IB
c
3000
IA
0
IB
0
1C
970
s
1A
0
IB
0
1C
0
10
0
IE
0
IF
0
1G
0
1H
p
550
1A
0
IB
0
1C
2600
D
1A
i^ISSIPMS START ING IN
OtTF
690318
690319
690319
690319
690319
690321
690321
690321
690321
690322
690322
690322
690324
690324
690324
690324
690324
690324
690324
690324
690324
690324
690324
690324
690327
690327
690329
690329
690329
690329
690329
690329
690329
690401
690401
690402
690402
690402
690412
690412
690412
690412
690412
690412
690412
693412
690412
690412
690412
690415
AGN
0
W
W
0
W
W
0
B
W
H
W
0
B
0
PROV NO. =
UTM
BP478465
BR96O570
CR048510
Bf 98 1571
CR051510
BR957553
CRQ27490
8R955551
CR023490
CR 08 9450
CRG34496
CRO00590
BR913745
BR906748
8R91175S
BR919757
BR926760
BR934755
BR932722
8R937744
BP-934740
8R924742
BS388139
BR444942
BR620300
BR620310
CR070190
CR060185
CR045220
CR054224
BS372125
BS440010
BR465950
BR973565
CP 04 050 6
BS352118
3R430980
BR450930
BR452477
BR459477
BP46O466
BR456463
8R445465
BR436467
3R445470
BR447473
BR450485
8R475490
BR488451
BP990570
�DAT?
690415
690415
690415
690416
690416
690416
690416
690422
690422
690422
690422
690423
690423
690423
690426
690426
690426
690426
690426
690426
690426
690426
690426
690426
690426
690426
690426
690426
690426
690426
690427
690427
690428
690428
690430
690430
690430
690430
690430
690502
690502
690502
690502
690502
690502
690505
690505
690514
690514
690514
AGN
0
GALS
0
0
0
3000
0
0
TYP
D
0
W
0
W
'A
B
8
0
0
W
0
1650
0
275
0
330
0
495
350
0
0
0
0
0
0
0
350
0
0
0
0
0
0
0
275
0
2000
0
3825
0
0
0
0
2000
a
W
0
0
0
0
0
2000
0
55
0
0
P
P
c
P
P
P
C
0
P
0
C
r
LEG
IB
2A
2B
1A
IB
2A
28
1A
2A
1A
2A
1A
2A
1A
1A
IB
1C
10
IE
IP
1G
1H
1A
IB
1C
10
IE
IF
1G
1H
IA
IB
IA
IB
1A
IB
1C
10
IE
1A
IB
1C
2A
2B
2C
1A
IB
1A
18
1C
UTM
CR045520
8P96Q545
CR02J.49O
SR843O49
BR849O10
80360991
B0666965
3R780350 .
BS 7 90340
BR78Q350
BR790340
8Q900895
BC893-910
BQ950762
BR929747 .
BR930745
8R931743
BR932740
BR930733
8P525740
9P924742
BR925745
8R929747 .
BR930745
BP9317-43
BP932740
3R930736
BR925740
BR924742
BR925745
BR6203OO
8R620310
CR046180
CR072127
8R448455
3P.445470
BR45O490
8R480490
3P486450
CR068127
CR042180
CR056147
CR039180
CR053146
CP036180
BS356113
8R440950
8S750015
BS750025
BS754025
�. . : - • > K^GAI o
o
•j
0
0
1.?*
1C
o
to
5>5
nr
IA
O
10
0
•J
55
i
K
0
0
1A
IB
iC
t*
(-.',051-'i
0
0
in
-)y
i*
0
riu
o
o
'• i! — '•- I J: i
CK'>'-:*i,i
ti
0
•5
0
1'. *
o
^^
• o
IB
0
iC
o
0
0
J
n
o
55
0
1-4
1J*
^' f ! ! l .V
3B
P '• H f< S t
«
�DATE
690522
690522
690522
690522
690522
690522
690522
690522
690522
690522
690522
690522
690524
690524
690524
690524
690525
690525
690525
690525
690526
690526
690526 <
690526
690526
690526
690526
690526
690602
690602
690602
690602
690602
690602
690602
690602
690602
690602
690602
690602
690602
690602
690602
690606
690606
690606
690606
690606
690606
690606
AGM
0
0
0
n
0
0
W
g
GALS
0
0
55
0
0
0
0
0
0
0
0
0
440
0
0
0
825
0
0
0
990
0
0
0
2000
0
2000
0
600
0
0
0
0
40
0
TYP
c
IB
P
P
F
D
n
p
,
c
6
B
0
B
0
0
15
0
55
0
0
0
550
0
0
, 0
0
550
0
L£G
3C
30
It
c
c
p
p
2A
2B
2C
2D
3A
3B
3C
30
16
2A
3.A
4A
1A
2A
3A
4A
1A
2A
3A
4A
1A
IB
1A
IB
1A
IB
1C
ID
IE
1A
2A
3A
4A
1A
2A
1A
2A
3A
4A
14
2A
3A
4A
5A
IA
2A
UTM
BS739183
BS738178
BS742210
BS744215
BS745205
3S745200
SS750200
BS750215
3S735179
BS735185
8S739183
BS738178
BR6 18404
SP617398
BP640400
BR642395
BR604409
BR612416
BR620407
BR619397
BR620407
BR619397
BR640403
8R643395
CR050144
CR034180
CR050144
CR034180
BR448455
BR445470
BR450490
3R480490
BR48 64-50
BS760023
BS759029
BS76203O
BS763042
BS75203U
BS750040
BS764030
BS766038
BS76803S
BS766030
8R960230
B P. 93823 7
BF.935245
BP947257
BR956251
BP960230
BR938237
•,
'
�DATE
690606
600
966
690606
690608
690608
69060S
690608
690608
690608
690608
690608
69060E*
690608
690608
690608
690611
690611
690615
690615
690615
690615
690615
690615
690615
601
965
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
601
96?
690615
690615
690621
6906Z1
690621
690621
690621
690628
690626
690628
AGN
B
0
W
B
3
n
BINH DINH
************
LEG
GALS
TYP
3A
0
4A
0
5A
0
1A
55
C
2A
0
3A
0
4A
0
5A
0
6i
0
1A
55
C
2A
0
3A
0
4A
0
5A
0
6A
0
1A
275
F
18
0
1A
110
C
IB
0
1C
0
ID
0
2A
0
2B
0
2C
0
3A
0
36
0
3C
0
30
0
4A
0
4B
0
4C
0
4D
0
5A
0
5B
0
5C
0
50
0
5E
0
5F
0
6A
0
6B
0
0
6C
6D
0
U
100
P
0
2A
3A
0
4A
0
5A
0
1A
10
90
C
IB
0
0
1C
PROV NO. =
MISSIONS START ING IN
UTM
BR935245
BR947257
BP956251
BS715205
BS717223
BS723265
BS720217
BS723214
BS722220
BS716228
BS712224
BS715220
BS714217
BS718214
BS713205
BP368460
BR300455
BS618184
BS618192
BS621192
BS621184
BS676211
BS678214
BS677210
BS681202
BS681204
BS685204
. BS685202
8 $73 1 6
00
8S73206&
BS734O68
SS733060
BS725050
BST2S056
B 573 005 8
BS730056
BS728055
BS728050
3S73O050
BS733050
BS733052
3 S 73 005 2
BR754937
BP.751C41
BS751947
BR755945
BP.756941
CPQA5137
CR0171B9
CR04219S
7
�UNCLASSIFIED
MISSIONS
DUE;
690623
690628
690628
690623
69062S
690630
690630
690630
690630
690630
690630
690630
690630
690702
690702
6C-0702
690702
690704
6T0704
690704
690704
690704
690704
690704
690704
690704
690704
690706
690706
690706
690706
690706
690706
690706
690706
690706
690706
690706
690706
690706
690706
690707
6?0707
690707
690707
690707
690707
69070S '
690708
690708
S T A R T I N G IN
AGN
Q
Q
GALS
0
0
0
2600
0
3000
0
0
0
BINH OINH
TYP
D
D
0
0
0
0
0
0
2700
0
0
0
1600
0
0
0
0
D
D
0
0
0
3
n
0
0
2800
0
0
0
3000
0
0
0
0
0
0
0
2600
0
0
0
0
0
800
0
0
1500
0
,0
3000
0
0
D
D
D
D
D
C
PROV NO.
LEG
10
2A
2B
1A
IB
14
IS
1C
10
2A
28
2C
20
1A
IB
2A
28
IA
IB
1C
24
2B
2C
1A
IB
1C
ID
1A
IB
2A
2B
3A
3B
4A
4B
1A
IB
2A
28
3A
3B
1A
13
1C
1A
IB
1C
1A
IB
2A
UTM
CR056168
CR046139
CR019190
BP-832040
BQ851961
CR057145
CR03M94
CR04920Q
CR059184
CR053148
CR029193
CR046199
CR05<3182
QP814135
BR799050
BR816134
3R801050
CR051146
CR028193
CR038196
CR055164
CR049144
CR025191
BR837042
BQ856964
BR840042
BC858965
CP053157
CR034195
CR054159
CR036196
CR044198
CR057173
CR046199
CR058177
BR370460
BP.353451
BR325463
BR300454
BR285455
B&277470
BR540466
BP 58045 7
BR617473
BR697520
3R704483
8R748458
CR020126
3R992181
CR023128
=
�MISSIONS STARTING IN
BINH DINH
T-l-T
D4TF
690703
690708
690703
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690715
690715
690715
690715
690715
690715
690715
690715
690715
690715
690715
690715
690716
690716
690716
690716
690718
690718
690720
690720
690720
690720
690721
690721
690721
690721
690722
690722
ASN
B
B
e
8
0
0
0
0
0
0
0
GALS
0
0
0
15
0
0
0
50
0
0
0
0
0
0
10
0
0
0
35
0
0
0
1500
0
0
0
0
0
1500
0
0
0
0
0
200Q
0
0
0
3000
0
6000
0
0
0
3000
0
0
0
2200
0
TYP
c
C
c
c
F.
p
n
D
D
c
c
LEG
28
34
38
1A
2A
3A
4A
1A
2A
3A
4A
5A
6A
7A
1A
2A
3A
4A
1A
2A
3A
4A
1A
18
2A
2B
3A
3B
IA
18
2A
2B
3A
38
JA
IB
2A
28
1A
18
1A
18
2A
2B
1A
IB
1C
10
1A
18
UTM
BR998182
CRQ25129
CROG0133
BF.64O926
BF642726
BP.640729
6F.642929
8R633763
BR635956
BR63876O
6R640964
BR638966
BR634967
BR633965
BR638943
3R6389A6
8P64054fc
BR640946
BF 63 493 9
BP640930
BP640933
BR 63 593 3
CR043135
CR015188
CP042134
CR014188
CR042133
CRQ14188
BR576442
&R619468
BR577440
BR622465
BR578433
BP.623463
CR001079
CR001170
BR999079
BR99917O
BR388370
BR322275
BS724150
BS742050
6S74705O
BS747150
BS759150
BS759050
3S732050
BS732150
CR055148
CF 09 511 3
�DATr
690722
690722
690722
690722
690725
690725
690725
690725
690801
690801
690801
690801
690801
690801
690802
690802
690802
690802
690802
690802
690802
690804
690804
690804
690804
690804
690804
690804
690804
690804
690804
690806
690806
690807
690807
690807
690807
690810
690810
690810
690810
690810
690810
690810
690811
690811
690811
690811
690811
690811
AGN
GALS
0
0
TYP
0
0
0
W
8
B
B
0
0
0
B
B
0
0
5000
0
0
0
605
0
0
0
1155
0
330
0
0
0
0
0
0
100
0
0
0
0
0
10
0
0
0
550
220
165
0
0
0
1500
0
0
0
3000
0
0
1210
0
0
0
0
0
P
P
P
P
C .
C
C
C
C
C
C
C
LEG
1C
ID
2A
28
1A
IB
2A
2B
1A
2A
3A
4A
1A
2A
1A
2A
3A
4A
5A
64
7A
1A
2A
3A
4A
5A
6A
1A
2A
3A
4A
1A
1A
1A
2A
3A
4A
1A
IB
1C
ID
1A
IB
1C
1A
2A
3A
4A
5A
6A
UTM
CR053154
CP095123
CR058153
CROS4127
BS752150
BS752050
8S737050
8S737150
RR629459
BR618429
8R630420
BR638425
BR628430
BP634437
BR980243
BR980245
3R990241
BR989246
BR988247
BR984247
3R984246
BR676195
BR672200 |
8R672207
8R675210
BR675207
BR755099
BR754O92
BR754100
BR755090
BR685360
BR620330
3F627440
BR637434
BR6344-47
3R641445
BR27O840
BR320770
BR320730
3R400690
BR260700
BR270770
BR31Q830
BR724527
BR727526
BF726523
BP731527
BR732524
RR728520
�UNCLASSIFIED
M I S S I O N S STARTING IN
IG
3IW OINH
PROV MO.
k^c
a^^a^^Jj:*****^
DATE
690611
690811
690811
690811
690811
690811
690811
690811
690311
690811
690811
690811
690811
690811
690811
690811
690811
690811
690811
690815
690815
690815
690815
690815
690815
690815
690815
690815
690815
690815
690815
690815
690815
690815
690815
690815
690815
690815
690815
690315
690815
690815
690824
690824
690824
690824
690824
6°0824
690824
690824
AGN
GALS
TYP
0
0
0
220
0
0
0
2000
0
0
0
2000
0
0
0
0
0
0
0
10
0
0
0
35
0
0
0
10
0
0
0
35
0
0
0
15
0
0
10
C
C
c
c
c
c
c
c
c
0
0
0
150
0
0
0
100
0
0
0
c
c
LEG
7A
8A
SA
1A
2A
3A
4A
1A
IB
1C
10
1A
IB
1C
10
2A
28
2C
20
1A
2A
3A
4A
1A
2A
3A
4A
IA
2A
3A
4A
IA
2A
3A
4A
1A
2A
3A
1A
2A
3A
4A
1A
2A
3A
4A
1A
2A
3A
4A
UTM
8R731S24
BR735518
BR 736524
BR739522
BR748524
BP751529
8R749533
8 R2 70960
BR290830
6P320860
8R310790
BR4.25685
8R440750
BR410750
BR400680
BR30O69O
8R290770
BR3 10790
BR31084Q
S 5 , , 2 10
689
BS691211
BS687216
BS689218
3S681234
8S682226
BS 68 523 5
BS686226
BS662236
8S666235
BS663238
BS665238
BS651194
BS654196
BS648205
3 S6 5 2 20 6
3S&37145
BS640137
BS639144
3S618162
BS618164
BS622161
6S622164
BS911099
3S915098
9S919090
BS904094
BS911099
3S915098
BS919090
3S904094
�DtTF
690824
690824
690824
690824
69J827
690827
690829
690829
690829
690829
690830
&90830
690830
690830
690830
690830
690830
690903
690903
690903
690903
690905
690905
690905
690905
690905
690905
690905
690905
690905
690905
690905
690905
690905
AGN
'0
690906
690906
690906
690906
690914
690914
690915
690915
690915
691018
69 10 If
69101P
691013
691018
691018
691010
0
P
0
0
0
0
B
0
0
0
GALS
50
0
0
0
3000
0
1700
0
0
0
475
0
0
0
0
0
0
1650
0
0
0
2915
0
0
0
0
0
130
•
o
0
0
0
0
0
715
0
0
0
3000
0
275
0
0
3000
0
0
TYP
C
D
r-
p
p
p
c
p
D
P
C
•o
0
3000
0
0
C
LEG
1A
2A
3A I
4A
1A
IB
1A
IB
2A
28
1A
2A
3A
43
5A
6A
7A
IA
2A
3A
4A
IA
2A
3A
4A
5A
6A
1A
2A
34
3B
3C
4A
5A
1A
2A
3A
4A
1A
IB
1A
2A
3A
14
IB
2A
28
UTM
BS908114
BS908119
BS913117
BS912H4
BR394363
8R325270
CP043134
CR013188
CR035132
CR006186
BR980243
BR930245
BR990241
BR989246
BR988247
BR984247
8F.984246
BP922242
BR927236
BR946256
BR941262
BR979243
BR98422O
BR98120O
BR991200
BR999215
BR992247
3S698156
BS699148
BS678164
BS700164
BS700158
BS697166
BS670150
BR932222
BR943206
BR95O210
BR937227
BR894O17
BR958178
BP840301
BR850305
BR85U90
BF48096O
1A
IB
3R555.B73
3R480970
BR570,fcf7G
BR263700
BR268770
1C
fl?330t>70
J
�Df-TE
691013
691013
691018
691024
691024
691024
691024
691024
691024
691026
691026
691026
691026
691026
691026
691026
691026
691031
691031
691031
691031
691109
691109
69110V
691109
691109
691109
691109
691109
691112
691112
691112
691112
691114
691114
691114
691114
691114
691121
691121
691121
691121
691130
691201
691201
691203
691205
691205
691205
691205
AGN
R
0
0
R
B
R
B
3
B
B
B
3
B
B
B
0
3
0
0
0
GALS
0
0
0
380
0
0
0
0
0
2600
0
0
0
3000
0
0
0
3700
0
0
0
25
40
30
45
50
50
40
50
3000
0
0
0
3000
0
0
0
0
3000
0
0
0
825
50
460
825
425
0
0
0
TYP
P
C
C
C
C
C
C
C
C
C
C
C
C
C
C
P
P
P
F
P
LEG
2A
28
2C
1A
2A
3A
4A
5A
6A
1A
IB
1C
ID
1A
IB
1C
ID
1A
IB
1C
ID
1A
1A
1A
1A
1A
1A
1A
1A
1A
IB
1C
ID
1A
IB
1C
2A
2B
1A
IB
1C
ID
1A
1A
1A
1A
1A
IB
1C
10
UTM
8P300810
8R410670
BP350710
BS744140
BS741137
8S742130
8S746127
8S749130
BS748136
BR350740
BP410740
BR410690
BR360690
BR300B20
BR3 00910
BR330910
8R330S20
BR350740
BR410740
BR360090
BP410690
BR470150
BR480160
BR500140
BR490130
8R510130
BR520120
BR530130
BR540120
BR260630
BR370630
BP.260830
BR200S30
BP250860
SR300930
8S210020
BR170960
BR250860
8R350900
BP350930
BR210980
B»210900
8R577444
3S800140
BS800140
BR576437
BR980243
BP990245
BR988247
BR984246
'••
(
�PATE
691206
691206
691206
691206
691223
691223
700111
700113
700113
700203
700203
700203
700203
700204
700204
700204
700204
700205
700205
700205
700205
700207
700207
700207
700207
700215
700215
700225
700226
700226
700226
700226
700226
730226
700226
700226
700226
700226
700226
700226
700226
700226
700227
700227
700227
700227
700227
700227
700227
700227
AGN
0
0
n
0
n
0
g
3
n
0
o
0
w
a
0
0
GALS
1430
165
165
165
550
550
1320
990
0
20
0
0
0
825
0
0
0
1100
0
0
0
660
0
0
0
110
0
105
95
0
0
0
0
0
0
0
70
TYP
P
P
P
P
F
P
P
P
£
P
P
P
'
P
C
C
c
0
n
0
0
0
0
55
0
0
0
0
0
55
0
0
c
c
LFG
1A
1A
1A
1A
1A
1A
1A
IA
2A
IA
2A
3A
4A
1A
2A
3A
4A
1A
2A
3A
4ft
1A
2A
3A
4A
1A
IB
1A
IA
2A
3A
4-A
5A
6A
7A
8A
1A
2A
3A
4A
5A
6A
1A
2A
3A
4A
5A
1A
2A
3A
UTM
6R6Q6451
8R 59 844 3
BR619464
BR612453
BR931209
BR942215
BP 840580
BR939224
BR931210
SR800857
BP8O6859
BR812B52
BR809349
BR659385
BR6643U6
8 P 66 6 37 9
6R662378
6R935230
BR943230
3F 93 523 8
BR943238
BR647486
BR653483
6P649480
BR646485
BR4T0640
8R47O76O
BS720120
BR52094Q
BR 53 0980
8R500980
BR50095Q
3P510960
BP 5.2 0970
BP.54G98O
BR550550
BF520940
BR560970
BR490OOO
BS500020
BS490000
BS460000
BR490960
BR500950
BR560970
BR540980
BR530970
BR540970
BR570890
3R510940
�OAT^
700227
700227
700312
700312
700312
700312
700315
700315
700315
700315
700315
700315
700315
700315
700315
700315
700315
700315
700315
700321
700321
700321
700321
700324
700324
700324
700324
700325
700325
700325
700325
700326
700326
700409
700409
700409
700409
700409
700409
700411
700411
700411
700411
700411
700411
700411
700411
700416
700416
700416
AGN
0
B
B
'
W
0
0
0
0
0
3
GALS
0
0
330
0
0
0
1700
0
0
0
1900
0
0
0
0
0
0
0
0
275
0
0
0
165
0
0
0
110
0
0
0
60
0
50
9
0
0
0
.0
100
0
0
0
0
0
0
'0
'
50
0
0
TYP
P
C
C
P
P
P
C
C
C
C
LEG
4A
5A
1A
2A
3A
4A
IA
IB
2A
2B
1A
IB
1C
ID
IE
IF
1G
1H
11
1A
2A
3A
4A
1A
2A
3A
4A
1A
2A
3A
4A
iA
IB
IA
2A
3A
4A
5A
6A
IA
2A
3A
4A
5A
6A
7A
84
1A
2A
3A
UTM
BR520930
3R510980
8P.930220
BS936226
BR949209
BP940202
B R6000 10
BF.60020Q
8R66003Q
8R660130
3R479383
3R480340
BR540300
BR550270
BR530240
8R490240
BR510200
BP490090
BP.420100
BP930220
BR936226
BR949209
BR940202
8P932202
BR939228
BR953216
BR9482J.O
BR932202
SR939228
BR953216
BR948210
8S710097
BS718O93
BP580700
fJR600700
BR590750
3P580770
BP, 560780
?P550790
3R550»00
BR590770
BP.580790
BR600800
BP580840
8R4808,60
BR470890
BR460900
8F.500900
3P590740
3R 5^0740
3 -'"I
�UNCLASSIFIED
M I S S I O N S STfiRTING IN
DAT^
700416
700416
700416
700416
700416
700418
700413
700501
700501
700501
700501
700501
700501
700501
700502
7C0502
700502
700502
700611
700611
700612
700613
700620
700620
700620
700620
700626
700626
700627
700627
700808
700824
70090G
700911
700912
700912
700912
700912
700915
700915
700915
700915
700925
700925
700925
700925
700927
7C0927
700927
700927
AGN
0
W
GALS
0
0
0
0
0
150
0
150
0
0
0
0
0
TYP
0
'
0
0
'
0
0
0
n
B
3
B
B
3
w
6
B
R
180
0
0
0
275
0
110
165
160
0
0
0
55
55
165
110
1210
220
385
165
1800
0
0
0
2500
0
0
0
2700
0
0
0
1600
0
0
0
L =G
4A
5A
6A
7A
aA
C
C
0
W
PROV NO. =
8INH OINH
C
p
p
p
c
p
p
p
p
p
p
p
p
c.
c
r
c
IA
2A
1A
2A
3A
4A
5A
6A
7A
1A
2A
3A
4A
1A
2A
1A
1A
1A
2A
3A
4A
1A
1A
1A
IA
1A
IA
1A
1A
IA
IB
2A
2B
1A
IB
1C
10
1A
IB
1C
ID
1A
IB
1C
10
UTM
3R570750
8P58072Q
BR50088Q
BS42GQ20
8S410Q30
BR58a859
3R478970
BS49OOQO
BR500970
6R510970
BR52096Q
BS520950
BS530950
BS53O940
BR53095O
BR520950
BR52O960
6R530960
BR564439
8R631430
BR564439
BP631430
BS694074
BS702O78
BS 70 507 5
BS698069
3 R 56 44 3*3
SR631430
BR564439
BR631430
BR93026Q
BP 59 045 5
8R930260
8P809365
BR&0.5UO
BR602210
8R477160
&R380280
BR570863
BP 5 10944
BR490958
3 S4 1603 3
BP520030
BP.520220
BR 5 5,0 030
BR520030
BR510640
3R610340
S&620580
BF 590610
7
�UNCLASSIFIED
M I S S I O N S S T A R T I N G IN
DATE
700927
701010
701010
701010
701010
701010
701012
701012
701012
701012
701012
701219
701219
701219
701219
710128
710128
710128
71012S
AGN
GALS
0
B
2700
0
0
0
0
3
B
R
B
B
3
B
3
R
2500
0
0
0
0
45
25
25
25
25
25
25
25
BINH OINH
******
TYP
LF.G
IE
1A
C
IB
1C
ID
IF
1A
C
IB
1C
10
IF.
1A
S
S
1A
$
1A
1A
s
1A
s
1A
s
1A
s
s
1A
PROV NO. =
UTM
BR510840
BR470150
5R340240
8P3C0280
BR480180
BR470150
BR520030
BR550030
BR590020
BP520200
BR520030
3R590440
BP.596438
8P619458
8P612465
8 R 59 0 4
4 6
BP59643S
BR619458
BR612415
�C= 16?71
NREC= 16771
:!PPOV=
MPROV=
441
441
NZREC=
NZREC=
928
928
UMCLASSIFMO
L)MCLASS!P!-:-D
�DATE
651014
651014
651.106
651113
651113
651114
651114
651117
651121
651130
660124
660124
660125
660125
660126
660126
660126
660126
660203
660203
660206
660206
660206
660206
660222
660222
660222
660222
660223
660223
660417
660417
660417
660417
660419
660419
660419
660419
660419
660419
660419
660419
660419
660420
660420
660420
660421
660421
660424
660424
AGN
0
0
0
GALS
2000
0
1000
2000
TYP
0
D
D
LEG
1A
13
1A
1A
P
IB
1A
0
0
0
0
0
0
p
0
0
0
B
B
0
0
0
•J
0
r>
2000
0
1000
2000
1800
6000
0
3000
0
2000
0
0
0
3000
0
3000
0
0
0
20OO
0
0
0
3000
0
2000
0
0
0
2000
0
0
0
3000
0
0
0
0
2000
0
0
3000
0
2000
0
D
C
D
D
0
D
D
P
0
D
0
D
0
D
D
IB
1A
1A
1A
1A
IB
1A
IB
1A
18
2A
2B
1A
IB
IA
IB
1C
10
1A
IB
1C
10
1A
IB
1A
IB
1C
ID
1A
18
1C
10
1A
IB
1C
ID
IE
1A
IB
1C
1A
IB
0
1A
13
UTM
BR22G520
8P.389447
YA84Q245
SP22O52Q
BR3Q0455
BK22O520
8F30O*55
YA84O250
YA84025O
YA84O250
YA89OO30
YV92Q96O
YV92Q980
YA880UOO
YV9 15960
YV9 15980
YA90001O
YA895O25
YV 38 0 9 5
9
YV92Q96O
W92Q960
YA92002Q
YA880O30
was 0960
YA377O35
YV881992
YV872982
YV8.62985
YA880O40
YV940970
YA855554
YA859556
YA855524
YA864517
YAS56555
YA872555
YA865516
YA348521
3R215515
BR225495
BR160515
BR075545
&R085570
8R195'326
3R247489
3R195593
YA875553
YA870492
YA876r>00
YA876573
�MISSIONS START ING IN
DATF
660425
660425
660426
660426
660426
660426
660501
660501
660501
660501
660506
660506
660506
660506
660508
660508
660515
560515
660515
660515
660525
660525
660525
660525
660530
660530
663530
660530
660530
660621
660621
660621
660621
670420
670420
670421
670421
670422
670422
670429
670429
670506
670506
670508
670508
670508
670508
670509
670509
67050<r
4GN
0
n
n
n
i_*
0
0
0
GALS
2000
0
2000
0
0
0
1000
0
0
0
4000
0
0
0
3000
0
3000
0
0
0
1000
PLSIK.U
************
TYP
L 5G
1A
D
IB
1A
D
18
2A
28
p.
1A
IB
2A
20
1A
D
IB
1C
10
1A
D
IB
r
D
Q
0
0
0
a
0
0
0
ri
w
W
0
0
2000
0
0
0
0
2000
0
0
0
2790
0
1860
0
1860
0
2550
0
1500
0
2790
0
2790
'•0
1860
D
C
D
D
r
n
D
0
r
!?
0
*
1860
p
1A
IB
1C
10
1A
IB
1C
10
1A
IB
1C
ID
IE
1A
IB
2A
26
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
UTH
YA882508
YA882579
BR160513
BR075545
BR075547
SR085570
YA897505
YA897580
YA893505
YA893580
ZA155070
ZA175069
ZA168037
ZA153038
YA891505
YA891583
ZA153070
ZA1 50030
ZA188043
ZA190075
ZA140033
ZA164037
ZA190072
ZA190045
ZA140O70
ZA135032
ZA171Q38
ZA163075
Z6162063
YA860560
YA887543
ZA145039
ZA189050
BR170480
BR140400
YA750500
YA800460
BR150480
BR 140400
BR130490
BR130400
BP 11 0490
3R080400
YA730443
YA730270
YA699437
YA699273
YA710438
YA710262
Y4717269
'
}
�OiTH
670509
670511
670511
670512
670512
670512
670512
670515
670515
670515
670515
670516
670516
670517
670517
670517
670517
670517
670517
670524
670524
670524
670524
670613
670613
670715
670715
670715
670715
670716
670716
670912
670912
671006
671006
671007
671007
671024
671024
671024
671024
671027
671027
671103
671103
671105
671105
671106
671106
671100
AGN
W
W
GALS
0
3720
0
TYP
C
C
1860
0
vV
0
Q
W
w
vJ
W
1860
0
2760
0
2590
0
2790
0
2660
0
2250
0
0
0
1900
D
r
r.
D
D
D
D
0
0
o
w
0
w
a
n
0
w
w
w
w
•fi
0
1950
D
0
1860
0
2000
0
2700
0
2600
0
1500
0
2000
0
3000
0
3800
3
0
0
2900
0
3750
0
4000
''0
4000
0
2650
C
C
n
D
p
c
D
C-
P
D
D
C
D
LEG
IB
1A
IB
1A
IB
1A
13
1A
18
1A
IB
1A
IB
1A
IS
1A
IB
2A
2B
IA
IB
1A
IB
1A
IB
1A
IB
1A
IB
I*
IB
1A
18
1A
IB
1A
IB
1A
IB
2A
26
1A
IB
1A
IB
14
18
1A
IB
1A
UTM
YA817131
YA72Q433
Y A 72 026 4
YA690436
YA690257
YA797123
YA685265
3R125490
6RG9540CI
YA75Q500
YA790460
YA697268
YA80312T
YA980473
ZAO59493
ZAO21587
YA959587
ZA023584
YA957584
BR160430
8R 14.0400
BP-160480
BR14Q40O
YA710440
YA710280
Y A 70 143 7
YA701270
SR130470
8FU40520
Zfe023582
YA9525S2
8P-14540O
8R 140280
3R135464
8R117280
BR137463
BR1 19280
YA686263
Y A 76 02 10
YA762213
Y* 799108
YA725433
YA725267
YA713437
YA713274
YV882960
YV874790
YV864941
YV873763
Yf 718433
1
�UNCLASSIFIED
MISSIONS START IMG IN
DATE
671108
671115
671115
671117
671117
671113
6711 IS
671120
671120
671121
671121
671126
671126
671129
671129
671204
671204
671207
671207
671203
67120S
671209
671209
671210
671210
671212
671212
671219
671219
671219
671227
671227
680111
680111
680114
680114
630116
680116
680118
680118
680118
680118
680122
630122
680124
680124
680126
680126
680127
630127
AGN
H
0
0
0
0
0
0
W
W
W
W
0
W
W
0
W
'it
W
4
0
0
H
0
W
P R O V NO. =
PLEIKU
**&&&&&:f:&4L **
GALS
0
4000
0
3000
0
3400
0
2150
0
4000
0
3000
0
3000
0
2600
0
3000
0
3000
0
3000
0
3000
0
2700
0
2000
0
0
2600
0
3000
0
3000
0
"6000
0
850
0
5000
0
7900
0
7970
0
7650
0
4000
'
0
TYP
0
0
D
D
r
0
D
r
D
D
D
D
D
D
D
.D
0
V
0
0
n
D
LEG
IB
IA
16
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
IA
IB
1A
IB
1A
18
IA
18
IA
18
1A
IB
iA
IB
IA
IB
1C
IA
IS
IA
IB
1A
IB
IA
IB
1A
13
IA
is
1A
IB
IA
18
n
p
1A
IB
IA
IB
UTM
YA718265
YA693436
YA693260
YA927000
YV933847
ZA021580
ZA049508
YA938080
"
YV955967
YA717438
YA715274
YV912960
YV913740
YV928964
YV927792
Yft69 843 7
YA705260
YA704438
YA7Q7269
YA924000
YV924810
YA728440
YA728275
I
YV9H980
YV912820
YA731439
YA729269
YA694214
YA766219
VA805140
BP091429
BR091230
YA939O80
/
YV939898
YV928950
YA350073
YV900978
YV9s01810
Y A 92 8 00 3
YV932830
Y* 9.2 8003
YV932830
YA9350tiO
YV935917
YA913003
YV916830
VV931993
YA848068
YV935960
Y.*935014
8
�UNCLASSIFIED
PROV
PLf !KU
MISSIONS STARTING IN
* *
•
DATE
6C0127
680204
630204
630204
630204
680206
630206
680317
680317
680320
630320
680323
630323
680422
680422
680424
680424
680503
680503
630507
680507
680519
680519
680519
680528
63052S
680606
680606
630614
680614
680617
630617
680718
680716
68071S
680816
630817
680817
680617
680817
680820
630820
680820
630820
6dOS2f!
680823
680823
680828
630828
630912
4GN
n
v;
n
w
w
o
w
w
W
GALS
0
1COO
0
6000
0
4750
0
6000
0
6000
0
4700
0
3000
0
6000
0
60GO
TYP
n
R
D
c
D
C
D
P
D
0
Q
W
W
w
w
w
W
B
W
W
•fl
W
w
w
6000
0
2700
0
0
6000
0
5000
0
3000
0
6000
0
3000
0
0
330
440
0
0
0
275
0
0
0
110
220
0
55
0
130
C
P
D
n
c
D
p
p
p
p
p
s
• p
p
LEG
1C
1A
IB
1A
IB
1A
IB
1A
16
1A
16
1A
IB
IA
IB
1A
18
1A
IB
IA
IB
IA
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
1A
IB
1C
ID
IA
18
1C
ID
1A
1A
1R
1A
IP
1A
UTM
YA354072
YA931026
YA869071
YA931026
YA931026
YA367057
YA803198
YA922004
YV922840
YA905014
YV905834
YA899010
YV899840
YA90101Q
YV901850
YA725440
YA728268
YA710270
YA814143
YA893020
YV893835
YA708268
YA773222
YA810128
YA707438
YA730270
YA715438
YA715270
YA695436
YA695280
YA885003
YV875820
YA910013
YA861047
YA&14138
AP783508
AR794464
AR800477
AP812477
AF8044&3
AP.793513
AR805506
AR802504
AR7S1510
BP039539
BF162523
BR174526
4R785356
AR785345
4P813352
NO.
�UNCLASSIFIED
PRQV NO.
MISSIONS STARTING IN
DATP
680912
630916
'630916
680917
690917
680917
630917
630919
630919
630919
630919
630919
680919
680919
630919
680919630921
630921
630923
600925
680925
680925
630925
630925
680925
630925
680925
630925
680925
680925
6.80 9 2 "5
630925
680925
680925
680927
681003
631004
681004
631005
631005
, 681005
631011
681011
631011
631011
631018
631018
681018
631018
631018
A ON
B
B
'
4
B
3
3
S
W
w
B
W
fj
W
W
•ft
w
fj
B
3
i-J
W
GALS
0
1700
0
100
0
350
0
80
0
110
60
0
110
0
55
0
1200
0
110
100
0
50
80
0
0
0
40
0
0
0
40
0
0
0
550
100
1000
0
1200
0
0
220
0
0
0
440
0
0
0
0
TYP
C
s
s
p
C
F
P
P
5
P
P
P
P
LEG
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
1A
IB
1A
IB
IA
IB
1A
IB
IA
IA
IB
1A
1A
IB
1C
P
P
S
S
p
p
p
p
ID
1A
IB
2A
2B
1A
16
2A
28
1A
1A
IA
IP
IA
IB
1C
IA
IB
2A
28
1A
IB
1C
ID
IE
UTH
AP813360
BP.2Q0528
3P2 80469
AR93G497
RR095551
AF.93O497
BR095551
AP,79Gi36i>
AR79O340
BR130270
3R 060540
BP I 00550
AR738517
APT/40517
AR74O517
AP742<517
8R254475
8P243482
ZA27010O
AP.762517
AR765517
AP.721461
A P 78 1 48 3
AR783483
8R783485
BR7814.64
AP.783491
AR787491
AR787494
AR783494
AR803503
AR606503
A.C806506
4R804506
YA980140
AR907268
AR790360
SR790340
AR79Q34Q
A R8 13 340
AR813360
ZA230-470
ZA232470
ZA232460
ZA230460
ZA223532
ZA223540
ZA233536
ZA234530
ZA227523
�DAT?
631023
631023
681023
631023
681023
681023
631023
631023
631023
681023
631023
631023
631024
681023
6S1029
631030
631101
631101
681101
631101
6811J1
631101
681101
681 101
631101
631102
631102
681104
631104
6311J6
631109
681109
631139
681109
631123
681124
681125
631125
681125
681125
681125
681125
631126
681201
631212
681212
681212
681212
690110
690110
AGN
W
W
W
GALS
110
0
0
0
220
0
0
0
110
.
W
W
W
W
W
ri
W
B
14
W
M
W
0
W
W
B
W
U
W
,-J
TYP
p
p
p
0
0
0
100
100
100
100
100
100
150
3000
0
0
0
0
0
100
100
950
0
200
5000
0
0
0
100
300
550
0
0
0
0
100
200
500
220
0
c.
p
p
p
p
p
p
c
p
p
F
P
D
P
P
P
P
P
P
p
'• 0
0
u
5000
0
P
LtG
1A
IB
1C
ID
1A
IB
1C
10
1A
IB
1C
10
1A
1A
1A
1ft
1A
1A
IA
1A
IB
1C
10
IE
IF
1A
1A
IA
IB
1A
1A
IB
2A
2B
1A
1A
1A
IB
2A
23
2C
1A
1A
1*
1A
IB
1C
10
1A
13
UTM
AR783491
AP.785491
AR785493
4P783493
AR802509
AR805505
AR806506
AR803508
'
AR795509
A<U93509 .
AR7S8512
AR795512
YA910170
YA846303
YA833172
YA905506
YA760320
YA830160
ZA160060
BR217530
BP268465
BS200521
BR220520
f
3R250482
BP.265472
YA360460
YA310300
AP960490
BR 200520
AR790360
YA820240
YA787225
YA765219
YA737226
YA760320
AR800470
AR796490
AR798487
AP.300494
AR808494
AR804498
YAa20080
AR780360
AR780350
Z*160063
ZA163064
ZA167067
ZM60067
YAU00302
Y.1.750262
�MISSIOMS STARTING
DATE
690110
690111
690119
690119
690119
690119
690120
690120
690128
690128
690128
690126
690128
690128
690128
690128
690128
690130
690130
690130
690130
690130
690130
690131
690131
690131
690131
690131
690131
690131
690131
690203
690203
690203
690203
690203
690203 •
690204
690204
690204
69J204
690204
690204
690208
690208
6^0208
690214
690214
690222
690227
ASN
4
W
W
w
W
W
W
ri
W
W
D
0
«
W
GALS
0
100
100
0
0
0
200
0
110
0
0
440
0
0
0
0
0
330
0
0
0
0
0
200
0
770
0
0
0
0
0
330
0
0
0
0
0
440
0
0
0
0
0
3000
0
0
3000
0
400
660
PRQV NO.
PLTIKU
TYP
P
C
p
p
p
p
p
p
p
p
C'
n
p
p
1_F G
1C
1*
1A
IB
2A
2fi
1A
IB
1A
IB
1C
1A
IB
1C
10
IE
IF
1A
18
1C
ID
IE
IF
1A
IB
1A
IB
1C
ID
IE
IF
1A
IB
2A
26
3A
3B
I*
IB
2A
2B
3A
36
14
IB
1C
1A
IB
1A
1A
UTH
YA695262
BK 04 1562
Bfi 122272
BR 140280
BR 11 929 5
BP.1323O6
BP 15 950.5
BP071564
AR 79 748 8
AR800495
A P, 8 09495
AR880545
AR9OO528
AR90054O
AR9O5554
ARSSB57O
AR880545
AR88O545
AP900528
Afi9OO54jQ
AR905554
AR398570
AR8.80545
AR817364
AP.815328
AP.880545
AR90O528
AP.900540
AP 905 5.5 4
A.P39857Q
AP.880545
AR880545
AP.900528
AR90054Q
AR905554
AR898570
A P. 88 054 5
48*805.45
AR9O0528
AP.900540
AR905554
AR898570
AR880545
YA882016
YV&V7930
YV908835
Y£741318
YA 732480
AP760330
AS880545
�UNCLASSIFIED
MISSIONS STARTING IN
DATE
690227
690227
690227
690227
690227
690302
690407
690407
690407
690407
690407
690411
690413
690413
690426
690426
690426
690426
690515
690517
690517
690520
690526
690530
690531
690610
690610
690610
690611
690611
690611
6<?0611
690611
690611
690611
690612
690613
690616
690619
690620
690624
690624
693624
690624
690624
690624
690624
090624
690624
690702
AGN
w
8
w
w
w
R
w
w
w
w
w
w
w
6
w
w
w
D
w
w
0
0
w
GALS
0
0
0
0
0
550
440
0
0
0
0
770
220
330
220
0
0
0
600
275
0
275
550
110
550
220
0
0
300
0
0
0
0
0
0
165
300
660
610
470
420
3000
0
3000
0
0
-.0
'0
0
715
PROV NO. =
TYP
F
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
C
C
P
LEG
16
2A
26
3A
36
1A
1A
IB
1C
10
IE
1A
1A
1A
1A
18
1C
ID
1A
1A
IB
1A
1A
1A
1A
1A
IB
1C
1A
IB
2A
2B
3A
38
4A
1A
1A
1A
1A
1A
1A
1A
18
1A
18
1C
2A
2B
2C
1A
UTM
AR900528
AR900540
AP905554
AR898570
AP880545
A0920690
ZA223532
ZA223540
ZA233536
ZA234530
ZA227528
AR820480
A P. 82 0480
YAB60450
AP760519
AF764519
AR762517
ART68517
A R 82 0480
YA980964
ZAQ08964
YA860450
AR820480
ZAU35.60
A R 82 0480
YA850190
YA830170
YA80Q230
AS 79 3 46 3
AR8O3483
AR805476
AR810478
AR813475
ARS09470
ARS06461
AR 82 0480
AR820480
AR82Q430
AR820480
A P 82 0480
AR820480
9R1 56474
BR1203GO
3R112386
BR134356
BR137324
BR125300
BR121257
BR110240
Aft820430
8
�UNCtASSIFISD
0*T5
690713
6^0827
690827
690827
69Q827
691019
691022
691106
691114
700114
700114
700114
700114
700209
700209
700209
700209
700301
700301
700301
. 700301
700301
700301
700302
700302
700302
700302
700304
700304
700304
700304
700304
700304
700313
700313
700313
700313
700314
700314
700316
700316
700318
70031E
700318
700313
700319
700319
700326
700328
700323
AfcN
W
0
rt
0
0
0
H
0
0
0
GALS
660
3000
0
0
0
890
55
200
400
4000
0
0
0
3000
0
0
0
2700
0
0
0
0
0
2700
0
TYP
P
D
P
P
P
P
P
D
D
D
0
- • •- o
0
3000
0
0
0
0
0
0
0
2500
D
Q
0
0
0
3
'
0
1100
.• 0
300
0
1700
P
P
,
•_ ..._C
0
0
0
0
T
0
PP.OV NO. =
PLEIKU
MISSIONS STARTING IN
200
'• 0
200
2600
0
P
P
D
LEG
1A
1A
IB
2A
28
1A
1A
1A
1A
1A
IB
2A
2B
1A
IB
2A
2<3
1A
IB
2A
2B
3A
3B
1A
18
2A
2B
1A
IB
1C
2A
2B
2C
1A
IB
2A
28
,1A
18
1A
2A
1A
IB
2A
28
1A
2A
1A
1A
IB
UTNI
AR820430
AQ816680
AQ817770
ZA240063
ZA190063
ZA170-J60
YA740810
ZA215535
AR790520
AQ770964
ZV190964
AQ770368
ZV190968
AQ890730
AQ30073U
AC890727
AQ800727
Z«240059
ZA190059
ZA190056
ZA240056
ZA240054
ZA190054
AQ770961
ZV190961
ZV190961
AU770953
AQ815680
AQ813737
A0815770
4C813770
AQ813740
AS810713
A0890724
A0800724
A0896722
A0300722
A0770921
ZV190921
3K220500
3R220510
4Q890717
AQ300717
AC390719
AQ800719
RR220300
3P22O510
BM230510
ZA240041
Z&190041
8
�UNCLASSIFIED
MISSIONS
700328
700328
700328
700328
700330
700330
700330
700401
700401
700401
730401
700411
700411
700411
700411
700413
700413
700413
700413
700413
700415
700415
700415
700415
700420
700420
700420
700420
700422
700422
700422
700422
700422
700425
700425
700425
700425
700507
700507
700507
700507
700507
700508
700503
70050S
700508
PROV NO.
IG IN
PLEIK.U
************
TYP
L
GALS
2A
0
2B
0
3A
0
38
0
P
1A
300
2A
0
3A
0
1A
D
3000
0
IB
2A
0
26
0
1A
1700
0
IB
0
2A
0
2B
0
1A
2600
C
0
IB
0
1C
0
0
4000
0
0
0
2700
0
0
0
2300
0
0
0
0
3000
0
0
0
3000
0
0
0
0
3000
0
0
0
10
IE
tA
D
IB
r
D
D
• D
n
2A
2B
1A
IB
2A
2B
IA
IB
1C
2A
2B
IA
IB
2A
26
1A
IB
1C
2A
28
1A
IB
2A
2B
UTM
ZA240043
ZA19C043
ZA240047
ZA190O47
BR2205OO
3R23O500
BR23P510
AQ8 00734
AQ890734
A Q 30073 7
A0890737
AQ770950
I VI 9095 O
ZV190947
A0770947
AQ770927
ZV223925
ZV 19092 7
ZV190930
ZV770932
A 08 90 74 7
A08O0747
A0800750
A0890750
A0844680
A0800750
A0800745
A0841630
A086577O
A 08 72 74 7
AQ872680
AOC68680
AQ868770
AQ874680
A0874770
AQ877770
AC877680
A0885630
AQ885720
A0889770
A0889770
A0889680
A0770939
ZV190939
A0770937
ZV190937
�NPEC= 17594
NREC= 17594
M?ROV=
iv!PROV=
218
218
NZREC=
NZR6C=
328
32S
UNCLASSIFIED
�MISSIONS ST.tPT ING IN
DATE
661029
661029
661030
66103C
661031
661031
661101
661101
661107
661107
661107
661107
661108
661108
661121
661121
661124
661124
661124
661124
661205
661205
661205
661205
661205
661205
661205
661205
661210
661210
661213
661213
670109
670109
671003
671003
671003
671003
671003
671003
631119
681119
631119
631119
681119
68111?
681119
700214
7C0214
700214
AGN
W
'.i
VI
W
fi
w
w
0
w
w
0
0
8
Q
3
B
0
PHU BON
************
TYP
GALS
L£G
n
2700
1A
0
IB
IA
3600
D
0
IB
1A
1800
0
0
IB
0
1A
2700
0
IB
D
1800
1*
0
18
0
2A
0
2B
1800
1A
0
0
18
D
1800
1A
0
18
1300
D
1A
0
IB
0
2A
0
2B
1800
IA
D
0
IB
0
2A
0
2B
0
3A
0
38
4A
0
0
4B
1800
D
1A
0
IB
1800
D
1A
0
IB
2700
0
1A
. 0
IB
1600
C
1A
0
IB
0
2A
0
2B
0
3A
0
3B
3000
1A
c
0
IB
2000
C,
1A
0
IB
0
1C
2000
c
1A
•o
IB
2000
c
1A
0
IB
0
2A
t>TM
AR940075
BR025013
BP252005
3C165140
BP.322255
BR285045
BR320250
BR160140
8Q188798
3Q064705
B0049658
6Q021592
8Q260950
SR305060
BP315110
B3258950
B0300780
BQ330750
BQ330760
8Q300790
AP943078
AR965058
AR982050
BP.028020
BR023015
A0976043
BP955058
BR937072
8R330180
80260950
BR315212
BR 29 004 8
BQ440650
80420710
BR081192
BR083192
BR113147
BR12O153
BP081192
8P117150
BR268270
8R340110
BR250260
BR160200
BF 12 0200
BP210260
BP.320100
BQ370586
B0383526
B0333526
�NREC= 17594
17594
NPRCV=
hSPROV=
218
218
NZREC=
NZREC=
328
328
UNCLASSIFIED
UnCLiSSIFIEO
�MISSIONS ST£«STING IN
0&TE
661029
661029
661030
661030
661031
661031
661101
661101
661107
661107
661107
661107
661108
661108
661121
661121
661124
661124
661124
661124
661205
661205
661205
661205
661205
661205
661205
661205
661210
661210
661213
661213
670109
670109
671003
671003
671003
671003
671003
671003
631119
681119
631119
631119
631119
68111T
681119
700214
7C0214
700214
4GN
W
W
W
W
fi
W
W
0
W
W
0
0
3
0
9
3
n
GALS
2700
0
3600
0
1803
0
2700
0
1800
0
0
0
1800
0
1800
0
1300
0
0
0
1800
0
0
0
0
0
0
0
1800
0
1800
0
2700
. 0
1600
0
0
0
0
0
3000
0
2000
0
0
2000
0
20100
0
0
PHU BON
************
TYP
LEG
IA
0
IB
1A
D
IB
D
D
0
n
D
D
1A
IB
1A
IB
1A
is
2A
2B
1A
18
1A
IB
1A
IB
2A
D
D
D
C
C
C
c.
c
c
2B
IA
18
2A
2B
3A
3B
4A
48
1'A
18
IA
IB
1A
IB
1A
IB
2A
28
3A
38
1A
IB
IA
IB
1C
1A
18
1A
18
2A
UTM
AR940075
BR025013
8R252005
3P165140
3F.322255
8*285045
3R32O250
BR16Q140
BG188798
BQO64705
BQ049658
8Q021592
60260950
8R305060
6R315110
83258950
BQ30O780
BQ330750
8Q330760
BC300790
AR943078
AR965058
AR982050
BP.028020
BR023015
AR976043
BP955O58
BR937072
BR33016O
B026O95JO
BR315212
BR290048
BQ44O650
80420710
8R081192
BR083192
BRU3147
BR120153
8P081192
BR117150
BP.26827O
BR3-4G11G
BP.250260
BR160200
BP1202OO
BR2 10260
BP-320100
BQ370536
BQ383526
PQ333526
|
�PHU BON
************
TYP
LEG
GALS
0
26
1000
C
1A
0
IB
0
1C
0
ID
0
2A
2B
0
2900
f
1A
0
18
0
1C
0
ID
0
IE
2A
0
2B
0
0
2C
0
2D
0
2E
0
2F
0
2G
0
2H
0
21
2400
C
1A
0
IB
0
1C
0
ID
0
IE
0
IF
0
2A
0
26
0
2C
0
20
0
2E
0
2F
0
2G
0
2H
0
21
0
2J
MISSIONS STARTING IN
IG IN
DATE
700214
700214
700214
700214
700214
700214
700214
701008
70100S
701008
701008
701008
701008
701008
701008
701008
701008
701008
701008
701008
701008
701022
701022
701022
701022
701022
701022
701022
701022
701022
701022
701022
701022
701022
701022
701022
701022
AGN
0
PROV NO. =
UTM
B0370586
BP219050
9R200078
BP170080
BP085178
BP-005170
AP-983120
AR97Q12Q
BR010170
8R030170
BRQ50750
BR030120
BP080170
BP090190
BR170100
BR200100
BR230050
BP210050
BP16008O
BP.110130
BR080170
AR970120
BP010170
BR030170
BP050150
BRQ30120
AP.970120
BR080170
BR090190
BR170100
8R200100
BR230G50
BR210050
BR160080
BP120120
BR110130
BR080170
IR30
�-NREC= 18053
NREC= 18053
NPSOV=
MPP.OV=
20
20
NZREC=
NZR5C=
67
6?
UNCLASSIFIED
UNCLASSIFIED
�MISSIONS STARTING IM
OATH
651007
651007
651008
651008
651009
660204
660204
660309
660309
660312
660312
660318
660318
660318
660319
660320
660320
660320
660320
660323
660323
660323
660328
660328
660323
660328
660329
660329
660329
660329
660329
660401
660401
660404
660404
660404
660404
660408
660408
660411
660411
660411
660411
660411
660411
660417
660417
660417
660417
660427
AGN
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
n
n
0
PHU YEN
************
GALS
TYP
LEG
1450
C
IA
0
'IB
3000
C
1A
0
IB
1800
1A
C
5800
D
1A
0
IB
1550
1A
D
0
IB
1150
1A
D
0
IB
3000
C
1A
0
IB
0
1C
1700
1A
C
1800
1A
C
0
IB
0
2A
0
26
1A
2000
C
0
IB
0
1C
2000
1A
C
0
IB
0
2A
0
28
1A
3000
C
0
IB
0
1C
0
10
0
IE
2800
IA
C
0
IB
3500
IA
C
0
IB
0
1C
0
10
1A
2000
C
0
IB
3000
C
IA
0
IB
0
2A
0
3A
0
4A
0
48
2400
r
1A
0
IB
0
2A
0
2B
n
3000
IA
UTM
BQ795960
BQ860770
BR950070
BQ920890
BQ773845
CQ27222O
CQ237300
CR090005
CQ085887
CR040U5
CR040030
CQ157335
CQ116285
C0000300
CC255245
B0750150
B0820150
BQ750310
BQS20290
80780643
BQ770605
BQ843614
C 009 2 245
CQ019306
CQ156266
6Q932348
BQ947576
B0950660
BQ975637
C 0034652
CC03O630
B0772397
BO&43763
CQ050640
CQ100550
C 005 0500
CQ000550
BC7&085Q
B081O770
B092Q520
BQ91 5.460
BQ840540
BQ825520
BQ79060Q
BQ840580
CQ105930
CRO90008
CQQ75800
CQ0957SO
C0220210
�DJTE
660427
660427
660427
660428
66042 C
660429
660429
660429
660429
660430
660430
660501
660501
660503
660503
660507
660507
660507
660509
660509
660512
660512
660609
6606O9
660719
660719
660720
660720
660730
660730
660920
660920
660920
660920
660928
66092R
660928
660928
669928
661001
661001
661001
661001
670113
670113
670221
670221
670224
670224
670302
AGN
Q
0
0
n
0
0
0
n
0
0
n
0
n
0
0
0
n
rj
0
GALS
0
0
0
2000
0
3000
0
0
0
3000
0
3000
0
3000
0
3000
0
0
3000
0
1000
0
2000
0
950
0
900
0
2000
0
3400
0
0
0
2700
0
0
0
0
3600
0
0
0
1800
0
2700
0
2280
0
2400
TYP
0
n
D
D
p
D
D
P
D
D
P
D
C
C
c
c
c
c
f
L6G
IB
1C
ID
.
IA
IB
1ft
IB
1C
10
1A
18
1A
IB
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
2A
2B
1A
IB
1C
10
IE
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
UTM
C0230210
CQ240260
CQ230260
CQ085255
CQ000290
CQ230280
CQ220290
C019D270
CG220260
CC170330
CQ105267
CQ000280
CQ080260
C0000277
CG077250
CQ103240
C0110265
CQ182333
CQ000275
CGOS0252
CQ1 90270
CQ230280
CQ220285
CC210315
CR033130
CR040115
CR038115
CR045113
CR040115
CP037080
BC765370
BQ733765
BC780820
BC855768
BC95Q570
BQ980700
BG970570
CG000710
C 0040 700
3Q905900
BG863965
3Q92O985
BG980350
COO 10690
OQ770620
8U840767
B0783810
BQ930570
BC960610
BG960630
1
�QATT
670302
670302
670302
670315
670315
670324
670324
670324
670324
670330
670330
670617
670617
670617
670617
670706
670706
670706
670811
670811
67O825
670825
670825
670825
670825
670825
670325
670828
670328
670828
670828
670828
670828
670923
670923
670923
670523
671001
671001
671001
671001
671001
671001
671001
671001
671001
671001
671001
671001
671006
AGN
0
5
0
0
a
0
0
GALS
0
0
0
750
900
2700
0
0
0
1860
0
2650
0
0
0
2000
0
0
1575
0
0
2610
TYP
-•— .
C
C
c
c
c
c
c
c
i»
0
0
6
0
0
0
0
D
B
e
1850
0
0
0
0
0
2400
0
0
0
3000
ff
0
0
0
0
0
0
0
0
' 0
0
2950
LEG
IB
2A
28
1A
1A
1A
IB
2A
28
IA
IB
IA
IB
2A
28
1A
IB
1C
iA
13
IA
c
D
C
n
2A
28
3A
3B
3C
1A
IB
2A
28
3A
3B
1A
IB
2A
28
IA
IB
2A
28
3*
3B
4A
48
5A
56
6A
6B
1A
UTH
8Q96067Q
BG940650
BG970650
BQ790710
3G790710
BQ710B90
BQ790920
BQ760850
B080O900
B«980680
CQ02O620
30789799
SQ843747
8Q8O4798
BQ845758
BQ797908
BQT56873
80853768
BQ92Q3Q5
CQ045300
BQ8 70310
CGOOO350
CQ040310
6 Q 96 0300
BQ950320
B 092 0340
6,09 0-0 3 30
BC940600
BQ920660
BQ92Q588
9,6875655
B6948586
BQ910655
BQ865965
8Q867<>35
BQ881900
8^950820
BQ754210
BC755259
BQ762229
3G759212
3Q768229
BQ766210
BQ815175
BC815205
BC820190
B0816215
BG845173
BQ835185
RC373553
'
1
�D4T£
671006
671006
671006
671007
671007
671010
671010
671010
671010
671011
671011
671011
671011
671011
671011
671022
671022
671023
671023
671023
671023
671027
671027
671027
671027
671223
671223
671223
671228
671228
671228
680202
680202
680202
680202
630411
680411
680411
680411
680513
680513
680515
680515
680515
680515
680515
680515
680515
680515
680524
AGN
R
3
B
0
0
,
8
0
0
0
0
0
0
H
GALS
0
0
0
3000
0
2800
0
0
0
3000
0
0
0
0
0
3000
0
3750
0
0
0
3000
0
0
0
2850
0
0
2850
0
0
1900
0
0
0
1 740
0
0
0
3000
0
2700
0
0
0
0
0
0
0
2750
TYP
C
C
C
C
C
C
D
D
D
D
D
r-
D
LPG
IB
24
2B
1A
IB
1A
IB
2A
2B
1A
IB
2A
2B
3A
3B
1A
IB
1A
IB
2A
2B
1A
IB
2A
2B
IA
IB
1C
IA
IB
1C
1A
IB
2A
26
1A
IB
2A
2B
IA
18
1A
IB
2A
2B
3A
3B
4A
4B
14
UTM
BQ901535
BQ365550
8Q865520
BQ785910
BQ853768
BQ880580
6Q910580
BQ880590
BC910590
BC920592
B0870592
BQ870588
BQ920588
B0920598
BQ875598
BQ947599
BQ924688
BQ875555
B0901535
BQ865534
BC890526
BQ888512
BQ834541
8Q386495
BQ850541
BQ983875
CQ003882
CQO06895
CQ017901
CG002903
DC982884
BQ883550
8Q901537
B0860530
B0890525
BQ863963
8Q371947
BQ891383
BQ947835
CQ166271
CQ176341
3G9 83388
CQ055395
BQ967332
30950420
BQ711434
BQ932438
BU913446
BC913430
CQ261240
�MISSIONS STARTING IN
04TE
630524
680524
680524
630531
630531
630613
680613
630613
6S0613
680613
680613
&80619
680619
630626
630626
680628
680628
680711
680711
680711
680711
630711
630711
630717
630717
&S0717
680717
630717
680717
630717
680723
680723
680723
680723
680729
680729
680729
680729
630729
680729
680729
630729
680730
680730
680730
630730
680730
630730
680801
630802
&GM
W
0
w
•'
3
B
B
3
0
1500
0
0
0
0
0
0
0
3000
0
0
3000
B
3000
0
0
0
0
3
2000
0
0
0
B
PHU YEN
************
TYP
GALS
LEG
0
IB
2A
0
2B
0
D
1A
2000
0
16
2800
D
1A
0
18
0
1C
2A
0
2B
0
0
2C
C
1A
2000
IB
0
1A
2500
c
0
13
2000
C
1A
0
IB
3000
c
1A
IB
0
2A
0
0
28
0
3A
2000
c
c
c
c
c
c
0
0
0
0
•o
0
0
510
480
p
p
38
1A
IB
1C
2A
2B
2C
20
IA
IB
IA
IB
1A
18
2A
2B
1A
IB
2A
2B
IA
IB
2A
2B
3A
3B
IA
14
UTM
C0223313
CQ26923V
CQ228307
CC30G253
CQ245290
CQ168280
C0193310
CQ168347
C0166280
CQ169310
C0164343
CU1.69236
C0123293
80740862
BQ342738
BQ750870
80848740
3Q790910
80753884
BQ754358
BQ785811
B.Q830770
B084Q745
3Q788908
8Q753888
8Q749865
BQ753S56
BQ792811
B0840775
BQ345745
BQ736719
807 51 85 5
80736719
B0751855
BQ820335
BQ355335
B0875380
30865280
B0820350
S0855335
BQ875380
BC865280
B08S4570
B0902579
BQ855620
B0827628
BQ856670
BG822667
C0220300
C0220310
'
*
�DATE
630803
63030b
680805
680805
680805
680305
630805
630805
680805
680805
660805
630805
630805
680805
680805
680805
680S05
680805
680805
680805
680805
680805
680605
630805
630805
680805
680805
630805
630805
680805
630805
680805
680805
630605
680805
680805
680805
630805
630805
680805
680805
680805
630805
630805
680805
630805
680805
630805
680805
680805
4GN
0
R
B
B
GALS
55
82
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
83
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
55
0
0
0
0
0
0
0
0
0
0
0
0
TYP
P
C
LEG
1A
1A
IB
2A
2b
3A
33
44
4B
5A
58
6A
68
7A
7B
8A
8B
SA
9B
IA
13
2A
28
3A
36
4A
4B
5A
5B
6A
6B
7A
TB
8A
6B
9A
9S
1A
IB
2A
2B
3A
3.B
4A
46
5A
SB
6A
68
7A
UTM
C0034330
BQ986538
8Q96554Q
B0991340
BQ990543
CQ000544
CQ000553
CQ008544
CQ008557
CQ034562
3C043562
CQQ32577
CQ040579
CC054560
C 0362 564
CQ053565
CQ061568
CC068577
CQ068577
CQ08458?
CQ064D77
BQ983615
BQ985619
BQ992615
BQ993619
B0919607
BQ928608
8Q920613
BQ928613
B08e7587
B088Q592
BG888537
BQ868592
BC884505
30a895O4
B45884516
BO8B9516
BG930467
BQ930485
BG935465
BQ936485
C0002602
CQQ04597
C 001 0 0
60
C0010607
CQO20607
CQ023610
C 002 061 8
CQ015619
C0013617
�UNCLASSIFIED
PHU YEN
*.*«.#********
LEG
rvr
GALS
7B
0
1A
P
55
1A
P
55
1A
E
400
IB
0
1A
S
500
1A
S
1400
2A
0
1A
c
50
IB
0
2A
0
2B
0
3A
0
4A
0
4B
0
5A
0
58
0
6A
0
68
0
7A
0
7B
0
8A
0
1A
c
25
IB
0
2A
0
2B
0
3A
0
3B
0
1A
P
55
1A
P
55
P
1A
110
1A
P
80
1A
138 V ,.._p
1A
C
2000
18
0
1C
0
P
1A
60
1A
P
55
P
1A
50
1A
c
3800
IB
0
1C
0
1A
r
3000
IB
0
2A
0
2B
0
1A
c
2000
IB
0
0
1C
2A
0
PROV NO. = 10
MISSIONS STARTING IN
DATE
680805
680806
680807
6808 1 2
680812
680313
630813
6S0813
68081?
680815
680815
680815
68081 5
680815
6808 15
680815
680815
680815
680815
630815
680815
680815
680815
680815
680815
680815
630815
680815
680817
630817
680817
6308 1 7
680817
680818
6 BOB 1C
630818
680821
680822
630823
680827
580827
680827
680828
680828
680828
63082P
680831
630831
630831
680831
ASM
0
0
0
0
0
B
0
0
W
0
W
W
0
0
0
0
3
P
S
UTM
CQ014610
CGQ34380
CC121383
C 003 7900
C0020730
BQ957768
B0950830
BQ880390
CC673460
C0655460
CQ650464
CQ655470
C0655470
CQ701595
CQ706589
CQ718592
C Q71 6 59 7
CQ718534
CQ748623
C07&5596
CQ757513
CQ757582
CC763575
CQ765787
CQ725664
CQ731678
CQ733664
CQ733669
CQ051308
CQ051308
CP02422B
CP024228
CPO 18294
80857610
BQ907600
30910640
C0077342
CQ051308
CP018294
BQ900565
BQ855&20
BQ880700
B 0 3 0520
9
BQ930480
B08505UO
80850520
B0980960
BQd80910
BCS60S60
BR910000
�UNCLASSl^ltU
MISSIONS STARTING IN
OftTE
630831
680917
680917
680917
630917
630917
680919
AGN
680923
630924
680924
680927
681004
631004
631004
0
68rooe
681008
681009
631009
681010
681016
631026
681027
681103
681103
681103
681104
681104
631104
631104
631108
681108
681205
631212
681212
681212
681219
681219
681219
681219
681220
681220
6S1220
631220
681220
631220
690101
630101
690101
690101
690103
B
0
B
O
0
0
0
w
o •
G
Q
0
f>
0
Q
0
n
n
0
D
0
W
n
n
0
w
w
n
GALS
0
3000
0
0
0
0
20
55
2500
0
55
385
440
495
55
55
55
60
65
100
100
90
2000
0
0
3000
0
0
0
3000
0
110
165
385
165
3000
0
0
0
2000
0
2000
0
0
0
275
0
3000
0
99
PRQV NO.
TYP
C
LEG
26
IA
IB
24
P
P
C
p
p
p
p
p
p
p
p
p
p
p
p
D
D
D
P
P
P
P
D
C
0
s
r
p
28
2C
1A
iA
1A
IB
iA
iA
iA
1A
IA
iA
iA
IA
1A
IA
IA
iA
IA
16
1C
1A
IB
2A
2B
IA
IB
1A
1A
IA
IA
1A
IB
2A
2B
1A
i8
1A
IB
2A
28
1A
IB
1A
IB
1A
UTH
BP950000
6Q920890
80880910
BC360960
BP91QOQG
BQ98O960
CQ271343
C0271343
BQ316045
B028D050
CQ235273
BQ880880
60950840
8039094O
CQ074916
COO 7 7 34 2
C0077342
CQ271336
C0271326
CQ271326
C0271343
C0271343
60667519
BQ721483
BQ76O480
BQ390453
30968383
BQ888450
B 094 64 16
60359978
8Q913836
C0271343
00090780
C 0061 693
C0087688
B0864980
BQ868940
50896883
B0942837
CP032130
CR037080
BQ858980
BC868922
B0890380
B0942836
CR105780
CR067742
BQ666515
B0714480
C0024228
I:
10
�UNCLASSIFISO
M I S S I O N S STARTING IN
04TP
690103
690106
690106
690107
690112
690112
690112
690112
690112
690112
690112
690112
690118
690224
690225
690301
690306
69O309
69030S
690320
690321
690326
690514
690514
690514
690514
690605
690605
690605
690605
690605
690605
690605
690605
690605
690605
690606
690606
690606
690606
690606
690606
690606
690606
690617
690620
690620
690620
690621
690621
AGN
0
w
0
W
3
W
0
W
W
W
w
0
w
w
ft
0
0
0
w
w
0
0
C
GALS
83
220
275
385
495
0
0
0
495
0
0
0
330
400
220
455
450
3000
0
500
455
375
3000
0
0
0
3355
0
0
0
0
0
385
0
0
0
2640
0
0
0
935
0
0
0
550
2800
0
0
3000
0
PHU YEN
TYP
F
S
S
P
S
S
P
P
P
P
P
0
P
P
P
D
C
c
c
c
c
c
c
PROV
LEG
1A
1A
1A
1A
1A
IB
1C
10
1A
IB
1C
ID
1A
1A
1A
1A
IA
IA
IB
1A
IA
1A
IA
IB
1C
ID
1A
2A
3A
4A
5A
6A
1A
2A
3A
4A
IA
2A
3A
4A
1A
2A
3A
4A
1A
IA
IB
1C
1A
IB
UTH
CQ024226
BQ957782
CP 07 5 78 5
CQ024228
CR090460
CR085448
CR110460
CR110444
CR043558
CR043549
CR069559
CR069549
CQ173337
C0121383
CQ078346
CQ051303
CG051308
3R843033
BQ901870
C0173337
CQ1 73337
CG173337
BQ859960
BC858940
60887880
BQ920852
CQ072703
CQ066695
CQ079683
CQ087660
C0096663
CQQ90690
CQ042714
CQ039706
CQ046705
CQQ47712
CQ052725
CQO52690
C 006 5690
CQ064726
CQ015742
CQ011736
C0020723
CC020729
CQ264298
B0730200
BQ310180
BC8 10200
BQ903608
B 091 8600
NO.
10
�PHU YEN
************
GALS
TVP
LEG
0
1C
0
ID
0
IE
0
• 2A
0
2B
0
2C
0
2D
0
2E
0
2F
2000
C
1A
0
IB
0
1C
0
ID
0
IE
0
2A
0
2B
0
2C
0
20
0
2E
330
C
1A
2600
C
1A
0
IB
0
1C
0
ID
0
2A
0
23
0
2C
0
20
0
3A
0
38
0
3C
2000
C
1A
0
IB
0
1C
0
ID
0
2A
0
2B
0
2C
2600
D
1A
0
IB
2600
C
1A
0
IB
2A
0
0
26
0
2C
3000
C
1A
0
IB
' 0
24
0
2B
3000
C
1A
,«ISS!DNS ST*RT ING IN
D*TP
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
6*50621
690621
690621
690621
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690702
690702
59070R
690708
690706
690708
690706
AGN
0
0
0
0
0
0
690714
B
690714
690714
690714
690714
B
UTM
BQ93757B
BC939554
BC95O558
60960553
BC92857Q
80924560
BC928552
BQ938549
B0950552
80691210
B 068 1244
BC682226
BG678249
B0708221
BQ704239
806,91261
80677275
BQ664259
8Q655263
C 002 3.22 4
BC763776
B0799777
B0811771
BQ32&751
80829745
BQ84-2719
BQ799712
eeaio730
BQ812738
9QS20765
BC874769
B 0955660
B0980628
BQ994635
B0948688
B0995617
B0995535
B0990610
CP015126
BP.989166
3Q710574
80740588
BQ695532
BG750535
BC730623
3Q760890
B0786301
B 083 5 771
30360770
R0380610
�UNCLASSIFIED
PHU YEN
&
$
**
^ifr^X^^*3^
!G IN
MISSIONS STARTING IN
0/iTE
690714
690714
690714
690714
690718
690718
690718
690718
690720
690720
690720
690720
690720
690730
690731
690821
690824
690914
690914
690916
690923
690923
690925
690926
690926
690929
691005
691006
691023
691023
700129
700129
700129
700129
700129
700129
700129
700129
700129
700222
700222
700222
700222
700222
700222
700222
70022Z
700226
700226
700301
AGN
TYP
GALS
0
0
0
0
3000
0
c
o
0
3000
0
0
0
Q
0
O
*")
W
0
w
0
w
0
w
0
<fi
W
w
0
w
B
0
450 —
110
275
275
0
0
0
0
0
0
330
145
210
150
275
385
330
2600
0
0
0
0
0
c
^
c
c
c
c
p
p
p
p
p
p
p
p
p
p
p
p
p
0
o
0
0
300
0
0
1900
c
c
0
0
o
C
0
0
935
0
28QO
E
D
LEG
IB
2A
26
2C
1A
IB
2A
28
1A
IB
1C
2A
28
IA
1A
1A
IA
IA
1A
IA
1A
1A
1A
1A
1A
14
IA
1A
IA
iA
IA
IB
1C
ZA
2B
ZC
3A
3B
3C
.
1A
IB
1C
iA
IB
1C
10
IE
IA
IB
1A
PROV NO.
UTM
B0980532
BQ940580
60975430
6Q954546
B0968568
PQ995665
80970605
8Q980660
BQ790912
BQ783903
BQ77190Q
SC755894
BQ7568SO
C0235273
CQ1213&3
C0268243
CQ266232
CQ271343
CQ271343
C 027 134 3
CQ034367
CCQ343&7
CQ034367
CQ271343
C 0 7 134 3
2
B0974916
B0974916
BQ974.916
CQ235273
CC235273
COZ&9237
CQ255248
C 024,32 76
C0244278
CQ258250
CQ271239
C02T3240
CQ2.&Q252
C0246279
B0810200
B0320160
BQB00200
50685590
BO/20613
BQS40630
BQ79559?
BC760610
CQ263233
CO23519J
CQ243275
10
�MISSIONS STARTING
r
04T
700301
700301
700301
700301
700301
700301
703301
700301
700312
700312
700312
700312
700312
700312
700318
700318
700318
70031G
700319
70031°
700319
700319
700320
700320
700320
700320
700325
700325
700325
700325
700402
700603
700605
700606
700609
7U0612
700614
700615
700615
700616
700617
700619
700701
700912
701005
701006 '
701111
701113
701117
PRGV NO. =
0
0
LEG
IB
1C
0
2A
0
0
0
0
A ON
28
2C
3A
38
3C
GALS
TYP
0
li
600
0
0
0
0
0
250
0
0
0
440
0
0
0
330
0
0
0
250
0
0
0
165
165
165
165
165
165
165
825
825
275
275
110
275
150
135
135
53
In!
90
W
75
0
0
0
0
0
0
0
0
0
0
0
0
n
n
n
0
0
R
0
w
w
P
P
P
P
P
P
P
P
P
P
P
P
r>
P
P
P
P
P
P
P
P
P
F
P
1A
IB
1C
2A
2B
2C
1A
2A
3A
4A
1A
2A
3A
4A
1A
2A
3A
4A
1A
2A
3A
4A
IA
1A
1A
1A
1A
1A
IA
If1A
1A
1A
IA
1A
1A
1A
1A
1A
1A
1A
UTM
CQ258247
CU270237
CQ245277
CC262249
CQ274237
CC248273
C0272245
Cti288234
BQ530280
B0550240
BQ570230
BQ600230
BQ580280
BQ530280
CQ067503
0008-3419
CQ100490
C0085515
CQ067503
CQ089419
CQ100490
CQ085515
CQ067503
COO89419
CQ100490
CQ085515
CC023506
C 003 8493
CQ048503
C0045035
CQ023506
CQ093492
C0135525
CC051308
B0936361
CQ265302
CQ135525
C0019643
CC074788
30916850
BQ916850
C0176356
80916850
CQ235274
C0050305
8Q963362
C0273323
C0093492
CQ135525
' J N C L « S S I FHO
10
�NREC= 17541
NREC= 17541
NiPROV=
MPROV=
2C7
207
NZREC=
NZREC=
392
392
UNCLASSIFIED
�DATE
670912
670912
670912
670912
670913
670913
670913
670913
630323
6S032S
630326
680328 '
680329
68032S
680407
680407
680407
680407
630429
630429
630508
680508
680508
680508
680518
680518
630518
630518
6805 18
680518
680518
630518
630518
680518
630518
680518
630520
630520
680520
680521
680521
630522
680522
680525
630525
630525
630525
680526
6B0526
630601
AGN
0
n
w
<!
tf
w
0
0
0
0
W
W
0
0
w
n
n
GALS
2000
0
0
0
2100
0
0
0
1000
0
5000
0
3000
0
5000
0
0
0
3000
0
4900
0
0
0
6000
0
0
0
1250
0
0
0
1000
0
0
0
4000
0
0
3000
0
6000
0
6000
0
0
0
3000
0
3000
TYP
C
C
D
D
D
r
o
D
D
D
C
D
0
O
D
D
0
LEG
1A
IB
2A
28
IA
IB
2A
2B
1A
IB
IA
IB
1A
IB
1A
IB
1C
ID
1A
IB
1A
IB
1C
ID
1A
IB
2A
2B
16
18
1C
10
1A
IB
1C
10
1A
IB
2A
LA
IB
1A
IB
1A
18
2A
2B
1A
IB
1A
UTM
BP368770
BP340820
6P470830
BF345832
BP350727
BP340820
8P430333
BP347830
B0323100
BQ321190
B0323100
BQ321190
AC922670
AQ995540
BQ302100
B0302190
BC314190
30314100
B0343100
8Q343190
8G368190
B0373190
BQ368100
BC373100
80297100
B03O7190
3Q297150
BQ3O7106
BQ318145
BQ318100
8Q315100
BC315190
B0318145
BQ318100
80315100
B031519Q
8035O190
8Q318190
BG318100
B0363100
B0363190
BQ380161
BC299175
8Q330100
80330190
8Q33519Q
BQ335100
B0368100
BQ368190
BQZ85100
'
�D&TP
630601
680606
680606
680612
630612
680619
680619
680619
680619
680701
630701
6S0701
680701
680710
630710
680710
680821
680821
680830
680830
680830
680830
680924
680924
680924
680924
681011
631011
681030
681030
631030
681030
681103
631103
631122
681122
681123
681123
681205
681205
690102
690102
690102
690102
690106
690106
690106
690106
690302 •
690302
AGN
GALS
TVP
0
0
4000
D
0
0
•ti
3000
0
0
3000
0
0
0
0
n
3000
0
0
0
0
0
3000
0
0
3
2000
0
B
3000
0
0
0
S
2500
0
c
c
c
0
0
0
0
3700
D
0
0
5700
D
0
0
0
0
3000
D
0
0
2900
0
5000
D
0
D
0
0
2750
0
0
0
2000
D
0
0
0
0
w
3000
~D
0
0
0
8500
0
C
LEG
IB
1A
16
1A
IB
IA
IB
ZA
28
1A
IB
2A
28
IA
IB
1C
iA
IB
1A
IB
2A
2B
IA
IB
2A
28
IA
IB
1A
IB
2A
28
IA
18
1A
18
IA
IB
1A
IB
1A
IB
2A
28
1A
IB
2A
28
1A
IB
UTW
BQ235157
B0377100
BQ377190
BQ347100
9Q347190
BQ338100
SQ338190
BQ34619O
8G346100
8Q31110Q
BQ31119O
BQ326190
B0326100
BQ250100
BQ290190
6Q290100
BP220920
BP1O0840
BQ385164
80286176
BQ387162
80321169
8Q316O45
BQ28OO50
AQ990080
BQ316045
AQ992560
AQ992400
AQ9«T400
AQ925436
AQ9I985O4
AQ993540
AQ995900
AQ983434
YV 802 47 4
YV 85 762 4
YV802474
YV772300
BQ000403
AQ983540
BQ001420
A0982462
AQ997505
AQ9S0544
BQ387167
BQ285178
B0280170
BQ366162
YU9 90830
ZU090910
'
*
�MISSIONS
DATE
690302
690320
690320
690320
690320
690320
690320
690320
690320
690610
690610
690610
690610
690610
690610
690610
690630
690630
690630
690630
690630
690630
690703
690703
690703
690703
690703
690704
690704
690704
690707
650707
690707
690707
690707
i>90708
690708
<S9070e
690712
690712
690712
690714
690714
690714
690714
690715
690715
690715
690715
690715
STARTING
AGN
C1
0
fj
0
0
0
0
0
n
0
0
0
n
0
IN
GALS
0
3000
0
0
0
3000
0
0
0
2500
0
0
0
0
0
0
2000
0
0
2000
0
0
3000
0
0
2700
0
3000
0
0
2300
0
3000
0
0
3000
0
0
3000
0
0
3000
0
0
0
3000
0
0
0
0
PROV NO, = 1 1
OflRLAC
TYP
P
D
D
D
D
n
n
0
0
P
n
n
C
C
LEG
1C
1A
IB
2A
28
IA
IB
2A
26
1A
IB
1C
2A
2B
2C
20
1A
IB
1C
1A
18
1C
IA
IB
1C
1A
IB
1A
IB
1C
1A
IB
IA
IB
1C
1A
IB
1C
IA
IB
1C
1A
IB
2A
2B
IA
16
2A
26
3A
UTM
ZU140920
BG380157
B0289167
3Q288170
BC370160
80390169
BQ300180
B0289164
BQ365155
AP994827
AP985792
4P982765
AP982765
AP981790
AP994805
AP998827
ZV206O54
ZV176150
ZV101225
ZV181056
ZV157134
ZV083213
ZV177059
ZV152134
ZV082212
A P9 74 76 7
AP9S4830
ZV211054
ZV177149
ZV103226
BP038580
AP871605
BP392647
BP3A26S2
BP370800
ZV203055
ZV174148
ZVa'58222
ZV185100
ZV170146
ZV097221
AP969830
AP971763
AP968769
AP986830
ZV203100
ZV186154
ZV206100
ZV1SO150
ZV2091'JO
rO
�DAT1:
690715
690716
690716
690716
690716
690716
69J716
690726
690726
690726
690726
690726
690726
690726
690726
690727
690727
690727
690813
690818
690818
690823
690823
690823
690823
690928
690928
690928
690928
690928
690928
690928
690928
690928
69100S
691008
691008
691008
691008
691008
691008
691008
691015
691015
691112
691112
691112
691112
700316
700316
AGN
0
8
0
0
0
0
3
W
B
a
GALS
0
3000
0
0
0
0
0
1200
0
0
0
0
0
0
0
2500
0
0
2500
0
0
2000
0
0
0
2000
0
0
0
0
0
0
0
0
2880
0
0
0
0
0
0
0
6000
0
1100
0
0
0
2000
0
TYP
0
C
D
D
D
C
D
D
C
C
LEG
3B
IA
IB
2A
2B
3A
38
1A
IB
1C
ID
2A
2B
2C
20
1A
IB
1C
1A
IB
1C
1A
IB
2A
2B
1A
IB
1C
ID
2A
2B
2C
2D
2E
1A
IB
1C
ID
2A
2B
2C
2D
1A
IB
1A
IB
1C
ID
1A
IB
UTM
ZV194145
BPGQ2772
8P01S830
AP998773
AP015830
AP995773
AP012830
BP390847
8P372342
BP3&7S4Q
BP357836
BP400840
BP390839
BP380840
BP360832
ZV182100
ZV168143
ZV094219
BP388647
BPM0682
BP367800
YU995203
ZU037204
ZU105155
ZU157143
&P353851
BP346834
BP339832
BP317834
BP284843
BP266847
BP294842
8P226844
BP229886
BP390810
BP350818
BP320820
BP295836
BP285838
BP26Q845
BP21O850
• BP180877
BP022545
AP859583
BP410825
BP340817
BP235886
BP070834
BP070820
BP1 10830
�UNCLAiSiHtU
MISSIONS STARTING IN
0/TS
700316
700316
700316
700331
700331
700331
700416
700416
700416
700416
700720
700720
700720
700720
700824
700824
700824
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
701005
7J1005
701024
701024
701024
701024
701024
701024
701024
701024
701024
701024
701024
701024
701024
701024
701024
701024
701108
701121
701121
701121
701216
AGN
0
0
B
3
3
8
8
B
W
9
B
GALS
0
0
0
2500
0
0
1800
0
0
0
3000
0
0
0
2500
0
0
13
0
0
0
13
0
0
13
0
0
0
0
2420
0
0
0
0
0
0
0
0
0
0
0
0
O
0
0
50
1500
0
0
1060
DAPLAC
************
IYP
C
D
C
C
C
C
C
PROV NO.
tEG
1C
10
IE
IA
ie
1C
1A
16
1C
10
IA
IB
2A
2B
1A
IS
!
£
IA
IB
1C
10
IA
18
1C
IA
IB
1C
to
C
IE
1A
18
1C
10
IE
IF
1G
1H
2A
28
2C
2O
2E
2?
2G
2H
P
IA
C
1A
IB
1C
1A
C
UTM
8P19O900
BP200S50
BP14083Q
8P38QS05
8P2*OS67
6POAJOB30
8P43OSOO
BP43090Q
BPO6O90O
8P06O800
BP35O790
BP38O000
BP220a9O
BP1&O380
BP34O69O
BP37O770
BP33:Q820
BS13199O
8S 133490
8S1339S1
85 130981
BS12Q964
8 SI 2495 6
8S11896O
BS129951
BS130953
BS13O947
3S128945
BS 12 542 5
BRO9O810
BRX)?O880
SR240910
BP33O8&0
BP41O«00
8R380770
&R370710
8P-3T0670
BR3O0670
BR33O700
8R360790
8R3O0810
BR220360
8R 150860
BK150810
3P.Q90810
60116332
BP345685
BP370765
3P328821
6PQ98820
11
�UNCLASiiHtU
MISSIONS
04TE
701216
T01216
ST&RTING
AGN
IN
GALS
0
0
PROV NO. = 1 1
DiPLAC
************
TYP
LEG
IB
1C
UTM
BP144862
BP253887
�17888
NREC= 17338
NPROV=
69
69
NZREC=
NZREC=
183
183
UNCLASSIFIcO
�n.M"
.1 GN
650828
650828
650829
65U829
650830
650830
660202
660202
660306
660306
660307
660307
660310
660310
660315
660315
660317
660317
660523
660528
660819
660819
660819
660819
660822
660822
660826
660326
660826
660826
660828
660828
660903
660903
660905
660905
660905
660905
660909
660909
660909
660909
670419
670419
670419
670419
670423
670423
670424
670424
0
900
0
0
1000
D
0
0
650
0
D
0
3000
D
o
n
GALS
TYP
C
LcG
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
18
1A
18
1A
18
1A
16
0
2000
0
0
2000
D
0
r)
2000
0
0
0
1900
D
0
0
2000
P
0
0
n
2000
0
0
2000
D
0
2000
D
0
0
3000
D
0
0
0
0
2000
P
0
0
3OOO
D
0
0
n
w
'j
4000
D
0
0
0
2000
0
0
0
0
3720
0
0
0
0
1860
0
0
w
2250
0
'
IA
IB
2A
26
0
0
0
0
IA
IB
1A
IB
2A
2B
1A
IB
IA
16
1A
IB
2A
28
1A
IB
24
28
1A
IB
2A
2B
1A
IB
IA
IB
UTM
BP700900
BP750877
80510122
B0435162
BQ435162
BQ510122
C0270220
CQ176150
CG22Q180
C0260230
CP02091G
CQ225190
BP75Q385
3P700900
8P667925
BP636999
8Q630000
BP67O925
CQ106083
CO224194
CPO2827O
CPQ00310
BP99531Q
CPO2O265
BP955360
8P950240
8P958240
B90!Q
P63&
SP950360
BP963310
CP024268
BP991310
BP9S03TO
& 9 5 6
P 7 2 O
3P95324D
&P95736O
& 9 0 330
P 6 ..
&P 958275
BP940240
BP9-40360
CPO:59220
CPO59211
CQ178164
CG225187
C0173173
C0217196
CPQ 15989
BP9 17932
BP74Q862
6P857960
�MISSIONS STARTING IN
DATE
670426
670426
670505
670505
670519
670519
670519
670519
670519
670520
670520
670524
670524
670526
670526
670526
670526
670527
670527
670527
67C527
670529
670529
670529
670529
670529
670529
670530
670530
670607
670607
670607
670607
670615
670615
670615
670618
670618
670616
670618
670618
670618
670619
670619
670621
670621
670621
670621
670624
670624
AGN
W
W
W
W
0
0
0
W
0
W
0
W
W
0
W
n
W
W
0
V*
W
W
KHANH HOA
************
TYP
LEG
GALS
1A
2430
0
IB
0
1800
0
1A
IB
0
1A
D
5580
IB
0
2A
0
2B
0
2C
0
1A
2700
D
0
IB
1A
2400
D
IP
0
IA
1860
D
IB
0
1A
2250
D
0
IB
1A
2600 ~- . . £ .
.„
IB
0
IA
2500
D
IB
0
D
1560
1A
IB
0
iA
930
D
IB
0
1A
700
D
IB
0
2790
1A
D
18
0
1A
2790
D
0
1-B
1A
2250
D
0
IB
2790
IA
D
0
13
1C
0
1A
3395
D
18
0
0
2A
2B
0
D
1A
2600
IB
0
r.
1A
1860
IB
0
r
1A
2400
IB
0
IA
3670
D
IB
0
c
IA
2790
0
IB
/
/
f
UTM
BQ927098
BQ841152
CQ130125
C0088092
CPOOQ993
CP013988
BP937958
BP936953
BP90S936
B0892085
8Q837138
BQ925120
CQ050093
80918118
BQ836177
8Q88O080
BP950994
BQ927132
'
ceoiooso
BQ94O110
CQ030070
30943047
CC010045
BQ875085
BQ820130
BQ875085
BQ820130
BP910935
BP853952
BQ929132
B0850128
BQ870090
BP950550
CQ080150
CQ040120
C 306 0090
BP766911
BP784902
3P830960
BP773907
CQO 10050
CQ080100
SP87G990
9 P9 10020
B«870080
8^820130
30352073
BQ928006
9Pb359o5
BP91J942
1
)-
�OATF
690415
690415
690415
690416
690416
690416
690416
690422
690422
690422
690422
690423
690423'
690423
690426
690426
690426
690426
690426
690426
690426
690426
690426
690426
690426
650426
690426
690426
690426
690426
690427
690427
690428
690428
690430
690430
690430
690430
690430
690502
690502
690502
690502
690502
690502
690505
690505
690514
690514
690514
AGN
0
W
o
H
W
B
8
0
0
M
0
W
D
GALS
0
0
0
3000
0
0
0
1650
0
275
0
330
0
495
350
0
0
0
0
0
0
0
350
0
0
0
0
0
0
0
275
0
2000
0
3825
0
0
0
0
2000
0
0
0
0
0
2000
0
55
0
0
TYP
D
p
p
p
p
p
p
c
0
p
LEG
IB
2A
2B
1A
IB
2A
26
1A
2A
1A
2A
1A
2A
IA
IA
IB
1C
ID
IE
IF
1G
1H
1A
IB
1C
10
IE
IF
IG
1H
IA
IB
1A
18
IA
ie
1C
ID
ie
D
C
f
IA
IB
1C
2A
2fS
2C
IA
IB
1A
IB
1C
UTM
CR045520
BR960545
CP021490
3R843049
BP 84 9010
30860991
BQ866965
BR780350 .
9R790340
BR780350
BR790340
80900895
BC893910
BQ950762
BR929747
BP.930745
BR931743
8R932740
BR930738
6R925740
BR924742
BR925745
8P.S29747 ,
BR930745
BR931743
BRS32740
BR930738
BR925740
BR924742
BR925745
8K620300
BR62Q310
Cf. 046180
CR072127
6R448455
BR445470
BR450490
3R480490
3R486450
CR068127
CRO4218O
CR056147
CRO39180
CR053146
,
CR036180 !
3S3561U
BR440950
S 57 50 01 5
BS75O025
BS754Q25
�"t • t ''
^j : -:
f^LS
(SSii'. \ ,
09 'i'~- ' '.'
!,'5:}N? i
r}9!j'-H
,' ' is l-',
6V J V ! .
': '
!
•;
?'j
0
0
:>
e-;:,
0
t)
,)
H
}'• I '>
,•,--• < ) ~ { /,
••• •--.!''• I -i
'»<•(}' I '•
6 -'fi'-l'i
Tvr>
0
;"
•i
f;
18
1C
f:
iu
, i f!'••
(
li
\.',.'
i"
HT?»
««?. 754ft I •;
i^ 7^001:5
f 4 S f 5,0fi/;,
£
b fs-'«o^:<
f»F I*>4OJ >5
nS750OO'i
1
sr f 'i ; jo-*
•M--fisvi-'*
ivi- / ^oa?-*
;':• f'-oOi'H
! i°.
n c 7';5L':.'-'»
1'.
0
0
(/.' ) ' " • \ 'i
; ' •'.
IP
! «.
i't. ( r .'>'"3V->
!;
o '-'.!'!
'
"
5r;
:\
;. 3. >'>!',
'j •>•.:• r> 1 ."•;•)'• 1 •:•'
to '.••.•••- IV
6 >OM1
61 •?'.• I'
f, •- ;'. ! • •
: •,>"• i 1
'•.'•'O'i -J 1
•• .-.; : . '• 1
; -- '• !
•' • '"•/ ;
'.•:•••!•• .-• j
i' ?iU^*> •'«
'55 » ^ :>•'-"* 8
^•?^nJ
ir
^7V5^!1
'K
f
}
n
5S
s
i »
6 J ; ! - ' I -t
•'. ' 0 r> i M
I i
1C
' r . ", t •>
i- •••.;' i t
.;••••• t-V
, '• »!r 'l^l
l
-. i
•i
n
'•
1
K'O'J
0
5?0
0
264O
r.
0
0
1'iJ-)
0
0
0
r
>5
!'
1A
li>
C
1A
lj
'S/'>:i;;V?
r !;-:J j 3 TJ i
cpoofti ?f.
rco/aivi
j *
tA
CSiOiH'lVO
•ift
li
2t-
!'•'
*"'• n V *^ 4 ^! ' J ^
3A
-'iA
£l£ G 7 7 ^•''j.-tt
M •?.: *.2 Q j y&i~\
AFSfl? <J'>6
• 1 j[i "iJ '"i *•* ^? ^ ^
•TR'04?^^'*
P? 'Gift* J'«t
jl. iJ C3 ^ -^ .* ^ *^
1A
' ! ??5U'.>» 3
f S ?»-Swv*S
1C
r.
^s?'5-»';vrf
0
in
j1*
/, -f.'^ ' i
0
Q
0
6 ,-O'?.: 1
0
"* A
** ^ ? ": 7 c i ** '
('rrW^? I
<>--Hj!:. !
w-'."!"1;..' I
0
0
0
5 "5
0
.3S
'iA
•«»«
ft*: '':3'J^i!
'; M)5 •' t
f'^^'JV 1
:
»<-:----f-?Z
ii
•.•':0":.~2
6'J- .)'.:•-'?
6v;> > .;;>
6*;o??2
n
£.'(.'
f
IA
li2A
0
•
2 ft
>
2C
?L'
3-4
(
fc'?0i,"?i?
i)
^'-V!'";!1 ?
0
^•5736 J3 J
E?
s ??vy5o
? s r ;? 'jo5 ?
j^ ^" V f* *"**Ja*% ff
8i ?'*??is)
&V/'<i *t I 5
i?S /A^iJO'S
«S?4?.2*.)J
i'!:75U^OO
«>?&(*? I *i
B* /:J*tl IV
�DATE
690522
690522
690522
690522
690522
690522
690522
690522
6S0522
690522
690522
690522
690524
690524
690524
690524
690525
690525
690525
690525
690526
690526
690526 /
690526
690526
690526
690526
690526
690602
690602
690602
690602
690602
690602
690602
69O602
690602 •
6S0602
690602
690602
690602 .
690602
690602
690606
690606
690606
690606
690606
690606
690606
AGN
0
0
0
0
0
0
w
3
GALS
0
0
55
0
0
0
0
0
0
0
0
0
440
0
0
0
825
0
0
0
990
0
0
0
2000
0
2000
0
600
0
0
0
0
40
0
TYP
LEG
3C
30
C
1A
P
P
P
D
0
8
0
0
15
0
55
0
0
0
550
0
0
. 0
0
550
0
IA
P
P
(
C
6
3
IB
2A
2B
2C
20
3A
3B
3C
30
1A
2A
3A
4A
IA
2A
3A
4A
1A
2A
3A
4A
iA
IB
C
C
P
P
IB
1A
IB
1C
ID
IE
IA
2A
3A
4A
1A
2A
1A
2A
3A
4A
1A
2A
3A
4A
5A
IA
2A
UTM
BS739183
BS738178
8S742210
8S744215
8S745205
BS745200
BS750200
6S750215
BS735179
8S73518S
BS739183
3S738178
BR6184Q4
BP617398
3P640400
BS642395
BR604409
BP-612416
BP.620407
BP-619397
BR620407
8R619397
BR640403
8R643395
CRO50144
CR034180
C8050144
CR034i80
BR448455
BR445470
BR45049Q
BR480490
W465
.840
BS760023
BS759029
8S762030
BS763042
3S75203U
BS750040
BS764030
BS766038
35768038
BS766030
BR960230
BR938237
BP.935245
BP.947257
BR956251
3R960230
RR93B237
*
�MISSIONS STARTING IN
BINH DINH
i AjfcJ"*"tf'5feA*A*J,
*
ap ^
^^ - 7 ^ 7
1 ^ 7 7
D«TF
690606
690606
690606
690608
690608
690608
690608
690608
69060?
690608
690608
690608
690608
690608
690608
690611
690611
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690615
690621
690621
690621
690621
690621
690628
690628
690628
AGN
B
0
W
B
GALS
0
0
0
55
0
0
0
0
0
55
0
0
0
0
0
275
0
110
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
TYP
C
3A
4A
C
F
C
0
0
100
P
0
0
0
0
0
1900
0
0
5A
6A
1A
2A
3A
4A
5A
6A
1A
18
1A
IB
1C
ID
2A
2B
2C
3A
' 3B
0
B
3A
4A
54
1A
2A
C
3C
30
4A
4B
4C
40
5A
5B
5C
5D
5t
5F
6A
68
6C
60
1A
2A
3A
4A
5A
1A
IB
1C
UTM
BR935245
BR947257
BP.956251
BS715205
BS717223
BS723265
BS720217
8S723214
BS722220
BS716228
8S712224
BS715220
BS714217
BS718214
BS713205
8P368460
BR300455
BS618134
BS618192
BS621192
BS62U34
BS676211
BS67S214
BS677210
BS681202
BS681204
BS685204
. ES685202
BS731060
BS732068
BS734068
BS733060
BS725050
BS725056
BS730058
BS730056
BS728055
BS728050
3S730050
BS733050
BS733052
3S730052
BR754937
BR751941
BS751947
BR755945
BR756941
CF045137
CR017189
CR042198
.
�MISS IONS STARTING IN
8INH DINH
#* * £ £ * ( * *
*#:::*
OME
690628
690628
690628
690628
690628
6S0630
090630
690630
690630
690630
690630
690630
690630
690702
690702
6?0702
690702
690704
690704
690704
690704
690704
690704
690704
690704
690704
6907O4
690706
690706
690706
690706
690706
690706
690706
690706
690706
690706
690706
690706
690706
690706
690707
690707
690707
690707
690707
690707
690703
69070C
690708
AGN
0
0
0
0
0
0
3
0
0
0
GALS
0
0
0
2600
0
3000
0
0
0
0
0
0
0
2700
0
0
0
1600
0
0
0
0
0
2800
0
0
0
3000
0
0
0
0
0
0
0
2600
0
0
0
0
0
800
0
0
1500
0
-. 0
3000
0
0
TYP
LEG
10
2A
26
P
1A
IB
D
1A
IS
1C
10
2A
2B
2C
20
0
D
D
D
D
0
D
P
1A
IB
2A
2B
IA
IB
1C
2A
26
2C
IA
IB
1C
10
1A
IB
2A
2B
3A
3B
4A
4B
IA
IB
2A
26
3A
36
1A
IB
1C
1A
IB
1C
1A
IB
2A
UTM
CR056163
CSO46U9
CRQ19190
8P.83204O.
BQ851961
CR057145
CR03li9<i
CR04<?200
CR059184
CRQ&3148
CR029193
CR046199
CR059182
BR814135
BR799050
BR816134
BR801050
CR051146
CR028193
CP038196
CRQ55164
CRO49144
CP025191
BR837042
BQ856964
BR840042
BOB 5 9 5
86
CR053157
CR034195
CR854159
CR036196
CR04419S
CR057173
CR 0 6 19 9
4
CR058177
8R370460
BR353451
BR325463
BR300454
BR285455
BP277470
8 R5 0 6 6
44
BR580457
BR617473
BR697520
BR704483
BR748458
CR020126
3R992181
CR023128
�UNCLASSIFIED
M I S S I O N S STARTING IN
!G
BINH DINH
PROV NO. =
^^^^(jjrs^^csj;^:^:^~$
04T?
690708
69070C
690708
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690710
690715
690715
690715
690715
690715
690715
690715
690715
690715
690715
690715
690715
690716
690716
690716
690716
6907IB
690718
690720
690720
690720
690720
690721
690721
690721
690721
690722
690722
0
0
GALS
0
0
0
15
0
0
0
50
0
0
0
0
0
0
10
0
0
0
35
0
0
0
1500
0
0
0
0
0
1500
0
0
0
0
0
2000
0
0
0
3000
0
6000
0
0
0
3000
0
0
0
2200
0
TYP
C
C
C
C
D
P
P
D
0
C
P
LEG
26
34
3A
3B
1A
2A
3A
4A
1A
2A
3A
4A
5A
6A
7A
1A
2A
3A
4A
1A
2A
3A
4A
1A
IB
2A
28
3A
3B
1A
IB
2A
2B
3A
38
1A
IB
2A
2B
1A
IB
1A
13
2A
28
1A
IB
1C
10
1A
IB
UTM
BR998182
CR025129
CR000133
BR640926
BP642726
8R640729
SR642929
BP633763
BR635956
BR638760
BR640964
BR638966
BR634967
BR633965
BR638948
BR.638946
8R640946
3R640946
ER634939
6P640930
BP640933
BR635933
CR043135
CR015188
CR042134
CR01418B
CR042133
CR014188
BR576442
BR619468
BR577440
BR622465
BR578433
BP. 62 3 46 3
CR001079
Cf.001170
BR999079
BR9S9170
BR388370
BF.322275
BS724150
BS742050
BS74705O
PSS747150
8S759153
8S759050
BS732050
BS732150
CR055148
C F 0<; 5 1 1 3
�UNCLASSIFIED
MISSIONS
OftTF
690722
690722
690722
690722
690725
690725
690725
690725
690801
690801
690801
690801
690801
690801
690802
690802
690802
690802
690802
690802
690802
690804
690804
690804
690804
690804
690804
690804
690804
690804
690804
690806
690806
690807
690307
690807
690807
690810
690810
690810
690810
690810
690310
690810
690811
690811
690311
690811
690811
690811
STARTING
AGN
i-}
0
w
B
B
B
0
0
0
8
B
0
IN
GALS
0
0
0
0
5000
0
0
0
605
BIMHDINH
TYP
D
P
• o
0
0
1155
0
330
0
0
0
0
0
0
100
0
0
0
0
0
10
0
0
0
550
220
165
0
0
0
1500
0
0
0
3000
0
0
1210
0
0
0
0
0
p
P
C
c
c
c
c
c
c
c
,
P R O V NO.
LEG
1C
10
2A
26
1A
IB
2A
2B
1A
2A
3A
4A
IA
2A
1A
2A
3A
4A
5A
6A
7A
1A
2A
3A
4A
5A
6A
1A
2A
3A
4A
1A
IA
1A
2A
3A
4A
1A
IB
1C
ID
1A
IB
1C
1A
2A
3A
4A
5A
6A
UTM
CR053154
CR095123
CR058153
CRQ<;4127
BS752150
BS75205O
BS737050
8S737150
3R629459
BR618429
8R630420
8R638425
8P628430
8P634437
BR980243
8R980245
3R990241
BR989246
8R988247
BR9S4247
SR984246
BR676195
BR672200
BR672207
BR675210
3R675207
3R678196
BR755099
BR754092
BR 754100
BR755090
BR685360
BR620330
BP 62 7 4
40
BR637434
BR634447
BR641445
3R270840
5R320770
BR320730
BR400690
BP260700
BR2 70770
BR310330
BR724527
BR727526
BP726523
BP73152 7
BR732524
BR728520
�.MISSIONS ST4RT IMG IN
OATE
690811
690311
690811
690811
690811
690811
690311
690811
690311
690811
690811
690811
690811
690811
690811
690811
690811
690811
690811
690815
690815
690815
690815
690815
690315
690815
690815
690815
690315
6S0815
690815
690815
690815
690815
690815
690815
690815
690815
6S0815
690315
690815
690815
690824
690821
690824
690824
690824
690824
690824
690824
' AGN
0
B
GALS
0
0
0
220
0
0
0
2000
0
0
0
3
8
3
8
B
B
B
«
0
2000
0
0
0
0
0
0
0
10
0
0
0
35
0
0
0
10
0
0
0
35
0
0
0
15
0
0
10
0
0
0
150
0
0
0
100
0
0
0
BINH DIMH
************
TYP
L £G
7A
8A
9A
IA
C
2A
3A
4A
IA
C
18
1C
10
1A
C
IB
1C
ID
C
C
C
C
C
C
C
C
2A
28
2C
20
iA
2A
3A
4A
IA
2A
3A
4A
IA
2A
3A
4A
IA
2A
3A
4A
1A
2A
3A
1A
2A
3A
4A
1A
2A
3A
4A
1A
2A
3A
4A
UTM
BR731524
BP.735518
BR736524
BR739522
BR748524
3P751529
BR749533
Bft2 70960
'
8R290830
BR320860
6R3 10790
BR425685
BR44075O
6R410750
BR400680
BR30O690
8R290T70
BR310T9Q
BR31084O
BS6.89210
BS691211
BS687216
8S689218 |
&S681234
8S682Z26
BS685235
BS686226
BS662236
BS666235
8 S 66323 8
8S665r238
B:S65 1.194
8S654196
BS648205
SS652E06
BS637145
BS640137
BS&39144
&S618162
8S618164
BS622161
BS622164
BS911099
BS915098
3S919090
BS904094
BS911099
3S915098
BS919090
8S9i04094
�06.TE"
690824
690824
690824
690824
69J827
690827
690829
690829
690829
690S29
690830
690830
690330
690830
690830
690830
690830
690903
690903
690903
690903
690905
690905
690905
690905
690905
690905
690905
690905
690S05
690905
690905
690905
690905
690906
690906
690906
690906
690914
690914
690915
690915
690915
691018
691018
69101P
691013
691018
691018
691018
AGN
-Q
0
0
0
0
0
B
GALS
50
0
0
0
3000
0
1700
0
0
0
475
0
0
0
0
0
0
1650
0
0
0
2915
0
0
0
0
0
130
0
TYP
C
3A
0
0
0
0
0
4A
1A
IB
1A
IB
2A
2B
1A
2A
3A
n
D
p
'
p
p
c
0
0
0
0
0
715
0
0
0
3000
0
275
0
0
3000
0
0
0
3000
0
0
LEG
1A
2A
p
D
P
43
5A
6A
7A
IA
2A
3A
4A
1A
2A
3A
4A
5A
6A
1A
2A
3A
3B
3C
4A
5A
1A
2A
3A
4A
1A
IB
1A
2A
3A
C
1A
C
IB
2A
28
1A
IB
1C
j
UTM
BS908114
BS908119
BS913117
BS912114
BR394368
BR325270
CR043134
CR013188
'
CR035132
C°006186
BR980243
BR980245
BR 99 0241
BP.989246
BR988247
BR984247
8P.984246
BR922242
BR927236
BR946256
BR941262
BR9 79243
8R984220
)
BR981200
BR591200
BR999215
BR992247
3S698156
BS699148
BS678164
SS700164
BS700158
BS697166 .
BS670150
BR932222
BR943206
BR950210
BP.937227
BR894017
BR958178
BP840301
3R850305
BR851290
BF480960
BP.555873
3R480970
BR570870
BR263700
BR268770
BP330C70
�UNCLASSIFl€&
M I S S I O N S STARTING IN
D.'TF.
69 10 IS
691013
69101B
691024
691024
691024
691024
691024
691024
6910Z6
ftC,N
P
0
691026
0
691026
6? 1026
691031
691031
691031
f.91031
691109
691109
691109
691109
691109
69110?
691109
691109
691112
691112
691112
691112
691114
f,
e
H
3
a
3
3
8
3
3
8
691114
691114
691114
691114
691121
691121
691121
691121
691130
691201
691201
691203
691205
691205
691205
691205
GALS
0
B
0
a
0
o
rj
0
380
0
0
0
0
0
2600
0 -,__
0
0
3000
0
0
0
3700
0
0
0
25
40
30
45
50
50
40
50
3000
0
0
0
3000
0
0
0
0
3000
0
0
0
825
50
460
825
425
0
0
0
P R C V NQ. =
TYP
L6G
2A
28
2C
P
IA
2A
0
691026
691026
691026
691026
R I N H OINiH
C
..
C
C
C
C
C
C
C
C
C
C
C
C
C
3A
4A
5A
6A
IA
16
1C
ID
IA
18
1C
10
1A
13
1C
ID
1A
IA
1A
1A
IA
IA
1A
iA
iA
IB
1C
10
IA
IB
1C
2A
28
1ft
IB
P
P
P
F
P
1C
10
1A
IA
1A
1A
IA
IB
1C
10
UTM
BP300310
8R410670
6P350710
BS744140
6S74U3T
8S742130
SS746127
8S749130
6S748136
BR350740
BR410740
8R410690
BR360690
BR30O320
6R3 00910
6R330910
BP330820
BP350740
BR410740
6R36Q09O
8P410690
3R470150
BR48016O
BR5O314O
BR490130
BR51013O
8R52012O
BP530130
8R540120
8R26063O
BP 3 7 6 0
03
RR280830
BR200S30
BP250860
3R30O930
BS210020
8P 170960
8 R 25 0860
BR350900
8P35Q98O
BR210980
BP210900
8R577444
3S800140
asaooi4o
6R576437
6P980243
BP990245
RR988247
BR984246
i i M r i .5 s <; i F T - n
�MISS IONS START ING IN
DATE
691206
691206
691206
691206
691223
691223
700111
700113
700113
700203
70H203
700203
700203
700204
700204
700204
700204
700205
700205
700205
700205
700207
700207
700207
700207
700215
700215
7J0225
700226
700226
700226
700226
700226
700226
700226
700226
700236
700226
700226
700226
700226
700226
700227
700227
700227
70022?
700227
700227
700227
700227
AGN
0
0
n
0
n
0
0
Q
0
n
0
0
w
0
o
0
n
0
3INH OINH
************
TYP
GALS
LFG
F
1A
1430
P.
1A
165
165
P
1A
165
1A
P
550
F
iA
P
550
1A
•P
1320
IA
P
IA
990
0
2A
E
20
1A
0
2A
0
3A
4A
0
825
P
IA
0
2A
0
3A
0
4A
P
1100
1A
2A
0
3A
0
4A
0
P
660
IA
0
2A
0
3A
4A
0
P
110
IA
0
IB
105
c
1A
95
c
1A
0
2A
0
3A
0
4A
5A
0
0
6A
0
7A
0
8A
1A
70
c
0
2A
3A
0
0
4A
5A
• 0
0
6A
c
iA
55
0
2A
3A
0
4A
0
0
5A
55
c
IA
2A
0
3A
0
UTM
BR606451
5R598443
8R619464
BR612453
BP.931209
8R942215
8P840580
6R939224
BR931210
8P.800857
8R806859
8R612852
BR809849
6R659385
BR664336
BP.666379
BR662378
BR935230
BR943230
3 F 93 52 3 8
8K943238
BR647486
BR653483
BR649480
BR646485
BR470640
BR470760
BS720120
BR520940
BR530980
BR50O980
BR500950
3R510960
BP520970
8P540980
BR55O950
BF, 52 0940
BR560970
3R490000
BS50O020
BS490000
BS460000
BR490960
BR500950
BR56Q97O
&P 54 0980
BR530970
BR540970
3R57Q890
BR510940
)
�MISS IONS STARTING IM
naiF
700227
700227
700312
700312
700312
700312
700315
700315
700315
700315
700315
700315
700315
700315
700315
700315
700315
700315
700315
700321
700321
700321
700321
700324
700324
700324
700324
700325
700325
700325
700325
700326
7C0326
700409
700409
700409
700409
700409
700409
700411
700411
700411
700411
700411
700411
700411
700411
700416
700416
700416
£GN
BINH DIMH
****>•* »*-#***
GALS
TYP
LEG
0
0
0
330
4A
5A
P
1A
2A
3,A
4A
0
0
0
3
1700
C
IA
0
0
0
8
1900
IB
2A
28
C
IA
0
0
0
0
'
IB
1C
ID
IE
IF
1G
1H
11
0
0
0
0
W
275
P
0
165
;
P
0
0
0
0
110
P
0
0
0
0
60
C
0
0
50
C
9
0
0
0
0
T
100
C
0
0
0
0
0
0
'0
'
D
50
0
0
1A
2A
3A
0
0
0
C
4A
1A
2A
3A
4A
1A
2A
3A
4A
1A
IB
1A
2A
3A
4A
5A
6A
IA
2A
3A
4A
5A
6A
7A
84
1A
2 1.
3A
UTM
BR520930
3R510980
8K93022Q
BR936226
BR9492Q<;
BP940202
BP.6Q0010
BP.6U0200
8R660030
BS66O130
3 P. 47 938 3
BR480340
BR54030O
BP550270
8P530240
9R49O24Q
BP510200
BP 49 0090
8P.420100
8P93022O
BR936226
BR949209
BP940202
BP932202
BR939228
BR953216
BR948210
8R932202
BR939228
BP.953216
BR948210
BS710O97
8S718093
BP580700
SK6Q0700
BR59075Q
BP580770
BR560780
3P550790
3R550800
BR590770
BF.580790
BF600800
BR580840
BK4-80860
BP470890
BP460900
BR500900
BP590740
3R580740
�OATf
700416
700416
700416
700416
700416
700418
7J0418
700501
700501
700501
700501
700501
700501
700501
700502
7C0502
700502
730502
700611
700611
7C0612
703613
700620
700620
700620
700620
700626
70062&
700627
700627
700308
700824
70090G
700911
700912
700912
700912
700912
700<?15
700915
700915
700915
700925
700925
700925
700925
700927
7C0927
700927
700927
AGN
0
W
w
0
Q
'
0
H
0
0
0
0
3
3
3
B
3
GALS
0
0
0
0
0
150
0
150
0
0
0
0
0
0
180
0
0
0
275
0
110
165
160
0
0
0
55
55
165
110
TYP
LEG
4A
5A
6A
74
8A
IA
2A
1A
2A
3A
4A
5A
6A
7A
IA
2A
3A
4A
1A
2A
IA
1A
IA
2A
3A
4A
IA
1A
1A
1A
tA
IA
1A
C
C
C
p
p
p
C
p
p
p
p
1210
p
220
385
165
p
p
p
1800
C
IA
IA
IB
2A
2B
1A
IB
1C
10
1A
IB
0
0
0
B
2500
C
0
0
0
B
2700
C
0
0
0
3
1600
0
0
0
•
C
1C
10
1A
IB
1C
ID
UTM
3R570750
BP58Q720
BR500380
BS42GQ20
8S410030
8R580859
3R478970
BS490000
BR500970
BR510970
BR52096Q
BS520950
BS530950
BS530940
6P.53&95Q
8 R 52 0950
8R5ZO960
8 R 53 0960
6P. 56443 9
8R&31430
8R564439
BP 63 1430
RS694O74
BS702O78
BS7O5O75
8S698069
3R564439
BR631430
8R564439
8R631430
BR93O260
BR 5.9 0.45 5
8R93026Q
&P 809 36 5
BR6»5UO
8R602210
BR477160
8R3-.8O28O
8R57O863
B» 51 094 4
BR490958
3S416033
eR520030
3P.520220
BP55-C030
Bft520030
3P.5 10640
8R610340
6^6.20680
8 P. 5906 30
|
�UNCLASSIFIED
MISSIONS
DATE
700927
701010
701010
701010
701010
701010
701012
701012
701012
701012
701012
701219
701219
70121?
701219
710123
710128
710126
710128
STf-RTING
iGN
8
3
B
B
B
B
3
B
B
R
IN
G£LS
0
2700
0
0
0
0
2500
0
0
0
0
45
25
25
25
25
25
25
25
PROV NO. =
BINH DINH
TYP
C
C
S
s
s
s
s
s
s
s
LPG
IE
1A
IB
1C
ID
IF
1A
IB
1C
10
IE
1A
1A
1A
1A
1A
1A
1A
1A
UTH
BR51G840
BR470150
BR340240
8P360280
BP480180
BR470150
BR520030
3R550030
BR590020
BR520200
BR520030
3R590440
BR596438
BP619458
BP612465
BR 59 0446
BR59643B
8R61945B
8R612415
7
�NREC= 16771
NREC= 16771
NPPOV=
NPP.OV=
441
441
NZREC=
NZREC=
928
923
UNCL.'-SSIFHO
�M I S S I O N S STARTING IN
DATE;
AGN
651014
651014
651106
651113
651113
651114
651114
651117
651121
651130
660124
660124
660125
660125
660126
660126
660126
660126
660203
660203
660206
660206
660206
660206
660222
660222
660222
660222
660223
660223
660417
660417
660417
660417
660419
660419
660419
660419
660419
660419
660419
660419
660419
660420
660420
660420
660421
660421
660424
660424
0
0
0
0
0
0
0
0
n
0
GALS
2000
0
1000
2000
0
2000
0
1000
2000
1800
6000
0
3000
0
2000
0
0
TYP
p
D
C
C
D
D
0
P
0
D
0
0
0
B
B
3000
0
3000
0
0
0
2000
0
0
0
3000
0
Cl
Q
0
0
n
0
2000
0
0
0
2000
0
0
0
3000
0
0
0
0
2000
0
0
3000
0
2000
0
PROV NO. =
PLFIKU
D
D
0
C
n
P
D
L5G
1A
IB
1A
1A
IB
1A
IB
1A
1A
1A
1A
18
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
iC
10
1A
IB
1C
ID
1A
IB
1A
IB
1C
ID
1A
IB
1C
ID
1A
IB
1C
r
D
C
10
IE
1A
19
1C
1A
18
1A
IB
UTM
BR^20520
BR389447
YS840245
3R220520
BR300455
BR220520
BP300455
YA840250
YA840250
YA840250
YA890030
YV920960
YV920980
YA380000
YV915960
YV9 15980
YA900010
YA895O25
YV380995
YV92096O
YV92C960
YA920O20
YA880030
YV880960
YA877035
YV881992
YV3729S2
YV862935
YA880O40
YV940970
YAS55554
YA8 59556
YA855524
YA864517
YA856555
YA872555
YA865516
YA348521
BR215515
BR225495
BR 1605 15
BP.075'345
BR085570
BR195520
BR247439
8R19559rf
YA&75553
YA870492
YA87650i)
YA876573
8
�M I S S I O N S START ING
DATE
iA tjn!
660425
660425
660426
660426
660426
660426
660501
660501
660501
660501
660506
660506
660506
660506
660508
660508
660515
560515
660515
660515
660525
660525
660525
660525
660530
660530
66J530
660530
660530
660621
660621
660621
660621
670420
670420
670421
670421
670422
670422
670429
670429
670506
670506
670508
670503
670508
670508
670509
670509
67050*7
0
IN
0
GALS
2000
0
2000
0
0
0
0
1000
o
a
0
0
0
0
0
a
0
0
0
4000
0
0
0
3000
0
3000
0
0
0
1000
0
0
0
2000
0
0
0
0
2000
0
0
0
2790
0
1860
0
0
1860
n
. 0
2550
0
0
1500
rt
w
0
2790
0
2790
'•0
w
1860
V4
1860
0
PLEIKU
************
TYP
L EG
c
1A
IB
r;
1A
IB
2A
28
1A
D
IB
2A
28
1A
D
IB
1C
ID
0
1A
IB
r
1A
IB
1C
10
D
1A
IB
1C
ID
D
1A
IB
1C
ID
15
1A
D
IB
2A
28
1A
D
IB
D
1A
IB
1A
r
IB
o
IA
18
1A
D
18
0
1A
IB
1A
r
113
p
IA
IB
D
1A
UTM
YA382508
YA882579
BR 16051 3
BR075545>
BR075547
8R08557Q
Yi897505
YA897580
YA893505
YA893580
ZA155070
ZA175069
ZA168O37
ZA153038
YA891505
YA891583
ZA153070
ZA150i)30
ZA188O43
ZA190.075
ZA140033
ZA164037
ZA190072
ZA190045
ZA140070
ZA135Q32
ZA171038
ZA163075
ZA162063
YA860560
YA887543
ZA145039
ZA189050
BR170480
BR140400
YA750500
YA800460
BR150480
SR140400
BR 13 0490
BR130400
BR1 10490
3R080400
YA730440
YA730270
YA699437
Y&699273
YA710438
YA710262
YA717269
�DATE
670509
670511
670511
670512
670512
670512
670512
670515
670515
670515
670515
670516
670516
670517
670517
670517
670517
67U517
670517
670524
670524
670524
670524
670613
670613
670715
670715 .
670715
670715
670716
670716
670912
670912
671006
671006
671007
671007
671024
671024
671024
671024
671027
671027
671103
671103
671105
671105
671106
671106
67110R
ft ON
W
W
GALS
0
3720
0
TYP
1860
n
D
0
4
0
0
W
W
W
W
1860
0
2760
0
2590
0
2790
0
2660
0
2250
0
0
0
1900
D
r
D
D
p
0
D
0
0
1950
•D
0
0
W
0
w
n
n
0•
W
W
w
w
w
0
1860
0
2000
0
2700
0
2600
0
1500
0
2000
0
3000
0
3800
0
0
0
2900
0
3750
0
4000
'••o
4000
0
2 £50
C
C
p
D
0
D
0
C
p
D
LEG
18
IA
18
1A
IB
IA
13
1A
IB
1A
13
IA
IB
1A
IB
1A
IB
2A
2B
IA
IB
IA
18
IA
IB
14
IB
IA
IB
iA
18
IA
18
1A
IB
1A
16
1A
IB
2A
2B
1A
IB
14
IB
D
r
D
1 A
IB
1A
IB
1A
UTM
Y4817131
YA720438
YA720264
Y 469 043 6
YA690257
YA797123
YA685265
8R125490
BR 09 5400
YA75Q50Q
YA790460
YA697268
YA8O3127
YA98O473
Z A 05949 3
ZA021587
YA959587
Z A 02 3 58 4
YA957584
6R16CH80
8R140403
B«U60480
BR14Q4-QQ
YA710440
YA710280
YA7O1437
YA7CU270
SR130470
SR14O520
ZA023582
YA9S2582
BR 145400.
8R140280
ftP. 13 5464
B.R1 17280
BR137463
SRI 19280
YA6C6263
Y£ 76 02 10
YA762213
Y/ 1 799108
YA725433
YA725267
YA713437
YA713274
YVfc82960
YV874790
YVS64941
YV873763
Y#718433
�0/iTF-
671108
671115
671115
671117
671117
671113
671118
671120
671120
571121
671121
671126
671126
671129
671129
671204
671204
671207
671207
671203
671208
671209
671209
671210
671210
671212
671212
671219
671219
671219
671227
671227
630111
680111
680114
680114
630116
6S0116
680118
680118
680118
680118
680122
630122
680124
680124
680126
680126
680127
680127
AGN
GALS
TYP
0
W
0
0
0
n
0
0
w
w
w
w
0
w
w
n
•A
X
w
4000
0
3000
' 0
3400
0
2150
0
4000
0
3000
0
3000
0
2600
0
3000
0
3000
0
3000
0
3000
0
2700
0
2000
0.
0
2600
0
3000
0
3000
0
6000
0
n
r>
P
r
0
D
r
D
D
D
0
D
0
D
D
0
C
0
•d
0
0
w
0
VJ
850
0
5000
0
7900
0
7970
0
7650
0
4000
0
P
D
C
D
0
C
LEG
IB
IA
16
1A
IP
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
18
1A
18
IA
IB
1A
IB
IA
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
18
1A
IS
1A
IB
UTM
YA718265
YA6S3436
YA6S3260
YA927000
YV933347
ZA021580
ZA049508
YA938080
YV955%7
YA717438
YA715274
YV912960
YV913740
YV928964
YV927792
Y 669 843 7
YA705260
YA704438
YA707269
YA924000
YV924810
YA728440
YA728275
YV911980
YV912320
YA731439
YA729269
YA694214
YA766219
YA805140
BR091429
BRO91280
YA939080
YV939398
YV928950
YA350073
YV900976
YV901810
YA928003
YV932830
Y4928003
YV932830
YA9350aO
YV935917
YA913003
YV916830
YV931993
YA348068
YV935960
Yf935014
I
�DATE
680127
680204
630204
680204
680204
680206
680206
680317
680317
680320
680320
680323
630323
680422
680422
680424
680424
680503
630503
680507
680507
680519
68051<5
680519
680528
630528
680606
630606
630614
680614
680617
630617
680718
680718
680718
680816
630817
680817
680617
680617
680820
68J820
680820
680820
680828
680828
680828
680628
68002C
630912
4GN
GALS
TYP
0
D
1000
P
0
W
6000
r
0
0
4750
D
0
W
6000
W
6000
c
0
D
0
0
4700
C
0
W
3000
D
0
W
6000
D
0
H
60CO
0
C
6000
D
r>
0
W
27CO
P
0
0
W
6000
C
0
W
5000
D
0
W
3000
C
0
W
6000
D
0
W
3000
•ft
0
0
330
440
0
0
0
275
0
0
0
110
W
'220
B
W
W
W
W
0
55
0
130
P
P
P
F
P
s
P
r
LEG
1C
1ft
13
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
18
1A
IB
1A
18
iA
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
1A
IB
1C
ID
1A
IB
1C
ID
1A
1A
IB
1A
IB
1A
UTH
YA854072
YA931026
YA869071
YA931O26
YA931026
YA867O57
YA803198
YA922004
YV922840
YA905XH4
YV905S34
YA899O10
YV899840
YA901010
YV901850
YA72544Q
YA72826H
YA710270
YA814143
YAa93Ki2O
YV 89 3 83 5
YA7O8268
YA773222
YA81Q128
YAT07A38
YA730270
Y ATI 543 8
Y ATI 5 270
YA695436
YA695280
YA885O03
YVA75820
YA910013
YA861047
YA814138
4R783508
AR 794464
ARSOO477
AR812477
A F 804 46 3
ART'S 35 13
Afi8055t>6
AR802504
AR791510
BF039539
BP162523
BR 174526
AR785356
4P.785345
AP813352
�UNCLASSIFIED
M I S S I O N S S T A R T I N G IK
DATS
680912
680916
'630916
680917
630917
680917
630917
630919
63J919
680919
630919
680919
680919
630919
680919
6809196S0921
630921
630923
680925
630925
680925
630925
630925
680925
630925
680925
630925
680925
630925
680925
680925
680925
680925
68092?
631003
681004
681004
631005
631005
681005
631011
681011
681011
631011
631018
631013
6310ld
631018
681018
AGN
8
B
W
B
3
3
8
W
«
rt
W
W
sJ
w
rf
w
u
B
B
W
W
GALS
0
1700
0
100
0
350
0
80
0
110
60
0
110
0
55
0
1200
0
110
100
0
50
80
0
0
0
40
0
0
0
40
0
0
0
550
100
1000
0
1200
0
0
220
0
0
0
440
0
0
0
0
PROV NO.
TYP
C
5
s
LcG
18
1A
IB
1A
18
1A
IB
P
1A
IB
C
F
1A
1A
IB
P
1A
IB
1A
P
IB
S
P
P
P
P
P
P
S
s
P
P
P
P
IA
IB
It
1A
IB
iA
1A
IB
1C
ID
iA
IB
2A
2B
1A
IB
2A
2B
1A
1A
1A
IB
IA
IB
1C
IA
IB
2A
2B
1A
IB
1C
ID
1 £-
UTH
AP813360
BR200528
BP280469
AR930497
8R095551
.SF930497
BPOS5551
AP.790360
4R790340
BR130270
3R060540
BR100550
AR738517
AP740517
AR740517
AP742517
BR2 54475
BP243482
ZA27010Q
AR762517
AR765517
AP.721461
AR781483
AR783483
BR783485
8R781484
AR7834-91
AR787491
AR787494
AR783494
AR803503
A.R&065.03
AC806506
AR8045O6
YA980140
AR9O7268
AR 790360
AR79034Q
AR79O340
AR3I3340
AR813360
If 1230470
ZA232470
ZA232460
ZA230460
ZA223532
ZA223540
ZA233536
ZA234530
ZA227523
�PAT?
681023
681023
681023
6<31Q23
681023
681023
681023
681023
681023
631C23
631023
631023
681024
681023
681029
681030
531101
631101
681101
631101
631101
631101
681101
681101
681101
631102
681102
681104
631104
631106
631109
681109
631109
681109
631123
631124
681125
681125
681125
681125
681125
681125
681126
6S1201
681212
681212
681212
681212
690110
690110
AGN
W
GALS
110
TYP
P
0
W
W
W
W
w
w
w
vJ
W
H
M
W
ill
ft
0
w
w
B
W
w
w
rf
0
0
0
220
0
0
0
110
0
0
0
100
100
100
100
100
100
150
3000
0
0
0
0
0
100
100
950
0
200
5000
0
0
0
100
300
550
0
0
0
0
100
200
500
220
0
• 0
0
5000
0
P
P
C
P
P
P
P
P
P
C
p
p
F
P
D
P
P
P
LEG
1A
IB
1C
ID
1A
18
1C
ID
1A
IB
1C
ID
1A
1A
1A
1A
1A
1A
1A
1A
IB
1C
ID
IE
IF
IA
1A
IA
IB
14
IA
IB
2A
2B
1A
1A
IA
IB
2A
p
p
P
D
C'
23
2C
1A
1A
14
1A
IB
1C
ID
IA
19
UTM
4R783491
AP785491
AP785493
AR783493
AR80250S
AR805505
AR80.6506
AR8035Q3
AR795509
AR798509
AR7S8512
AR795512
YA91Q170
YA846308
YA833172
YA905506
YA76032Q
YA830160
ZA160O60
BR217530
BR263465
BR200521
BR220520
8R250402
8R265472
YA860460
YA310300
AR960490
BR200520
ART90360
Y.A820240
YA787225
YA765219
YA737226
YA760320
AR800470
AR796490
AR756487
A R 30 049 4
AR308494
AP804498
Y4320030
AR780360
AP780350
ZA160063
ZA163064
ZA167067
ZA1 60067
YAC00302
YA750262
�Mi-i i r L ^-
M I S S I O N S STARTING IN
OATE
690110
690111
690119
690119
690119
690119
690120
690120
690126
690128
690128
690126
690128
690128
690128
690128
690128
690130
690130
690130
690130
690130
690130
690131
690131
690131
690131
690131
690131
690131
690131
69D203
690203
690203
690203
690203
690203
690204
690204
690204
690204
690204
690204
690208
69020s
6^0208
690214
690214
690222
690227
A;;NJ
GALS
PROV NO.
TYP
0
W
W
1 00
100
P
1A
C
1A
0
0
0
W
200
P
0
W
110
P
0
0
W
440
P
0
0
0
0
0
H
330
P
0
0
0
0
0
W
200
P
0
</i
770
P
0
0
0
0
0
W
330
F
0
0
0
'
0
0
W
0
0
440
0
0
0
0
0
3000
0
0
3000
0
W
400
W
660
LEG
1C
P
r
t>
p
p
IB
2A
2B
1A
IB
1A
IB
1C
IA
IB
1C
ID
IE
IF
1A
IB
1C
10
IE
IF
1A
IB
1A
IB
1C
ID
IE
IF
IA
IB
2A
28
3A
3B
It
IB
2A
26
3A
36
IA
IB
1C
1A
IB
1A
1A
UTM
YA695262
BR041562
BR122272
BK 14 0280
Bf 11 929 5
BP132306
Bf 159505
BRQ71564
AR 79 748 8
A R 80 049 5
AP.809495
AR880545
AR90052 8
AR900540
AR905554
AR89a57O
AR880545
AR880545
AP900528
AR90054G
AR905554
AR89857Q
A R 88 054 5
AP.817364
ARS15328
A R 88 054 5
AR9O0528
AP.V0054Q
AR9SO5554
APS98570
AftS80545
A.R&80545
AR9O0528
AR90054O
AR905554
AR898570
AR 8 6 054 5
4 R 8 6 054 5
.
AR9O0528
A f 900540
AP.9O5554
AR898570
A'R-8'8CT545
YA882016
YV&97930
YV908&35
Y/741318
YA 732480
A P. 7£- 0.330
A0880545
�UNCLASSIFIED
MISSIONS STARTING IN
PRDV NO. =
PLEIKU
j- ~f W ^ T- *f -V V
• •
**•
Jf a. V; * * ;*• •"* A
f-
DATE
690227
690227
690227
690227
690227
690302
690407
690407
690407
690407
690407
690411
690413
690413
690426
690426
690426
690426
690515
690517
690517
690520
690526
690530
690531
690610
690610
690610
690611
690611
690611
650611
690611
690611
690611
690612
690613
690616
690619
690620
690624
690624
693624
690624
690624
690624
690624
0.90624
690624
690702
AGN
VJ
8
W
W
W
B
W
W
W
W
W
W
W
W
W
W
0
W
W
0
GALS
0
0
0
0
0
550
440
0
0
0
0
770
220
330
220
0
0
0
600
275
0
275
550
110
550
220
0
0
300
0
0
0
0
0
0
165
300
660
610
470
. 420
3000
0
3000
0
0
,,0
0
0
715
TYP
F
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
C
C
P
LEG
IB
2A
2B
3A
3B
1A
1A
IB
1C
ID
IE
1A
1A
1A
1A
IB
1C
10
1A
1A
IB
1A
IA
1A
1A
1A
IB
1C
1A
IB
2A
2B
3A
3B
4A
1A
1A
IA
1A
1A
1A
1A
18
1A
IB
1C
2A
26
2C
1A
UTM
AP900528
AR900540
AP905554
AR89R570
AR880545
AQ920690
ZA223532
ZA223540
ZA233536
ZA234530
ZA227528
AR820480
AR820480
YA860450
AR760519
AP764519
AR762517
AR768517
AR820480
YA980964
ZA008964
YA860450
AR820480
ZA110560
A P. 82 0480
YA850190
YA830170
YA800230
AR793463
AR803483
AR805476
AR810478
AR813475
AR809470
AR806461
A R 82 0480
AR8204-80
AR 82 0-480
A P 82 0480
AP82Q480
AR82Q480
3R156474
BP12O30O
B P. 11 238 6
BR134356
BR137324
BR 12 53 00
BR121257
DPI 10240
AP020480
8
�D*TE
690713
6«0827
690627
690827
690827
691019
691022
691106
691114
700114
700114
700114
700114
700209
700209
700209
700209
700301
700301
700301
700301
700301
700301
700302
700302
700302
700302
700304
700304
700304
700304
700304
700304
700313
700313
700313
700313
700314
700314
700316
700316
700318
700318
700318
700318 •
700319
700319
700326
700328
700323
4GN
W
0
H
0
0
0
W
n
Q
0
0
0
0
0
'
0
n
0
0
GALS
660
3000
0
0
0
890
55
200
400
4000
0
0
0
3000
0
0
0
2700
0
0
0
0
0
2700
0
0
0
3000
0
0
0
0
0
2500
0
0
0
1100
. 0
300
0
1700
0
0
0
200
'. 0
200
2600
0
TYP
P
D
P
P
P
P
n
C
D
0
r>
D
D
P
C
P
P
0
LEG
1A
1A
18
2A
2B
1A
1A
1A
1A
1A
IB
2£
28
1A
IB
2A
23
1A
IB
2A
28
3A
3B
1A
IB
2A
23
IA
IB
1C
2A
2B
2C
1A
13
2A
2B
, 1A
IB
1A
2A
1A
IB
2A
2B
1A
2A
1A
1A
IB
UTM
AR320480
AO!J16680
AQ817770
ZA240063
ZA190063
ZA170060
YA740810
ZA215535
AR790520
AG770964
ZV190964
AQ770968
ZV190968
AQ390730
AQ30073U
AQ890727
A0800727
Z6240059
ZA190059
ZA190056
ZA240056
ZA240054
ZA190054
AQ770961
ZV190961
ZV190961
AQ770958
A0815680
A0813737
AQ815770
AG813770
A 081 3740
AQ810713
A0890724
A0800724
AQ896722
AQ300722
A0770921
ZV190921
3R220500
3R220510
AG890717
AQ800717
A0390719
A Q8 00 71 9
BR220500
BR220510
BR230510
ZA240041
ZA190041
�DAT £
700328
700328
700323
700328
70033D
700330
700330
700401
700401
700401
70 J 401
700411
700411
700411
700411
700413
700413
700413
700413
700413
700415
700415
700415
700415
700420
700420
700420
700420
700422
700422
700422
700422
700422
7C0425
700425
700425
700425
700507
700507
700507
700507
700507
700508
700503
70350S
70050S
& GN
0
0
0
0
^
W
W
W
W
ri
GALS
0
0
0
0
300
0
0
3000
0
0
0
1700
0
0
0
2600
0
0
0
0
4000
0
0
0
2700
0
0
0
2300
0
0
0
0
3000
0
0
0
3000
0
0
0
0
3000
0
0
0
TYP
P
0
n
D
LEG
2A
28
3A
3B
1A
2A
3A
1A
16
2A
28
1A
16
2A
26
1A
13
1C
D •
r
9
D
D
n
10
IE
1A
IB
2A
26
1A
IB
2A
28
1A
16
1C
2A
2B
1A
IB
2A
26
1A
IB
1C
2A
2B
1A
IB
2A
28
UTM
ZA240043
ZA190043
ZA240047
ZA190047
8R22050Q
3R2305O0
8R250510
AQ800734
A0890734
AQ800737
A 089073 7
4Q770950
ZV190950
ZV190947
AQ7T0947
A077O927
ZV223925
ZV190927
ZV19Q930
ZV770932
AU8 90747
AQ8Q0747
A080075i>
A089O750
A0844680
AQ8OOT50
A080O745
A0841630
A0 6 7 0
857
A 08 72 74 7
AQ8T2680
AC&686aO
AQS6877Q
A0874630
AQ874770
AC877770
AQ8T7680
A 086 5 630
AQ885720
A0869770
A0889770
A 088 9630
A0770939
ZV190939
A0770937
ZV1S0937
�NPEC =
17594
17594
MPRQV=
NP^OV=
218
213
NZREC=
NZR6C=
328
328
�DATE
661029
661029
661030
661030
661031
661031
661101
661101
661107
661107
661107
661107
6.61108
661108
661121
A61121
661124
661124
661124
661124
661205
661205
661205
661205
661205
661205
661205
661205
661210
661210
661213
661213
670109
670109
671003
671003
671003
671003
671003
671003
631119
681119
681119
631119
681119
681119
68111-3
700214
7C0214 '
700214
4GN
W
V*
w
w
c,
W
w
0
w
w
0
D
B
0
B
B
0
GALS
2700
0
3600
0
18CJ
0
2700
0
1800
0
0
0
1800
0
1800
0
1300
0
0
0
1800
0
0
0
0
0
0
0
1800
0
1800
0
2700
. 0
1600
0
0
0
0
0
3000
0
2000
0
0
2000
0
2000
0
0
TYP
D
0
0
C
D
0
D
D
n
D
D
C
c
c
c
c
c
L;G
IA
IB
iA
IB
1A
IB
IA
IB
I*
18
2A
2B
1A
18
1A
18
1A
18
2A
26
1A
IB
2A
2B
3A
3B
4A
4B
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
3A
3B
1A
IB
1A
IB
1C
1A
IB
1A
IB
2A
UTM
AP940075
BR025ai8
BR252005
3P16514Q
8R322255
8R285045
SR32025Q
BR160140
BG188798
BG064705
B 004965 8
88021592
6Q260950
BR305060
BP315110
B3258950
80300780
BQ330750
BQ330760
BQ3G079Q
AR943078
AR965058
AR982050
BR028020
BR023015
A9976043
BP955058
BR937072
BR330180
BQ260950
&P-315212
BR29O048
BQ440650
FVQ420710
BR081192
BP.083192
&R113147
BR1 20153
BP081192
BR117150
BR268270
BR340UO
8 R2 5 0260
BR160200
BP 12 0200
BP210260
BP.320100
BQ370586
BQ3B3526
BQ333526
�NREC= 17594
17594
MPPOV=
NPROV=
218
218
NZREC=
NZREC=
328
328
UNCLASSIFIED
UCiCLASSIFIED
�MISSIONS STARTING IN
DATS
661029
661029
661030
661030
661031
661031
661101
661101
661107
661107
661107
661107
661108
661108
661121
661121
661124
661124
661124
661124
661205
661205
661205
661205
661205
661205
661205
661205
661210
661210
661213
661213
670109
670109
671003
671003
671003
671003
671003
671003
631119
681119
681119
631119
681119
68111<?
681119
700214
7C0214
700214
4GN
W
TYP
D
GALS
2700
H
PHU BON
************
3600
0
D
0
W
0
1800
0
M
D
2700
0
Vi
D
1800
0
0
0
W
D
1800
0
W
D
1800
0
0
D
1300
0
0
0
W
n
1800
0
0
0
0
0
0
'
0
W
1800
0
0
0
1800
0
0
B
2700
. 0
1600
0
0
0
0
0
0
3000
0
o
2000
0
0
B
2000
0
0
201DO
0
0
D
c
c
c
c
c
c
LEG
IA
IB
1A
IB
1A
IB
1A
IB
14
18
2A
2B
1A
IB
1A
IB
1A
IB
2A
2B
IA
IB
2A
28
3A
3B
4A
4B
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
3A
36
IA
IB
1A
IB
1C
1A
IB
1A
IS
2A
UTH
AR940075
BR025018
BP252005
B0165140
BR322255
BR285045
3R320250
BR16Q140
BQ188798
BQ064705
BQO49658
BQQ21592
BQ260950
BR305060
BP.315110
B3258950
BQ3Q0780
BQ330750
BC330760
BQ300790
AP943076
AR965058
AR982050
BR028020
8R023015
A9976043
BP955058
BR937072
BR330180
BQ26O950
BR315212
BR290048
& 4 0 5
0 4 6 0
8O420710
BRO81192
BP.033192
BR 113 147
BP,12O153
BP081192
BP117150
BR268270
BR340110
BR250260
BF16020O
BP.12O200
BR 2 10260
BR32O100
BQ370536
B0383526
BQ333526
'
}
�MISSION'S STARTING IN
IG IN
AGN
700214
700214
700214
700214
700214
700214
700214
701008
701008
701008
701008
701008
701008
701008
701008
701008
70100S
701008
701008
701003
701008
701022
701022
701022
701022
701022
701022
701022
701022
701022
701022
701022
701022
701022
701022
701022
701022
0
PHU BON
************
TYP
LEG
GALS
0
2B
1000
C
1A
0
IB
0
1C
ID
0
2A
0
2B
0
C
1A
2900
0
IB
0
1C
0
10
0
IE
0
2A
0
28
0
2C
0
20
0
2E
2F
0
0
2G
2H
0
0
21
24 00
C
1A
0
IB
0
1C
0
ID
0
IE
0
IF
2A
0
0
2B
0
2C
20
0
0
2E
2F
0
0
2G
0
2H
0
21
0
2J
PROV NO. =
UTM
80370586
BP219050
3R2 00078
BP170O80
BP085178
BR005170
AR983120
AR970120
BR010170
BR030170
BR050750
BR030120
BR080170
BP090190
BR170100
BR200100
BR230050
BP210050
BP160080
BRl 10130
BROS0170
AP970120
BP010170
BR030170
BP050150
BR030120
AR970120
BR080170
BR090190
BR170100
Bfi.200100
BP230050
BR210050
BR160080
BP120120
BR110130
BP080170
UMCLCSSIF!:0
�-NREC= 18053
!MRcC= 18053
NPPOV=
NPP.OV=
20
20
NZREC=
NZREC=
67
67
UNCLASSIFIED
UNCLASSIFIED
�MISSIONS STARTING IN
flATF
651007
651007
651008
651008
651009
660204
660204
660309
660309
660312
660312
660318
660318
660318
660319
660320
660320
660320
660320
660323
660323
660323
660323
660328
660328
660323
660329
660329
660329
660329
660329
660401
660401
660404
660404
660404
660404
660408
660408
660411
660411
660411
660411
660411
660411
660417
660417
660417
660417
660427
AGN
0
0
0
0
0
n
0
0
0
0
o
0
0
0
0
n
n
0
PHU YEN
*#*#********
TYP
GALS
LEG
1A
1450
C
0
'IB
3000
C
1A
IB
0
IA
1800
C
5800
D
1A
0
IB
0
1A
1550
18
0
1A
1150
D
0
IB
1A
3000
C
IB
0
1C
0
1A
1700
C
1800
C
1A
0
IB
2A
0
2B
0
2000
1A
C
IB
0
0
1C
C
1A
2000
0
IB
2A
0
0
' 28
1A
3000
C
IB
0
0
1C
0
10
0
IE
2800
C
1A
IB
0
C
1A
3500
IB
0
0
1C
0
ID
1A
C
2000
0
IB
C
3000
1A
IB
0
2A
0
3A
0
4A
0
0
4B
2400
1A
C
0
IB
0
2A
2B
0
n
3000
16
UTM
BQ795960
8Q360770
BR950Q70
3Q920890
BQ773845
CQ272220
CQ237300
CR090005
CQ085887
CR040U5
CR040080
CC157335
CG116285
C0000300
CC255245
80750150
B0620150
BC750310
BQ820290
B0780643
BQ770605
30843614
CC092245
CC019306
CQ156266
BQ932348
3Q947576
3Q950660
3Q975637
C 0034652
CQ030630
BQ772897
80843763
CQ050640
CQ100550
C0050500
CQ000550
BC780850
80810770
BQ920520
8Q915460
80840540
BQ825520
BQ790600
BQ840580
CQ1C5930
CR090008
CQ075800
CQ095780
C0220210
1
�HISS IONS START ING IM
PHU YEN
**
* * * * * *
* . * * * !
DAT£
660427
660427
660427
660428
660428
660429
660429
660429
660429
660430
660430
660501
660501
660503
660503
660507
660507
660507
660509
660509
660512
660512
660609
660609
660719
660719
660720
660720
660730
660730
660920
660920
660920
660920
660928
660928
660928
660928
660923
661001
661001
661001
661001
670113
670113
670221
670221
67J224
670224
670302
AGN
0
n
0
0
0
0
0
0
0
0
n
0
0
u
0
0
0
n
0
TYP
GALS
0
0
0
•D
2000
0
3000
P
0
0
0
3000
D
0
3000
D
0
3000
D
0
D
3000
0
0
D
3000
0
P
1000
0 .
2000 •, ,..-_D.
0
950
D
0
D
900
0
2000
0
0
3400
C
0
0
0
C
2700
0
0
0
0
3600
c
0
0
0
1800
c
0
27QO
c
0
c
2280
0
f
2400
LEG
IB
1C
10
IA
IB
1A
18
ie
ID
1A
IB
1A
IB
1A
IB
IA
IB
1C
IA
IB
1A
IB
1A
IB
1A
18
1A
t8
1A
IB
1A
IB
2A
2B
1A
IB
1C
ID
ie
1A
IB
2A
2B
1A
IB
1A
IB
IA
IB
IA
UTM
CQ230210
CQ24026Q
CQ2 30260
CQ085255
C CO 00290
CQ230280
CQ220290
CQ1 90270
CQ22O260
CG170330
CQ1Q5207
CQOO0280
CQ080260
C0000277
CQ077250
CQ103240
C0110265
CQ182333
CQ000275
C00s80252
CQ190270
CQ230280
CQ220285
CQ210315
CR033130
CR040115
CR038115
CR045113
CR040115
CP037080
B0765370
6Q738765
BQ780820
BQ855768
BQ950570
BQ9807OO
BQ970570
CQ000710
CC040700
B0905900
88883965
3Q920985
BQ980850
CQ01Q690
3Q770620
BQ840767
BG783810
BQ930570
B096O610
BG960630
/
>
�DAT^
670302
670302
670302
670315
670315
670324
670324
670324
670324
670330
670330
670617
670617
670617
670617
670706
670706
670706
670811
670811
670825
670825
670825
670825
670825
670825
670825
670828
670328
670828
670828
670828
670828
670?23
670923
670923
670923
671001
671001
671001
671001
671001
671001
671001
671001
671001
671001
671001
671001
671006
4GN
0
3
0
0
3
0
0
0
n
0
B
GALS
0
0
0
750
900
2700
0
0
0
i860
0
2650
0
0
0
2000
0
0
1575
0
2610
0
0
0
0
0
0
1850
0
0
0
0
0
2400
0
0
0
3000
0
0
0
0
0
0
0
TYP
C
C
c
c
c
c
•c
c
c
D
C
0
0
B
0
0
2950
LEG
IB
2A
2B
IA
1A
1A
IB
2A
28
1A
IB
1A
IB
2A
28
1A
IB
1C
1A
IB
IA
IB
2A
28
3A
3B
3C
1A
IB
2A
26
3A
38
IA
18
2A
28
1A
IB
2A
2B
3A
3B
4A
4B
5A
56
6fi
68
p
1A
UTH
BQ960670
BG940650
BC970650
80790710
B0790710
00710890
BQ790920
B0760850
B08Q0900
BQ980680
CQ020620
B0789799
BQ843747
B0804798
BQ845758
BQ797908
BQ756873
BQ853768
BQ920305
C0045300
BQ870310
CGOO0350
CQ040310
BQ960300
BQ950320
BQ920340
&Q900330
BCS40600
80920660
BQ920588
BQ875655
BQ948586
B0910655
BQ865965
B« 86 7935
8«881900
BQ950820
BQ754210
BQ755259
8Q762229
BQ759212
BQ768229
BQ766210
80815175
BCdl5205
BOS20190
B0816215
BG845173
BC835185
RC373553
'
1
�MISSIONS STARTING IN
DAT£
671006
671006
671006
671007
671007
671010
671010
671010
671010
671011
671011
671011
671011
671011
671011
671022
671022
671023
671023
671023
671023
671027
671027
671027
671027
671223
671223
671223
671228
671228
671228
680202
680202
680202
680202
630411
680411
680411
630411
680513
680513
680515
630515
680515
680515
680515
680515
680515
630515
AGfJ
680524
w
B
g
3
0
0
\
B
0
0
0
0
0
0
GALS
0
0
0
3000
0
2800
0
0
0
3000
0
0
0
0
0
3000
0
3750
0
0
0
3000
0
0
0
2850
0
0
2850
0
0
1900
0
0
0
1740
0
0
0
3000
0
2700
0
0
0
0
0
PRCV NO. = 10
TYP
C
C
C
C
C
C
D
C
D
D
D
r>
•o
0
2750
D
•
LFG
IB
2A
2B
1A
IB
1A
IB
2A
2B
1A
IB
2A
26
3A
3B
1A
IB
IA
IB
2A
2B
1A
IB
2A
2B
IA
IB
1C
1A
IB
1C
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
1A
IB
2A
2B
3A
3B
4A
4B
1A
UTM
BQ901535
BQS65550
B0865520
8C785910
BC853768
BQ880580
B0910580
80880590
80910590
BQ920592
B0870592
8Q870588
B0920588
B 092 059 8
BQ875598
B0947599
B0924688
BQ875555
B0901535
BQS65534
BG890526
BQ888512
BQ834541
BQ886495
8Q850541
BQ983875
CQ003382
CQ006895
C0017901
C0002903
OQ982884
BQ883550
BQ901537
BQ860530
BQ890525
BQ863963
8Q371947
B0891883
BQ947835
C 01 6 6271
CQ176341
BQ983388
C0055395
BQ967382
B«950420
BQ911434
B0932438
00913446
BC913430
C0261240
�OVfE
630524
680524
680524
630531
630531
630613
680613
630613
6S0613
680613
680613
680619
680619
63062&
630626
680628
680628
680711
680711
680711
680711
630711
680711
680717
680717
680717
680717
630717
680717
680717
630723
680723
680723
680723
680729
680729
680729
680729
680729
680729
680729
630729
630730
680730
680730
630730
680730
680730
630801
630802
AGN
GALS
w
2000
TYP
0
0
0
0
0
0
•>
w
B
B
B
2800
D
2A
28
2C
13
C
C
c
0
0
B
0
0
0
1500
0
0
c
0
0
0
0
0
3000
0
3000
a
3000
0
3
B
0
0
0
0
2000
0
0
0
2000
0
0
0
0
•o
0
0
510
480
1A
16
1A
IB
1C
0
0
0
0
0
2000
0
2500
0
2000
0
3000
LEG
IB
2A
28
c
c
c
IA
IB
1A
IB
iA
IB
1A
IB
2A
2B
3A
38
iA
18
1C
2A
28
2C
20
IA
IB
IA
UTH
CQ223313
CQ269239
C0228307
CC300253
C0245290
CQ168280
CQ193310
CQ168347
C0166230
C0189310
C0164343
C0169236
CQ123293
60740862
BQ342738
BQ750870
80848740
SQ790910
80753684
80754858
BQ705811
90830770
BQ840745
9Q788908
8Q753b88
BQ74.93&5
BQ753856
BQ7S2311
30840775
BQ345745
IB
BQ736719
B0751855
B07J6719
B 075 135 5
IA
80820335
18
c
c
80355335
2A
2B
1A
B0875380
3Q&65280
B0820350
&Q855335
IB
2A
2B
IA
IB
2A
2B
p
p
3A
3B
14
14
BQ875380
B0865280
B0a<54570
BQ90257'J
B0855620
B0827623
80356570
BG822667
C0220300
C0220310
�M I S S I O N S STARTING
DATE
630803
680305
630805
630805
680805
680805
680805
680805
680805
680805
680805
680805
630805
680805
690805
680805
680805
680805
680805
630805
680805
630805
680805
680805
680805
630805
680805
680805
630805
680805
630805
6SOS05
680805
630805
680805
680805
680805
630805
630P05
630805
630805
680605
680805
630805
680805
680805
680805
680805
680805
630C05
S*GN
0
B
IM
GALS
55
82
0..
0
0
0
0
0
0
0
0
0
0
0
0
0
R
S
0
0
0
83
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
55
0
0
0
0
0
0
0
0
0
0
0
0
PROV NO. =
PHU Y£N
TYP
P
C
PG
1A
IA
IB
2A
2B
3A
33
44
46
5A
5B
6A
63
7A
7B
8A
3B
9A
98
IA
IB
2A
28
3A
3B
4A
4B
5A
5B
6A
6B
7A
76
8A
8B
9A
9B
IA
IB
2A
2B
3A
36
4A
4B
54
56
6A
68
7A
10
UTM
CQ034330
BQ986538
30985540
80991540
BG990543
CQQ00544
CQ000553
CQ008544
C0008557
COO 3 456 2
BC043562
CQ032577
CQ040579
C0054560
CQ062564
CQ053565
CQ061568
CQ068577
CQ068577
CQ084587
CQ084577
BQ983615
BQ985619
80992615
BQ993619
8Q919607
BQ928608
BQ920613
8Q928613
60887587
BQ880592
BC888587
BQ888592
BQ884505
90889504
BQ384516
B0889516
BQ930467
8Q930485
BG935465
BC936435
CC002602
CC004597
CCO 10600
CQ010607
C0020607
CQ023610
C 002 061 8
CC015619
CC013617
S"~"
'i
^,,
�MISSIONS STARTING IN
OiTE
630805
680806
680807
680812
680812
680813
680813
680S13
680815
680815
680815
680815
680815
680815
680815
680815
630815
680815
680815
630815
680815
680815
633815
680815
660815
6S0815
630815
680315
680817
630817
680817
630817
680817
680818
600818
63Q818 '
680821
680822
680823
680827
680827
680827
680828
680828
680828
63082!?
680831
680831
630831
630831
AGN
n
0
0
o
0
B
B
0
K
0
W
W
0
0
n
n
a
B
B
GALS
0
55
55
400
0
500
1400
0
50
0
0
0
0
0
0
0
0
0
0
0
0
0
25
0
0
0
0
0
55
55
110
80
138
2000
0
0
60
55
50
3800
0
0
3000
0
0
0
2000
0
0
0
PHU YEN
*.***********
TYP
L1G
78
P
1A
P
IA
E
IA
16
£
1A
s
c
IA
2A
IA
IB
2A
2B
3A
4A
c
P
P
P
P
P
c
P
P
P
c
r
c
48
5A
58
6A
6B
7A
7B
8A
1A
IB
2A
2B
3A
3B
1A
1A
1A
1A
1A
1A
18
1C
1A
1A
1A
1A
IB
1C
1A
16
2A
2B
li
IB
1C
2A
UTM
CQ014610
C0034380
CG121383
COQ37SOQ
C0020730
BG957768
B0950830
BQ880S9Q
CQ67346Q
C0655460
CQ650464
CQ655470
CQ655470
CQ701595
CQ706589
CQ71S592
CQ716597
CQ718584
C0748623
C0765596
CC757513
C0757582
CQ763575
CQ765787
CQ725664
CQ731676
CQ733664
CQ733669
CQ051308
C0051308
CP024228
CP024228
CPO 18294
BQ857610
80907600
3Q910640
CQ077342
CC051308
CP018294
3G900565
BQ855620
B03 80700
B0930520
8Q930480
B03505UO
B«850520
F5G980960
BQ880910
BC360S60
BP910000
»
�MISSIONS START ING IN
PHU YEN
DATE
630831
680917
680917
680917
630917
630917
680919
680923
630924
680924
630927
681004
631004
631004
681008
681008
681009
631009
681010
681016
681026
681027
631103
681103
681103
681104
631104
631104
681104
631106
681108
681205
631212
631212
681212
681219
681219
631219
681219
681220
681220
6S1220
631220
681220
631220
690101
690101
690101
690101
690103
AGN
a.
0
9
3
n
Q
0
0
w
C
0 '
o
0
n
n
0
0
o
0
0
0
0
w
n
n
0
•fi
it
n
GALS
0
3000
0
0
0
0
20
55
2500
0
55
385
440
495
55
55
55
60
65
100
100
90
2000
0
0
3000
0
0
0
3000
0
110
165
385
165
3000
0
0
0
2000
0
2000
0
0
0
275
0
3000
0
99
PRQV NO. = 10
£$
4
TYP
C
P
P
C
P
P
P
P
P
P
P
P
P
P
p
P
n
P
D
p
p
p
P
C
p
D
s
r
p
tec
2B
1A
IB
2A
2B
2C
1A
1A
1A
IB
1A
1A
1A
1A
IA
1A
1A
1A
IA
1A
1A
1A
1A
IB
1C
IA
IB
24
23
1A
IB
IA
1A
IA
IA
1A
18
2A
2B
IA
IB
1A
IB
2A
28
IA
IB
1A
IB
1A
UTM
BR950000
BQ920890
B&S80910
BC360960
6P910000
B0980960
CQ271343
C0271343
BQ316045
BQ280050
C0235273
BQ880880
B0950840
BQ390940
CQ074916
CQ077342
CQ077342
C0271326
C0271326
CQ271326
CQ271343
CQ271343
6Q667519
80721483
BQ760480
B0890453
3Q968383
BQ888450
BQ946416
9Q859978
8091 383 6
C0271343
CQ090780
CQ061693
CQ087638
B0864980
BQ86894Q
BQ896883
BQ942837
GP032130
CR037080
«Q858980
R 086 8 92 2
BQ8S0380
BQ942B3&
CP105760
CR 06 7742
BQ666515
B0714480
CC024228
�MISSIONS STARTING IN
OATS
690103
690106
690106
690107
690112
590112
690112
690112
690112
690112
690112
690112
690118
690224
690225
690301
690306
690309
69030S
690320
690321
690326
690514
690514
6<=0514
690514
690605
690605
690605
690605
690605
690605
690605
690605
690605
690605
690606
690606
690606
690606
690606
690606
690606
690606
69061T
690620
690620
690620
690621
690621
AGN
0
W
0
W
0
W
0
W
W
«i
W
0
W
W
W
0
0
13
W
W
0
G
0
PHU YEN
************
TYP
GALS
LEG
P
83
1A
220
1A
S
275
S
1A
P
385
1A
S
1A
495
0
18
0
1C
0
10
495
S
1A
0
IB
0
1C
0
10
P
330
IA
P
400
1A
P
220
IA
P
455
IA
P
450
1A
D
IA
3000
0
IB
P
500
1A
P
455
1A
P
375
1A
D
3000
1A
0
IB
0
1C
0
ID
3355
C
IA
0
2A
0
3A
0
•4A
0
5A
0
6A
385
C
1A
2A
0
3A
0
0
4A
1A
2640
C
0
2A
0
3A
0
4A
935
C
1A
0
2A
3A
0
4A
0
IA
550
C
2800
1A
C
0
IB
0
1C
1A
3000
C
0
18
UTM
CQ024228
80957782
CR075785
CQ024228
CR090460
CR085448
CP110460
CR110444
CP-043553
CR043549
CR069559
CR069549
CQ173337
C0121383
C 00 7 8 346
C0051308
C0051308
3R843033
BQ90187Q
C0173337
CQ1 73337
C0173337
80659960
BQ858940
80887880
BQ920852
CC072703
CQ066695
CQ079683
CQ08766Q
CQ096663
C0090690
CQ042714
CQ039706
CG046705
CQ047712
CQ052725
CQO52690
CQ065690
C6064726
C0015742
CQ011736
C0020723
CQ020729
CQ264298
BQ730200
BQ310180
8^810200
BC903608
BCJ918600
'
�UNCLASSIFIfcD
MISS IONS STSRTIN6 IN
DATE
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690702
690702
690708
69070G
690708
690708
69070 6
690714
690714
690714
690714
690714
AGN
0
0
0
0
:
n
0
B
3
PHU YEN
************
GALS
TYP
LEG
0
1C
0
ID
0
IE
• 2A
0
0
26
0
2C
0
20
0
2E
2F
0
2000
C
1A
0
IB
0
1C
0
ID
0
IE
2A
0
2B
0
0
2C
0
20
0
2E
C
1A
330
2600
C
1A
IB
0
0
ic
0
ID
0
2A
0
23
0
2C
0
20
3A
0
33
0
0
3C
2000
C
1ft
0
10
0
1C
0
ID
0
24
28
0
0
2C
2600
0
IA
0
IB
2600
C
IA
IB
0
0
2A
0
26
0
2C
3000
C
1A
0
IB
' 0
24
0
2B
3000
C
1A
PROV
UTM
B0937578
8C939554
B0950553
B0960553
BC928570
8Q924-560
6Q928552
BQ938549
8G950552
Bg691210
B 0 8 1 244
6
BQ662226
BC678249
60T08221
8Q7O4239
86926
0,1.1
S0677275
B0664259
80655263
COO23224
BCT63776
B0799777
80811771
BQS25751
60329745
60842719
BQ799712
BOS10730
BQ812738
BQ820765
808:74769
B09S5660
B09S0628
BQ994635
&Q948688
B0995617
BQ995535
B099Q610
CPO15126
BP989166
50710574
BC740588
BQ695592
BC750535
8Q730623
9C760890
B0786S01
BQ835771
30360770
RQ380610
NO.
10
�UNCLASS1H&0
MISSIONS
DATE
690714
690714
690714
690714
690718
690718
690718
690718
690720
690720
690720
690720
690720
690730
690731
690821
690824
690914
690914
690916
690923
690923
690925
690926
630926
690929
691005
691006
691023
691023
700129
700129
700129
700129
700129
700129
700129
700129
700129
700222
700222
700222
700222
700222
700222
700222
700222
700226
700226
700301
STARTING
IN
AGN
GALS
0
0
0
0
3000
0
0
0
3000
0
0
0
0
450
110
.275
275
0
0
0
0
0
0
330
145
210
150
275
385
330
2600
0
0
0
0
0
0
0
0
300
0
0
1900
0
0
0
0
935
0
2800
PROV NO.
TYP
0
0
0
0
0
q
w
Q
W
0
w
0
w
0
w
w
w
0
w
B
0
0
0
0
C
C
C
C
C
C
P
P
P
P
P
P
P
P
P
P
P
P
P
P
C
C
E
0
LEG
IB
2A
28
2C
IA
IB
2A
23
1A
IB
1C
2A
2B
1A
1A
1A
1A
1A
1A
1A
1A
1A
1A
1A
1A
1A
1A
1A
1A
1A
IA
IB
1C
2A
2B
2C
3A
3B
3C
1A
IB
1C
1A
IB
1C
10
IE
1A
IB
1A
UTf!
80960532
BQ940580
BQ975480
BQ954546
B0968568
B0995665
B0970605
BQ980660
3Q790912
BQ783903
BQ771900
BQ755894
8Q758880
CQ235273
CC1213S3
CQ268243
CQ266232
CQ271343
CQ271343
CQ271343
C0034367
CQ034367
CQ034367
CQ271343
C0271343
BQ974916
BQ974916
BQ974916
CQ235273
CQ235273
CQ269237
C0255248
CQ243276
CQ244278
CQ258250
CQ271239
CQ273240
C0260252
C0246279
BQ810200
B0820160
BQa00200
BQ685590
BQ720613
8G840630
BQ795597
BQ760610
€0263^33
CQ235193
CQ243275
=
10
�MISSIONS ST^PTIN'G IN
PHU YEN
^.Ay^^^f.^.^^
DATP
700301
700301
700301
700301
700301
700301
700301
700301
700312
700312
700312
700312
700312
700312
700318
700318
700318
700318
700319
70031P
700319
700319
700320
700320
700320
700320
700325
700325
700325
700325
700402
700603
700605
700606
700609
700612
700614
700615
700615
700616
700617
70061V
700701
700912
701005
701006
701111
701113
701117
GN
0
0
0
G
0
0
0
o
n
n
o
o
R
0
w
w
w
W
W
GALS
0
0
0
0
0
0
0
0
600
0
0
0
0
0
250
0
0
0
443
0
0
0
330
0
0
0
250
0
0
0
165
165
165
165
165
165
165
825
825
275
275
110
275
150
135
135
53
90
75
TVP
PROV NO.
;$
&
LEG
16
1C
2A
26
2C
n
p
p
p
p
p
p
p
p
p
P
p
P
p
p
p
p
p
p
p
p
p
p
p
3A
36
3C
1A
IB
1C
2A
26
2C
1A
2A
3A
4A
IA
2A
3A
4A
iA
2A
3A
4A
1A
2A
3A
4A
1A
1A
1A
IA
IA
1A
1A
1A
1A
1A
IA
1A
1A
1A
1A
1A
1A
1A
1A
UTH
CQ258247
CQ270237
CQ245277
CQ262249
€0274237
CQ248278
C0272245
C0288234
80530280
B0550240
BQ570230
6Q600230
BQ58Q280
BQ530280
CQ067503
CQ089419
CQ100490
CQ085515
CQQ67503
CQ069419
C01O0490
CQ085515
CG067503
CQ1O049O
C0085515
CQ023506
CQO38493
CQ048503
CG045035
CQ0235O6
CQ093492
C0135525
CG051308
8Q936361
CQ265302
C0135525
C0019643
CQ074788
80916850
60.916850
CQ176356
B0916850
CQ235274
C0050305
S0963362
C0273323
CCOS3492
CQ135525
'J.MCLCSSIFIin
10
�NREC= 17541
NREC= 17541
NPROV=
,NPROV =
207
207
NZREC=
NZREC=
392
392
�OATf:
670912
670912
670912
670912
670913
670913
670913
670913
6S032d
630323
680328
680328
680329
680329
630407
680407
680407
680407
630429
680429
630508
6 SO 50 3
680508
680508
680513
680518
630518
63051S
630518
680518
680518
680518
630518
680518
680518
630518
630520
630520
680520
630521
680521
630522
680522
680525
630525
680525
630525
680526
630526
630601
AGN
0
n
W
n
X
w
0
0
0
0
w
M
0
0
w
n
n
GALS
2000
0
0
0
2100
0
• 0
0
1000
0
5000
0
3000
0
5000
0
0
0
3000
0
4900
0
0
0
6000
0
0
0
1250
0
0
0
1000
0
0
0
4000
0
0
3000
0
6000
0
6000
0
0
0
3000
0
3000
TYP
C
C
D
D
n
r
D
D
r
D
D
t?
0
D
0
D
D
LEG
1A
IB
2A
26
IA
IB
2A
28
1A
18
1A
IB
1*
IB
1A
IB
1C
ID
1A
IB
1A
IB
1C
ID
iA
18
2A
26
1A
IB
1C
ID
1A
IB
1C
ID
1A
IB
2A
LA
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
UTM
BP368770
BP340820
BP470830
BF345832
PP35Q727
BP340820
BP430333
BP347830
8Q323100
SW21190
8Q323100
BQ321190
AQ922670
AQ995540
3Q302100
B0302190
BC314190
BC314100
BQ343100
BC343190
BG368190
B0373190
BQ368100
BC373100
BQ297100
B0307190
3Q297150
BQ307106
BQ318145
BQ318100
8Q315100
BC315190
BQ318145
BQ318100
B0315100
BQ315190
BQ350190
3Q318190
BQ318100
S0363100
BC363190
80380161
BG299175
B0330100
80330190
BQ335190
BQ335100
B0368100
BQ368190
8Q285100
�04TF
630601
680606
680606
680612
630612
630619
680619
68061*;
630619
680701
630701
680701
680701
680710
680710
680710
680821
680821
630830
680830
680830
680830
680924
680924
680924
680924
681011
631011
681030
681030
631030
681030
681103
631103
631122
681122
681123
681123
681205
681205
690102
690102
690102
690102
690106
690106
690106
690106
690302
690302
AGN
0
0
X
0
0
3
3
B
0
0
0
0
0
0
0
0
w
GALS
0
4000
0
3000
0
3000
0
0
0
3000
0
0
0
3000
0
0
2000
0
3000
0
0
0
2500
0
0
0
3700
0
5700
0
0
0
3000
0
2900
0
5000
0
2750
0
2000
0
0
0
3000
0
0
0
8500
0
TYP
O
D
0
0
LEG
IB
1A
IB
1A
IB
IA
IB
2A
26
1A
10
D
C
C
C
D
D
0
D
0
2A
28
1A
IB
1C
IA
IB
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
IA
IB
2A
26
1A
IB
1A
16
1A
18
D
D
D
D
IA
18
IA
16
2A
28
1A
IB
2A
2B
1A
IB
UTM
8Q285157
BQ377100
BQ377190
8Q347100
3Q347190
3Q33810O
90338190
BQ346190
BQ346100
BQ311100
80311190
BQ32619Q
8Q326100
BQ2901QO
8C29Q190
6200
0910
6P220920
BP1O0840
8Q385164
BC286176
BQ387162
8Q321169
BQ316Q45
BQ316Q45
4Q992560
AQ992400
A69;e74OO
A0925436
AQ99s85O4
AQ99354Q
A/Q99/59OO
AQ983434
YV857624
YV802474
YV7723OO
BQOOO4O3
A0983540
BQ001420
AQ982462
AC997505
AQ9-90544
BQ387167
BQ285178
BQ280170
BQ366162
YW990830
ZU090910
�I)4T£
690302
690320
690320
690320
690320
690320
690320
690320
690320
690610
690610
690610
690610
690610
690610
690610
690630
690630
690630
690630
690630
690630
690703
690703
690703
690703
690703
690704
690704
690704
690707
690707
690707
690707
690707
690708
690708
69070E
690712
690712
690712
690714
690714
690714
690714
690715
690715
690715
690715
690715
AGN
0
0
0
0
GALS
0
3000
0
0
0
3000
0
0
0
2500
0
0
0
0
0
0
2000
0
TYP
D
D
D
D
0
0
2000
0
0
3000
0
0
2700
0
3000
0
0
2300
0
3000
0
0
3000
0
0
3000
0
0
3000
0
0
0
3000
0
0
' 0
0
D
0
0
0
0
0
0
0
n
0
D
n
D
D
C
0
D
D
D
LEG
1C
1A
IB
2A
28
1A
18
2A
2B
1A
IB
1C
2A
2B
2C
20
1A
IB
1C
IA
IB
1C
IA
IB
1C
1A
IB
1A
IB
1C
1A
IB
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
2A
26
1A
IB
2A
26
3A
UTM
ZU140920
BC380157
BC289167
BQ288170
8C370160
80390169
BQ300180
80289164
BQ365155
AP994827
AP985792
4P982765
AP982765
AP981790
AP994605
AP998827
ZV206O54
ZV176150
ZV101225
ZV131058
ZV157134
ZV083213
ZV177059
ZV152134
ZV082212
AP974767
AP994830
ZV211054
ZV177149
ZV103226
BP038580
AP871605
BP3S2647
BP342682
BP370800
ZV203055
ZV174148
ZVO?8222
ZV185100
ZV17Q146
ZV097221
AP989830
AP971763
AP968769
AP986830
ZV20MOO
ZV186154
ZV206100
ZV19O150
ZV209100
�n&T^
690715
690716
690716
690716
690716
690716
69 37 16
690726
690726
690726
690726
690726
690726
690726
690726
690727
690727
690727
690813
690818
690618
690823
690823
690823
690823
690928
690928
690928
690928
690928
690928
690928
690S28
690928
69100S
691008
691008
691008
691008
691008
691008
6°1008
691015
691015
691112
691112
691112
691112
700316
700316
4GN
0
8
0
0
0
0
3
«
3
rj
GALS
T¥P
0
3000
0
0
0
0
0
0
1200
c
0 ''
0
0
0
0
0
0
2500
D
0
0
2500
0
0
0
2000
D
0
0
0
2000
C
0
0
0
0
0
0
0
0
2880
D
0
0
0
0
0
0
0
6000
D
0 '
1100
C
0
0
0
2000
C
0
LEG
38
1A
IB
2A
28
3A
38
1A
18
1C
ID
2A
28
2C
20
IA
IB
1C
1A
IB
1C
1A
IB
2A
2B
1A
IB
1C
ID
2A
2B
2C
20
2E
IA
IB
1C
ID
2A
28
2C
2D
1A
IB
1A
IB
1C
ID
1A
IB
UT«
ZV194145
BP002772
BP019830
AP998773
AP015830
AP995773
APO12830
8P390847
BP372342
BP367340
BP357836
EP4O0840
6 P 39 083 9
BP38O840
BP360832
ZV182100
ZV168143
ZV094219
BP388647
BP34O682
BP36T800
YU995203
ZU037204
ZU1Q5155
ZU157143
BP353851
3P346834
BP339832
BP3 17834
BP284843
BP266847
BP294842
BP226844
BP229886
BP390810
BP350818
BP32O820
BP295836
BP285338
BP260B45
3P210850
• 8P180877
BP022545
AP659583
BP410825
BP340817
BP235886
BP070834
BPQ7082O
BPl 10830
�UNCLASSIFIED
MISSIONS STARTING IN
0/JTH
700316
700316
700316
700331
700331
700331
700416
700416
700416
700416
700720
700720
700720
700720
700824
700824
700824
701005
70100?
701005
701005
701005
701005
701005
701005
701005
701005
701005
7 3 1005
701024
701024
701024
701024
701024
701024
701024
701024
701024
701024
701024
701024
701024
701024
701024
701024
701108
701121
701121
701121
701216
AGN
0
0
B
3
3
8
3
3
GALS
0
0
0
2500
0
0
1800
0
0
0
3000
- 0
0
0
2500
0
0
13
0
0
0
13
0
0
13
0
0
0
0
2420
0
0
0
0
0
0
0
. 0
0
0
0
DAPLAC
************
TYP
LEG
1C
ID
IE
.C
U
IB
1C
1A
D
IB
1C
10
1A
C
IB
2A
28
1A
C
IB
1C
1A
C
IB
1C
ID
1A
C
IB
1C
1A
C
IB
1C
10
C
IX
10
IE
IF
IG
IH
2A
26
2C
2D
2E
2F
0
0
0
0
w
so
p
9
1500
0
C.
3
0
1060
te
1A
IB
C
2G
2H
1A
1A
IB
1C
1A
PROV NO.
UTM
BP190900
BP200850
8P140830
8P380805
BP240867
8P040830
8P430800
BP430900
BPO60900
6P060800
BP350700
BP380800
BP220890
8P150380
BP34069O
BP3 70770
BP330820
8S131990
8S133990
8S133981
BS 130981
8 SI 20964
BS124956
8S 11 8960
65129951
BS130950
6S130947
BS128945
6S125425
3RO9O810
3RO90880
SR240910
8R330860
BP410&00
8R380770
8R370710
8Ra70670
8 R3 00670
SR330700
BR36Q790
8R3.OO810
3ft22O860
&R15.086.Q
BR150810
BRQ9Q610
9Q1 16332
3P345605
BP37Q765
8P3i2882l
8Pd98820
11
�UNCLASSIFIED
MISSIONS
D&TE
701216
STARTING
AGN
IN
GALS
0
0
OAPLtC
TYf>
.
LF:G
IB
UTM
3P144862
1C
BP253887
UNCLASSIFIED
IJK'CLASSI FI='J
PROV NO. = 1 1
�17888
17338
NPPQV=
' N JPRQV=
69
69
MZREC=
NZRPC=
183
183
UNCLASM FI ~D
�PROV NO. = 12
MISSIONS STARTING IM
PIT 5
650828
650828
650829
650829
650830
650830
660202
660202
660306
660306
660307
660307
660310
660310
660315
660315
660317
660317
660528
660528
660819
660U19
660819
660819
660822
660822
660826
660826
660826
660826
660828
660828
660903
660903
660905
660905
660905
660905
660909
660909
660909
660909
670419
670419
670419
670419
670423
670423
670424
670424
AGN
0
0
0
0
0
0
0
G
0
0
0
KHANH HOA
GALS
900
0
1000
0
650
0
3000
0
2000
0
2000
0
2000
0
1900
0
2000
0
2000
0
2000
0
TYP
D
0
D
D
0
D
0
D
C
0
0
0
0
0
0
2000
0
3000
D
D
0
0
0
0
0
2000
0
3000
P
D
0
0
4000
D
0
0
0
0
W
0
W
2000 ,'
o '"
0
0
3720
0
0
0
1860
'0
2250
0
D
D
D
0
LEG
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1ft
IB
2A
28
1A
IB
1A
IB
2A
26
IA
IB
1A
IB
1A
IB
2A
2B
1A
IB
24
26
1A
IB
2A
28
1A
IB
1A
IB
UTM
BP700900
BP750377
B0510122
60435162
BQ435162
BQ510122
C 02 7 0220
C017615Q
CC220180
C0260230
CP020910
C0225190
BP750885
5P700900
BP667925
8P636999
BQ630000
3P670925
CQ106083
C0224194
CP028270
CP000310
BP995310
C PO2-026 5
BP955360
BP950240
8P958240
8P960360
BP950360
6P963310
CP024268
BP991310
8 9 0 1
P 8 3 0
BP975260
SP953240
BP957360
BP960330
BP958275
BP940240
BP940360
CP059220
CP059211
C0178164
CC225187
C0173173
CQ21T196
CP015939
BP917932
BP74O862
BP85 7-960
�DATE
670426
670426
670505
670505
670519
670519
670519
670519
670519
670520
670520
670524
670524
670526
670526
670526
670526
670527
670527
670527
670527 •
670529
670529
670529
670529
670529
670529
670530
670530
670607
670607
670607
670607
670615
670615
670615
670618
6 706 1 8
67061S
670618
670618
67061G
670619
670619
670621
670621
670621
670621
670624
670624
AGN
W
W
w
w
a
0
0
w
0
w
0
w
w
0
w
n
w
w
0
w
w
w
GALS
2430
0
1800
0
5580
0
0
0
0
2700
0
2400
0
1860
0
2250
0
2600
0
2500
0
1560
0
930
0
700
0
2790
0
2790
0
2250
0
2790
0
0
3395
0
0
0
2600
0
1860
0
2400
0
3670
0
2790
0
T¥P
D
D
0
D
0
0
0
D
0
D
D
D
0
D
D
0
D
0
n
P
D
£
LEG
1A
18
1A
IB
IA
IB
2A
2B
2C
IA
IB
IA
ie
1A
*B
IA
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
IA
IB
1A
IB
1A
IB
1A
18
1C
IA
18
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
UTM
BQ927098
BQ841152
CQ130125
COO88092
CP000993
CPO13988
BP937958
BP938^953
8P9O9936
80892085
80837138
B 0 2 5 120
9
CQO5OO93
80918118
BQ836177
BO 880080
BP950994
B0927132
C0010O80
RQ94OUO
CQ03OOTO
30943047
CCO1O045
B0875085
BQ82013O
B0875085
B0820130
BP910935
BP353952
BQ929132
B0850128
B0870090
BP95O950
C0080150
CQ04Q120
C0 6 0 0
009
BP766911
BP784902
3P830960
BP773907
CQ01G050
CQ080100
8P87C990
BP910020
B«870030
BC820130
BG852073
BQ928006
BPb359t>5
BP910942
'
*
�i r ici>
M I S S I O N S STARTING IM
D/VTE
670624
670624
670624
670624
670624
670625
670625
670630
670630
670701
670701
670703
670703
670703
670703
670703
670703
670703
670703
670705
t>70705
670707
670707
670707
670707
670712
670712
670717
670717
670717
670717
670721
670731
670724
670724
670724
670724
670724
670724
670812
670312
670816
67U816
670826
670826
670826
670826
670827
670827
670827
AGN
0
H
W
W
W
0
0
0
0
W
0
0
,-f
KHANH HOA
GALS
3460
0
0
0
0
2790
0
2790
0
2700
0 •
470
0
0
0
930
0
0
0
2360
0
2790
0
0
0
2450
0
2000
0
300O
0
2100
0
2700
0
T¥P
p
0
0
c
0
0
e
c
c
D
0
D
C
a
0
0
0
0
1450
0
0
H
0
1000
0
3000
0
0
0
3'0
00
0
0
C
c
ri
C
PROV NO. =
LEG
1A
IB
1C
2A
28
1A
IB
1A
IB
1A
18
1A
IB
2A
26
1A
18
2A
26
1A
IB
1A
IB
2A
28
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
3A
3B
1A
IB
1A
IB
1A
IB
2A
2B
1A
IP
2A
UTM
BQ892084
BQ94Q04*
CQ007042
CPQJ.8993
BQ976009
BP99O990
BP90Q940
BQ93012O
CQ060090
8P780910
BP840960
BQ923120
8Q847172
80922115
B0842169
BQ923120
BG&47142
BQ925U5
30842169
BP770298
BP663300
BP770279
6P717261
BP751269
BP718290
8P84-0674
BP7~9Q674
BQ889082
CQQ02037
8P987997
8P399948
BQ925112
CQO5-5O33
CC125185
CQ172161
C0123184
CC15017O
CQ115177
CO145162
BP715260
BP687295
3P754290
BP669297
80873078
BQ947977
B0936956
B0912942
BP770298
6P688297
BP770262
12
�MISSIONS STARTING IN
04TF
670827
670S27
670829
670829
670829
670829
670630
670830
670830
670830
670901
670901
670904
670904
670904
670904
670906
670906
670910
67091Q
67091Q
670910
670911
670911
670914
670914
670914
670914
670920
670920
670929
670929
670929
670929
670929
670929
680402
680402
630404
680404
680426
680426
680503
680503
630511
630511
680528
680528
630607
680607
#GN
0
0
w
0
o
0
Q
0
0
0
0
8
GALS
0
0
1800
0
2370
0
1000
0
2000
0
750
0
2600
0
0
0
2600
0
2500
0
0
0
2600
0
3000
0
0
0
3000
0
1650
0
0
0
KHANH HOA
**#*********
T¥P
LEG
26
2C
1A
D
18
D
1A
18
IA
D
IB
r
1A
D
18
1A
IB
D
r>
0
-
D
c
c
0
W
0
0
0
0
3000
0
3000
0
2100
0
2700
D
P
D
D
0
0
0
n
3000
0
3000
'0
'
2000
0
1A
18
2A
26
1A
16
1A
18
2A
2B
1A
f>
C
0
r
18
1A
16
2A
2B
1A
IB
1A
IB
2A
26
3A
36
1A
18
1A
IB
1A
IB
1A
18
1A
IB
It
IB
1A
IB
PRQV NO.
UTM
BP725286
BP695278
CQH5179
C0132125
BP84Q646
BP79Q646
BP842636
BP79Q635
8P842636
BP79O635
8P84O661
8 P 790661
BP84Q669
BP790.669
8P840682
BP79O682
CQO-06Q67
CQQ3-5108
3 P 8-4088 7
BP79063T
BP84O64O
8P790640
BP840655
BP79Q655
XS 87 8 188
XS952173
XS926143
XS847J64
BP840665
BP79O665
BP70O713
BP713700
BP7OO723
BP716700
BP700726
8P74O712
C0126131
CQO83097
B<P8T*982
CQ006O34
CC110128
C00771O2
C0164181
CC205202
C0130185
CQ1 75220
C6168174
CQ217197
C0155185
CC201205
;: c r c T - PI
12
�MISSIONS STARTING IN
0*TF
630710
680710
630710
680710
680726
630726
6S0726
680726
680726
680726
680803
680803
630803
680803
680805
680305
680805
680805
630805
630805
680805
680805
680805
680805
680805
680805
680805
680805
630805
680806
680806
630806
680806
630806
680806
680812
690813
630813
630813
68a813
660814
680817
680820
630820
680820
630820
6b082l
680821
680903
680903
AGN
3
H
B
0
3
B
6
3
W
0
W
0
0
0
0
0
0
n
W
W
KHANH HOA
************
TYP
GALS
LEG
C
1A
2800
0
IB
2A
0
0
2B
IA
D
2000
0
IB
0
2A
0
2B
3A
0
3B
0
1A
3000
C
0
IB
0
2A
0
2B
P
400
1A
C
3000
1A
0
IB
0
2A
26
0
3A
0
0
36
C
1A
500
0
16
3000
1A
C
0
IB
0
1C
0
2A
0
2B
0
2C
1500
C
1A
0
18
0
1C
2A
0
0
26
0
2C
£
55
1A
3000
C
1A
0
IB
.0
2A
0
IB
IA
55
F
P
1A
25
p
50
1A
100
P
1A
P
100
1A
P
40
1A
40
P
1A
r
42
1A
192
p
1A
p
193
1A
UTM
BP610580
BP640580
BP640530
BP610530
BP829630
BP829693
8P801680
8P803630
BP826639
BP826680
BP680740
BP680600
BP730740
BP730600
CP056?98
BP691768
BP743730
8P702732
BP794742
BP692762
BP791746
BP530881
8P56Q894
BP74553Q
BP760590
BP725590
BP780550
8P716558
BP780558
8P843663
BP840635
BP813632
BP810662
BP7 74669
BP77Q684
BP906573
8P6206O8
BP690603
39620606
BP6906O6
3P906573
BP965769
BP943766
BP991B56
BP993736
BP924230
BP991856
BF930blO
C0271343
CG235273
�MISSIONS
DATE
680904
680905
680906 *
680916
63091i
630916
680916
680918
680918
680918
68Q921
680921
680922
680922
63100 1
681002
681003
681005
681006
681007
681008
631009
681009
681010
681010
681013
631013
681014
681014
681015
631015
681015
681016
631016
681017
681017
681017
681017
681022
681023
681024
681025
681027
681028
681028
6-31028
631023
681029
681 101
631102
STARTING
AGN
0
n
n
0
B
0
p
o
Q
0
n
0
0
W
0
0
0
0
Q
n
rt
H
0
W
'ft
0
fi
W
o
W
W
Q
o
W
tl
W
W
W
W
o
0
0
o
0
0
.-t
•fi
IN
************
LUG
TYP
1A
P
P
1A
1A
P
1A
C
1000
16
0
1A
c
2000
18
0
1A
R
100
1A
P
100
1A
P
50
P
1A
50
1A
P
50
1A
P
100
4?
1A
100
1A
P
35
P
1A
55
1A
P
10
1A
P
100
1A
P
100
1A
P
100
1A
P
100
1A
F
5400
18
0
1A
P
55
1A
P
55
1A
P
25
1A
P
55
1A
P
55
1A
P
50
1A
P
55
1A
P
55
P
1A
50
P
1A
55
1A
P
55
1A
P
50
1A
P
50
1A
P
55
1A
P
1 0
1
P
1A
110
1A
P
110
P
1A
110
P
1A
110
1A
P
100
1A
P
100
p
1A
100
1A
•p
100
P
1A
100
P
1A
100
IA
P
110
1A
P
1 0
1
GALS
55
55
100
PROV
KHftNH HOA
UTM
CQ167136
BP906573
BP906573
BP60090O
BP6 70830
SP68079Q
BP74O760
CP024916
BP943766
BP924809
BP993T36
8P924809
BP974916
SP934864
CP001853
BP988853
C0167136
BP993736
8P993736
BP993736
BP943766
CP140500
CP105500
BP993736
BP993736
BP9-94843
C0107077
CGI Q7 07 7
C01O7077
CQ107077
CQ107077
C0107077
BP988853
CQ107077
BP966856
BP991856
C0107077
CQ107077
C0107077
CQ107077
C0107077
C0107077
SP988853
BP968853
8P993736
BP924809
BP943766
CQ107077
CQ107077
CQ107077
NO.
12
�UNCLASSIFIED
MISSIONS STARTING IN
DATE
631102
601102
681104
631104
681104
681105
631108
681109
681112
681112
681112
681115
631116
681201
681202
631204
681205
631205
681206
681211
631211
631211
681211
681212
681214
631215
631216
631216
6531216
631217
631217
681218
681218
681218
681218
681220
681221
631223
690105
6V0105
690108
690110
690110
690110
690111
690114 .
690121
690121
690122
690123
AGN
Ml
W
Q
0
0
W
,i
T
0
o
0
0
w
0
0
Q
W
0
W
B
0
Q
0
0
0
0
0
0
n
0
0
0
p
0
0
0
0
0
Q
0
w
0
0
w
. GALS
110
110
110
50
25
110
165
105
35
50
20
20
200
110
55
55
385
55
110
2000
0
0
0
165
UO
275
165
220
440
110
165
3000
0
0
0
110
110
110
88
22
275
55
110
55
99
330
330
150
27
275
KHANH HOA
TYP
P
P
P
P
P
P
P
F
P
P
P
P
P
P
P
P
P
P
P
C
P
P
P
P
P
P
P
P
D
p
P
P
P
P
p
P
P
P
P
P
P
P
P
P
PROV NO. = 12
LEG
1A
IA
1A
1A
1A
1A
1A
IA
1A
' 1A
1A
1A
1A
1A
1A
1A
1A
1A
1A
IA
IB
2A
2B
1A
1A
1A
1A
1A
1A
1A
1A
IA
IB
2A
28
1A
1A
1A
1A
1A
1A
1A
1A
IA
1A
1A
1A
1A
1A
IA
UTM
CQ167136
CQ107077
CG107077
BP988344
BP994843
BP993936
BP934864
CP08B853
CP001853
BF984854
BP990843
CPO01851
8P994843
BP938853
BP974916
BP988853
BP861534
BP988853
BP816584
BP740610
SP6 10610
BP6 1,0740
8P74Q74Q
8P988853
BP861584
8F861584
CPO(H853
CPOOi853
BP86.1584
€ POO1 849
BP943766
BP90Q730
SP830730
3P9O0732
8P830732
BP9248O9
BP934864
BP993734
BP993736
CP056998
BP978584
8P992828
BP841935
BP9 34864
BP943766
8P978504
CP024916
CP024916
CP014240
BP974916
�UNCLftiMMCU
MISSIONS
GATE
690124
690126
690204
690206
690210
690210
690212
690214
690218
690219
690220
690220
690220
690220
690223
690305
690310
690310
690311
690316
690317
690319
690404
690404
690405
6^0405
690407
690407
690710
690712
690712
690715
690715
690716
690716
690716
6907 IK
690720
690720
690721
690721
690805
690806
690809
690812
690812
690814
690817
690320
690905
S T A R T I N G IN
4GN
W
0
W
fi
0
W
W
VJ
u
0
0
w
w
0
w
w
w
w
w
0
w
0
0
GALS
480
33
55
165
165
275
385
275
275
330
110
0
220
0
220
220
550
0
550
495
550
550
165
275
110
0
110
w -
1 10
0
0
400
220
275
400
0
400
0
550
0
495
0
495
0
220
275
110
165
0
165
220
w
0
0
n
o
0
0
n
n
0
n
n
0
W
165
0
PROV NO.
KHANH HOA
TYP
P
P
P
P
P
P
P
P
P
P
P
P
P
P
p
P
P
P
P
P
P
F
P
P
C
C
f.
P
P
P
P
P
C.
C
C
r
C
r
r
p
L~G
IA
14
IA
•IA
1A
1A
IA
1A
1A
1A
1A
2A
IA
2A
1A
1A
1A
2A
IA
1A
1A
1A
1A
1A
1A
IB
1A
1A
1A
1A
1A
1A
2A
1A
2A
1A
2A
1A
2A
1A
2A
1A
1A
1A
1A
2A
IA
1A
li
1A
UTM
CQ107077
BP934864
BP906573
BP9Q6573
BP906573
3P906573
BP861584
BP943766
BP924809
BP934864
CP056998
CP024916
CP056998
CP024916
CP001853
BP992838
CP056992
CP024916
CP024916
CP024916
BP943766
CP056992
CQ107007
CQ107007
BP974916
CP024916
CQ1 07007
CQ107007
CP024-916
CP024916
CP024916
BP974916
CP024916
BP974916
CP024916
BP974916
CP024916
BP974916
CP024916
BP974916
CP024916
BP780710
3P714896
C0107077
CQ107077
CQ167136
3P941899
BP991856
BP974916
BP941899
12
�UNCLASSIFIED
MISSIONS STARTING IN
DATE
690005
690906
690906
690907
690907
690907
690907
690907
690907
690907
690907
690907
690907
690907
69C907
690907
690907
690911
690911
690912
690913
690913
690919
690919
690919
690919
690921
690921
690930
691019
691020
691021
691021
691025
691025
691025
691025
691025
691025
691025
691025
691025
691025
691025
691222
700116
700127
700127
700203
700203
AGN
n
0
W
8
W
0
a
w
n
0
w
0
W
W
W
0
W
B
GALS
0
0
0
26CO
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
3000
0
0
0
0
0
165
275
165
330
275
2300
0
KHANH HOA
************
TYP
LSG
P
1A
P
1A
P
IA
IA
c
IB
2A
26
3A
36
4A
48
5A
5B
6A
66
P
P
P
P
P
c
P
P
P
P
P
P
P
c
0
0
0
0
0
W
0
0
0
0
0
0
0
0
55
55
55
0
1237
1155
P
P
P
P
F
7A
7B
IA
1A
1A
1A
IA
1A
16
2A
26
1A
1A
1A
1A
1A
1A
1A
IA
IB
1C
2A
28
2C
2D
3A
3B
3C
3D
1A
1A
1A
2A
1A
1A
P R O V NO. =
UTM
BP941899
BF94I899
8P941899
8P588653
8P602630
3P59&664
ftP602638
BP6tS6l3
BP632598
6P643595
SP694605
8P72Q648
BP72B672
BP695680
BP716622
BP692673
8P697610
SP861584
BP86J584
RP941899
8P861584
BP861584
6P650460
8P77OA50
BP770500
BP63O505
8P978584
8P978584
CP024916
BP9 92450
BP996856
8P996850
8P996&50
8 P6 7 024 8
BP687250
BP6^5245
3P674239
BP700237
SP706230
BP713228
BP75023O
3P770260
BP740290
BP68O296
8P992336
BPS 34864
SP715380
BP713389
BP974916
BP974916
12
�UNCLASSIFIED
MISSIONS START ING IN
P R O V NO.
KHAN'H HOA
$ * * * * *
* * * * * *
DiTF
700305
700305
700325
700325
700521
700521
700522
700522
700523
700601
700707
700722
700722
700722
700722
700722
700722
700722
700730
700730
700801
700S01
700801
700803
700803
700803
700805
700805
700805
701021
701026
701026
701026
701026
701026
701026
701026
701026
7J1026
701026
701026
701026
701030
701105
701105 .
701105
701105
701105
701105
701105 '
AGN
0
0
0
0
0
0
0
o
0
8
GALS
1850
TYP
c
0
110
0
97
98
84
60
110
165
110
p
p
p
p
p
p
p
p
c
3000
0
0
0
0
0
0
B
c
c
2600
0
3
3000
0
0
5
c
3000
0
0
8
B
6
W
B
c
3000
0
0
535
p
c
3000
0
0
0
0
0
0
0
0
0
0
0
200
p
3100
0
0
0
0
0
0
__
c
LEG
1A
16
1A
IB
1A
1A
1A
1A
1A
1A
1A
1A
ie
1C
ID
IE
IF
1G
1A
18
1A
16
1C
1A
IB
1C
1A
IB
1C
1A
1A
IB
1C
10
2A
28
2C
2D
3A
3B
3C
3D
1A
1A
18
1C
10
2A
2B
2C
UTM
BP725830
BP650550
8P268213
BP255255
BP993843
BP984953
BP993846
3P9C2854
9P938853
3P924809
BP941899
BP580660
BP620660
BP620630
BP700630
BP700500
BP580500
BP580660
BP570740
3P700650
BP670295
BP745295
BP82 024-0
BP618797
8P740721
BP800700
8P670320
8P750300
BP 82 02 50
Y062C095
BP670260
BP670320
BP74Q320
BP740260
BP74026Q
BP740340
BP80034O
BP8O0260
BP780260
3P820260
BP8202QO
SP780200
CP024914
BP570660
3P620660
BP&20600
BP5 70600
3P62062Q
BP70062Q
3P700570
12
�MISSIONS STARTING IN
DfiTF
701105
701105
701105
701105
701105
701105
701106
701107
AGN
GALS
0
0
0
0
0
0
90
150
KHANh HOA
ryp
PROV NO. = 12
LJ?G
ZD
3A
3B
3C
3D
3E
1A
1A
UTM
BP620570
BP65O69D
BP730690
BP730630
8P68O630
BP660650
CP014399
BP907563
UNCLASSIFIED
�N R E C = 17532
= 17632
MPPOV=
'!PPOV=
272
272
NZREC=
NJR5C=
236
236
�MISSIONS ST1RTING IN
DAT!!
660413
660413
660418
660413
660418
660418
660424
660424
660424
660516
660516
660516
660516
660516
660516
660526
660526
660526
660526
660605
660605
660611
66J611
660628
660628
660710
660710
660805
660805
670329
670329
670501
670506
670506
670506
670604
670604
670605
670605
670629
670629
670705
670705
670709
670709
670712
670712
670717
670717
670717
AGN
0
0
0
0
GALS
2000
0
3000
0
0
0
2000
0
0
3000
0
0
0
0
NINH THUAN
***-***#*#***
TYP
LEG
1A
0
18
0
1A
IB
D
D
0
0
0
0
n
0
0
n
0
0
0
0
0
0
0
0
0
2000
0
0
0
2000
0
3000
o
1830
0
2800
0
2000
0
1860
0
1400
1500
0
0
2200
0
2290
0
2790
0
2790
0
2300
0
1900
0
3000
0
0
D
t>
•
D
D
n
P
c
c
c
c
c
, c
c
c
c
c
1C
ID
1A
IB
1C
IA
IB
2A
28
3A
3B
14
IB
2A
28
1A
IB
14
IB
1A
18
1A
IB
1A
IB
1A
18
IA
1A
IB
1C
IA
IB
1A
IB
1A
18
1A
13
1A
IB
1A
18
1A
IB
2«
PROV NO, = 13
UTM
BN695580
BN710666
BN696579
3N711690
B!'4703670
9N692580
BM694580
BN710668
BN690584
BN700577
8N716666
SN731546
3M757553
BN734540
BN758550
BN690580
BN715680
3N74O583
BN775583
BN732526
BN735554
BN724588
8N758574
8N710645
BN700600
BNi760580
BN724580
BN760370
BN760588
BP740110
BP690060
BP370750
8P72O090
BP680060
BP700040
BP750OOO
BP790300
BN480700
BN530770
BP612380
BP645317
BP605380
BP628290
BP555395
BP605289
BP735095
BP700040
PP533408
BP600290
BP515395
�05 T?.
670717
670720
670720
670721
670721
670721
670721
670721
670721
670721
670721
670721
670721
670722
670722
670722
670722
670722
670722
670722
670722
670722
670722
670807
670807
670303
670808
670808
670808
670917
670917
670917
670917
*GN
670918
0
670918
670928
670928
670923
670928
67J929
670929
670929
670929
670929
670929
670930
670930
670930
670930
670930
0
0
0
GALS
0
2500
0
1725
0
0
0
0
0
0
0
0
0
3000
0
0
0
TYP
C
C
C
• o
0
0
0
0
0
3
P
0
2950
0
0
0
500
0
1400
0
0
0
2400
0
0
0
1000
0
2S5d
0
0
0
3000
0
0
0
0
0
1100
0
0
0
0
C
C
C
C
C
C
C
C
LEG
2B
IA
18
1A
18
2A
2B
3A
36
4A
48
5A
58
1A
IB
2A
28
3A
36
1A
IB
2A
2B
1A
18
IA
IB
2A
28
1A
IB
2A
28
1A
IB
1A
16
2A
26
1A
13
2A
2B
3A
3B
1A
IB
2A
26
3A
UTM
BP59223B
BP54Q400
BP61028Q
BP582325
BP595232
BP575305
BP585265
BP522298
BP54?276
8P6Q6288
BP626303
BP61O280
BP627298
BP61538Q
BP640317
BP625380
8P63531?
BP641345
BP647320
BP60O370
BP550250
BP660320
BP580250
BN53583O
8N520S41
3N50584Q
BN520847
BN450791
SN45,98i5
BP5/72203
BP 585 166
BP669183
BP&69153
8P742Q94
BP718Q31
BP8OOO40
BP 86 0 3
00
8 P 82 0 9 .
00
BP77010O
BP670230
BP650180
BP680230
BP650180
BP700150
aP66015Q
Bf,'492890
3N515892
BN496864
3K495883
6N49O040
�OAT?
670930
670930
670930
671002
671002
671002
671012
671012
671012
671012
671012
671012
680627
630627
683921
631006
681006
681006
6G1006
631007
681007
681007
631007
681120
631120
681120
681120
681224
681224
631224
690213
690213
690213
690325
690325
690325
690416
690416
690416
690521
6^0521
690521
690528
690528
690523
690620
6S0620
690620
690620
690620
AG.N
B
B
8
0
B
8
B
3
G* L$
0
0
0
2000
0
0
3000
0
0
0
0
0
2150
0
100
2000
0
0
0
3000
0
0
0
3000
0
0
0
3000
0
TYP
C
C
c
p
c
c
c •
c
0
W
0
0
0
0
2000
0
0
3000
0
0
3000
0
0
3000
0
0
1000
0
p
D
0
r
0
0
0
3000
0
0
0
0
D
iFG
3B
4A
4B
1A
IB
1C
If.
IB
1C
2A
28
2C
1A
IB
1A
1A
IB
2A
2B
1A
IB
2A
2B
1A
18
2A
28
1A
IB
1C
IA
IB
1C
1A
IB
1C
1A
13
1C
1A
16
1C
1A
IB
1C
1A
IB
1C
2A
28
UTM
BN504866
SN5 02820
BN510362
BP720023
BP735106
9P677097
BQ148630
BQ146600
B0220626
BQ203668
BQ233620
B0226669
BQ555380
BQ600286
BN773893
BN440780
BN440870
8N500870
BN550730
BP640174
8P610O9Q
8P706151
BP626075
8P802Q78
BP818150
BP7T0150
BP750130
BN543820
BN533752
BN592708
BN730b70
BN76591S
BN784388
BP724146
BP806156
BP889129
8P724148
BP813159
BP3V3134
eP725152
BP8131S3
BP894135
BP818179
BP831164
f(P398138
BP727173
BP765172
BP801153
8P727170
3P764170
�UNCLASSIFIED
M I S S I O N S STARTING IN
OATH
690620
690620
690620
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690621
690624
690624
690624
690624
690625
690625
690625
690625
690628
690628
69062G
69U628
690623
690628
690628
690727
6S0727
693727
690727
690727
690727
690727
690727
690806
690806
690P06
6908J6
700324
700326
700326
700330
700330
700330
700330
AC,N
0
0
0
0
0
0
C
B
GALS
0
3000
0
3000
0
0
0
3000
0
0
0
0
0
0
0
0
3000
0
0
0
3000
0
0
0
2700
0
2700
0
0
0
0
1000
TYP
C
D
D
D
D
P
c-
C
0
0
0
U
0
0
0
0
1600
0
0
0
2500
0
0
0
110
250
0
2200
0
0
0
PROV NO. = 13
N I M H THUAN
C
c
P
P
n
LFG
2C
1A
IB
1A
16
2A
28
1A
18
1C
ID
2A
28
2C
20
2£
1A
IB
2A
26
1A
IB
2A
2B
1A
IB
1A
IB
1C
2A
2B
1A
IB
1C
ID
1A
IB
1C
ID
1A
IB
1C
ID
1&.
1A
• 2A
1A
IB
2A
2D
UTM
BP795153
BN772960
BN730940
RN788961
BN713929
BN789959
8N715925
BP728168
BP760168
BP792153
BP727166
BP760166
8P788152
BP726163
BP766163
BP785152
BN800960
BN723929
BN800957
BN725928
BP738177
BP77O183
BP800160
BP88014G
BN755924
BN800944
BP740182
BP770187
BP793168
BP820167
BP900140
BP628272
BP5S4267
BP564245
BP574191
BP628272
BP594267
BP564245
BP574191
BP635265
BP581253
BP580195
3P563228
BN714896
BP906573
Bf-:0l8294
3M360845
BN490920
BN5375B16
OM5 10891
�M I S S I O N S STARTING IN
DAT if
700330
700330
700330
700330
700531
700724
700724
700724
700724
700820
700820
701103
701103
70110J
701103
701113
701113
701113
70 1 1 1 3
701113
701114
710107
710107
710107
710107
710107
710107
AGN
GALS
^ I N H THUAN
o -
TYP
0
0
0
0
B
3
S
6
W
8
200
P
2600
f
0
0
0
2000
C
0
1950
C
0
0
0
1400
C
0
0
0 ~- •-•- .
0
75
P
1900
0
0
0
0
0
e
Pf(OV
LEG
2C
20
3A
3B
1A
1A.
IB
2A
28
IA
IB
1A
IB
1C
10
1A
IB
2A
2B
2C
1A
1A
IB
1C
2A
2B
2C
UTH
BN400810
BN525720
BK43083C
BN490685
6N780910
BN366833
BN503903
BN468847
8N550740
BP837123
BP773172
BP640230
3P670220
BP640110
8P610120
3P823148
6Pa0713Q
BP779122
BP738110
BP682062
3N7T3893
BP555382
8P609290
8P66O27S
BP575246
8P569238
8P590165
I P I --U
NO.
13
�NREC= 17913
17913
NPRQV=
MPROV=
65
65
NZREC=
NZREC=
162
162
UNCttSSIFKO
UfiCLASSIFI'iD
�MISSIONS
DATE
681005
691227
691227
691227
691227
691227
691227
691227
691227
691227
691227
700112
700112
700112
700112
700112
700112
700112
7C0112
700112
700326
700326
700328
700323
700330
700330
701005
701005
701005
701005
701005
701005
STARTING
AGN
'3
8
IN
GALS
100
2000
TUYEN n'JC
TVP
P
C
0
0
0
0
0
0
0
0
0
5
2500
C
3A
38
3C
0
P
0
165
P
0
Q
110
40
0
0
0
0
0
3D
1A
2A
1A
2A
P
1A
2A
C
1A
IB
1C
0
8
1A
2C
0
0
0
0
0
IB
16
2A
28
0
110
LEG
1A
1A
2A
2B
2C
3A
38
3C
4A
48
0
0
0
PRQV NO.
10
IE
IF
UTM
BP167136
BN146810
BN160779
BN249757
BN244765
BN277799
SN234796
BN234785
BN223753
3^156753
BN100S10
BN243794
BM233798
BN2 34786
8N226794
BN148810
9N142755
BM13773
BN1 13786
BN125S16
BP263213
ftP255255
8P268213
BP255255
3P268213
BP255255
AT976100
ATS88110
AT998099
AT995O98
AT987105
AT97809S
U N C L - ' C . S I F I ;!;
14
�NREC=
NREC=
18108
18108
MPSOV=
NPFOV=
1
7
NZR£C=
N2R€C=
25
25
�MISSIONS STARTING IN
DATE
670924
670924
670924
670924
670927
670927
670927
670927
67U928
670928
670928
670928
&71002
671002
671002
671002
671003
671003
671003
671003
671003
671003
671003
671003
671003
671003
671007
671007
671007
671007
671011
671011
671011
671011
671011
671011
671031
671031
671031
671031
671104
671104
671107
671107
671111
AGN
0
0
0
3
3
0
TYP
C
C
C
C
C
C
0
0
0
0
0
0
B
3
0
W
a
Q
0
671111
671112
671112
671114
671114
GALS
2000
0
0
0
2750
0
0
0
1850
0
0
0
2000
0
0
0
1850
0
3000
0
0
0
PROV NO. = 15
QUANG DUG
*****#******
2900
C
0
0
0
2750
T
0
0
0
0
0
D
3900
0
4000
D
0
D
3000
0
P
3600
0
r
4000
0
3800
D
0
4000
C
0 "- • -• — .
LEG
1A
18
2A
26
1A
IB
2A
28
16
IB
2A
2B
1A
IB
2A
28
1A
18
1A
IB
2A
26
3A
36
4A
4B
1A
IB
ie
ID
1A
IB
2A
28
3A
3B
IA
IB
1A
IB
1A
IB
IA
18
1A
18
1A
IB
1A
IB
UTM
YU540370
YU510300
YU57038Q
YU510280
YU570370
YU475325
YU538368
YU455297
YU600350
YU520270
YU58Q320
YU540270
ZUOIQ670
ZU11560O
ZUOOOA45
ZU1Q559Q
ZU121286
ZU161312
ZU1 00590
ZU110&35
ZU100652
ZU07264O
ZUO63627
ZU072640
ZU000652
ZU100590
ZU025686
ZU042693
ZU06163X)
ZU109698
YU53O390
YU502303
YU570377
YU53529.0
YU545302
YU588350
YU801633
YU860510
ZU030869
ZU136733
ZU120153
ZU220099
YU954810
ZU072907
YU804635
YU8 84479
YU958808
ZU073903
ZU120157
YU998217
�UNCLASSIFIED
MISSIONS STARTING
DATR
671115
671115
67111S
671113
671119
671119
671122
671122
671201
671201
671207
671207
671208
671208
671217
671217
671220
671220
671220
671220
671220
671220
671220
671220
680105
680105
680122
630122
680122
630122
630122
68(3122
680126
680126
680126
680126
680129
630129
680204
630204
680204
680204
680316
680316
630319
630319
630321
680321
630324
6803Z4
AGN
0
a
n
0
0
0
n
0
0
w
0
Q
y
0
w
w
,-j
0
IN
GALS
4000
0
4000
0
2900
0
3600
0
3000
0
3000
0
2750
0
3000
0
2600
0
0
0
0
0
0
0
3000
0
3800
0
0
0
0
0
4000
0
0
0
4000
0
2000
0
1900
0
5800
0
5800
0
3850
QUANG OUC
TYP
C
0
D
D
D
D
n
n
D
D
D
P
n
n
r- '
r
e
D
0
w
3000
0
D
PROV NO. = 15
LEG
1A
IB
1A
IB
1A
UTM
ZU12Q151
YU996200
ZU240568
ZU128449
ZU228070
fi-jjte* 16 ZU133158
^*S? -i *
ZU1 50456
IB
ZU038390
1A
ZU137733
IB
ZU032876
1ft
ZU120158
16
ZU003202
YU954813
1A
ZU070910
16
1A
ZU130730
IB
ZU03O867
1A
YU710125
YU660134
19
2A
YU710127
YU6&Q13.7
28
3A
YUT10130
YO66Q140
38
2A
Y SOS 86 39
26
X 595,7689
1A
YU799632
IB
YU860500
1A
YUT10133
YU66Q142
18
YUbfeOiso
1C
10
YU710122
IE
YU710127
IF
YU44Q13.8
IA
ZU240572
ZU195548
18
1C
ZU188512
10
ZU135454
1A
ZU123159
IB
ZU22C068
1A
YU8a7636
YU879479
IB
1A
YU807636
IB
YU879479
1A
YU795630
IB
YU383467
1A
ZU132732
16
ZU043870
1A
ZU240578
IB
ZU136456
1A
ZU045393
IB
ZU100444
�D1TE
6d0324
680324
680406
680406
680408
680408
680409
680409
680411
680411
680412
680412
680414
680414
680414
630414
680416
680416
680417
680417
680419
680419
680427
680427
630501
680501
680520
680520
680716
680716
630717
630717
680717
680808
680808
680823
680823
680831
680922
630<?22
680922
630922
680928
680928
680929
680929
680929
681009
681009
681009
AGN
0
ri
0
W
0
0
W
0
0
0
Q
0
w
0
w
0
w
w
w
0
w
0 .
w
GALS
1875
0
2800
0
2950
0
2700
0
5100
0
2500
0
800
0
2000
0
600J
0
2650
0
2000
0
5500
0
3000
0
3000
0
6000
0
2000
0
0
2000
0
2900
0
500
6000
0
0
0
3000
0
3000
0
0
2650
0
0
TYP
D
0
0
0 .
D
D
D
0
0
D
0
D
G
D
D
0
D
D
P
n
D
p
c
LFG
1A
18
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
^.B
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
1A
IB
2A
2B
1A
IB
1A
18
1C
1A
IB
1C
UTH
ZU045393
ZU10Q444
YU825612
YU881460
ZU127728
ZU041867
ZU120150
YU989220
ZU039395
ZU140440
ZU140156
ZU231070
ZU240575
ZU142448
ZU240575
ZU142448
YU809638
YU877484
ZU120152
ZU2 18070
ZU044337
ZU150449
ZU040406
ZU150458
ZU049387
ZU150452
ZU120155
ZU225060
YU960815
ZU088905
YU642437
YU581453
YU503532
YU871874
YV849050
YU953820
ZU071913
YU855770
ZU1 10460
ZU084450
ZU048420
ZU008340
YV872002
YU890852
YU620445
YIJ5b3454
YU509528
ZU130930
ZU070920
YU990850
,
.
'
�UNCLASSIFIED
MISSIONS
Q1TE
6S1011
681011
681011
681024
631024
681024
681024
681024
681025
681025
681025
681025
681026
681026
681030
681030
681030
631103
631103
631103
681109
681109
631109
681109
681109
681112
681112
681112
691116
681113
681118
631121
681121
681121
631121
631121
681121
631121
631123
681123
681123
631123
681123
681130
631130
681201
681201
681201
681202
681202
S T A R T I N G IN
AGN
0
W
W
W
0
W
W
0
0
W
0
0
V,
0
0
o
W
GALS
3000
0
0
600
0
5800
0
0
900
0
2800
.0
600
0
6000
0
0
3000
0
0
2000
0
0
0
0
3000
0
0
3000
0
0
3000
0
0
3000
0
0
0
5300
0
0
0
0
3000
0
6000
. 0
0
6000
0
QOANG TUC
TYP
PROV NO.
F
D
F
C>
F
D
0
0
C
D
D
C
r>
U
LEG
1A
IB
1C
1A
18
1A
16
1C
1A
16
1A
IB
1A
IB
1A
IB
UTH
ZU140927
ZU068914
¥0996837
ZU178995
ZU147S27
ZU08991Q
ZUO10862
YU97O814
YU9O6739
YU960817
ZU002331
ZU128443
YU9Q6989
YU960817
ZU14Q9.23
1C
C;
YU990839
YU99786Q
1A
18
1C
14
18
1C
2A
2B
1A
IS
1C
1A
IB
1C
1A
18
1C
1A
ID
2A
2B
1A
IB
1C
2A
28
1A
IB
D
ia
p.
13
1C
1*
IB
ZUQ78907
ZU140934
ZU1J3140
ZU16614Q
ZU204124
ZU210080
ZU228Q43
VA8Q5238
YA765217
YA742226
YU652440
YU585458
YU505539
YU680451
YU590476
YU530538
ZU112670
ZU048638
ZU105695
ZU112145
ZU165145
ZU231045
ZUa06128
ZU213082
YU534504
YU696413
YU698217
YU6Q3176
YU550174
YU692240
YU5B0190
15
�OATt
6812J2
681202
6G1202
681202
681202
681202
631202
631204
681204
631205
681205
681205
631213
681213
681213
631230
681230
631230
681230
690106
690106
690106
690106
690106
690111
690111
690111
690119
690119
69011?
690122
690122
690122
690123 .
690123
690123
690129
690129
690129
690201
690201 •
690201
690202
690202
690203
690203
&90206
690206
690206
690206
AGN
W
W
W
D
W
W
W
0
0
0
GALS
0
6000
0
0
0
2000
0
6000
0
3000
0
0
3000
0
0
3000
0
0
0
5000
0
6000
0
0
8000
0
0
4000
0
TYP
9000
0
0
2000
0
0
6000
0
0
5000
0
0
4000
0
5000
0
3000
0
D
D
2A
C
0
D
D
D
D
D
D
0
o —-
W
: 0
W
0
0
0
0
0
0
LEG
1C
1A
18
P
n
c
0
D
r
2B
1A
IB
IA
IB
1A
IB
1C
1A
IB
1C
1A
IB
2A
28
1A
IB
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1A
16
1A
IB
2t
28
UTM
YU556130
ZU016321
ZU037333
ZU073405
ZU145448
YU718116
YU552182
YU720108
YU550130
YU690215
YU605175
YU550173
YU721101
YU601142
YU567165
ZU109457
ZUOS8447
ZU055421
ZUQ10340
YU8 14611
YU870459
YU679447
YU580468
YU510530
YU657443
YU586464
YU520530
YU963804
ZUQ899O2
ZU1 10907
YU674447
YU593470
YU520540
YU885699
YU852601
YU789554
YU873696
YU84361O
YU775555
YU694237
YU580183
YU545178
YU692209
YU608170
ZU14017Q
ZU170170
YU982225
ZU996178
ZU026182
ZU066157
'
�UNCLASSIFIED
.MISSIONS STARTING IN
OATE
690206
690206
690210
690210
690210
690210
690210
690210
690211
690211
690213
690213
690214
690214
690218
690218
690219
690219
693220
690220
690220
690220
690305
690305
690305
690305
690305
690311
690311
690313
690313
690313
690313
690313
690313
690315
690315
690316
690316
690316
690316
690316
690316
690316
690321
690321
690325
690325
690325
690325
4GN
W
W
0
0
0
H
0
W
0
0
0
0
0
0
0
0
n
0
0
..
GALS
0
0
5000
0
3000
0
0
0
7000
0
6000
0
4000
0
6000
0
3000
0
5000
0
0
0
3000
0
0
3000
0
3000
0
3000
0
0
0
3000
0
9000
0
8000
0
2000
0
0
0
0
8000
0
4003
0
0
3000
PROV NO.
QUANG DUG
TYP
0
D
D
D
0
D
D
0
D
D
D
D
P
D
D
D
D
D
D
L£G
3A
3B
1A
10
1A
19
2A
28
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
ID
1A
IB
1C
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
IA
IB
1A
IB
1C
2A
26
1A
18
1A
IB
1C
It
UTM
ZUU1142
ZU130141
ZU1 07445
ZU217577
ZU11014B
ZU167148
ZU214130
ZU235045
YU730568
YU598472
ZU144448
ZU207569
YU607470
YU460557
YU825617
YU882458
ZU142453
ZU201565
YU960830
ZU01O870
YU070920
ZU140930
YU777562
YU720468
YU678450
YU886458
YU827617
YU875459
YU812637
ZU140158
ZU174158
ZU219136
ZU243052
ZU002232
ZUL40160
ZU1 10443
ZU220573
YU895856
YU880994
YU987227
YU998183
ZU020185
ZU070157
ZU110145
YU891455
YU331620
YU886434
YU875536
YU8 17647
YU83357J
15
�UNCLASSIFIED
S1PMS STARTING IN
OiTE
690325
650327
690327
690327
690327
690803
690808
690808
690308
691004
691004
691004
691004
691004
691010
691010
691010
691010
691010
691010
691012
691012
691012
691012
691012
6S1012
691012
691012
691013
691013
691013
691013
691013
591013
691013
691013
691013
691013
691013
691013
691014
691014
691014
691014
691014
691014
691014
691014
691014
691014
f. GN
n
0
0
W
W
w
w
GALS
0
TYP
3000
0
0
0
3000
0
0
0
5000
0
0
0
0
220
0
0
0
0
0
330
0
0
0
0
0
0
0
110
0
0
0
110
0
0
p
w
tt
ft
0
110
0
0
0
55
0
0
0
0
0
. 0
55
0
0
PROV NO. = 15
QUANG, DUC
LEG
16
1A
IB
2A
28
IA
IB
1C
ID
1A
16
1C
ID
IE.
1A
2A
3A
4A
5A
6A
1A
2A
3A
4A
5A
6A
7A
8A
1A
2A
3A
4A
1A
2A
3A
4A
1A
2A
3A
4A
1A
2A
3ft
4A
5A
6A
7A
1A
2A
3A
UTK
YU866460
ZU14Q162
ZU175153
ZU220137
ZU247048
ZV040406
ZV083443
ZV142462
ZV157502
ZU047405
ZU087438
ZU145457
ZU161481
ZU161507
ZUl 10265
ZU135265
ZU17O320
ZU165325
ZUl 3 3290
ZU115285
YU573359
YU544365
YU555340
YU558333
YU55O37O
YU580370
YU580340
YU55O35Q
YU49G3.2O
YU54032O
YO49O29O
YU54 029.0
YU54034O
YU56034O
YU5&Q320
YU54O32O
YU9915O3
ZUQ2.05QO
ZU020485
YU991485
YU940560
YU8T056O
YU9O0610
YU94O60.0
ZUOO.O630
YU940650
ZUJi00660
ZU000670
ZU07Q693
Z 0000630
�UNCLASSIFIED
MISSIONS
OiTE
691014
691015
691015
691015
691015
691015
691015
691015
691015
700228
700228
700228
700228
700326
700326
700326
S T A R T If4G
AGNl
W
W
IN
GALS
0
55
0
0
0
55
0
0
0
0
3000
0
0
0
0
2800
0
0
PRQV
QUANG DUC
TYP
C.
LEG
4A
IA
2A
3A
4A
1A
2A
3A
4A
1A
18
2A
23
1A
IB
1C
UTM
ZU070630
ZU03Q540
ZU040540
ZUO<t0530
ZUQ50530
ZU05O550
ZU070550
ZU050520
ZU070520
ZU09O614
ZU055638
YU994654
YU98O600
ZUIQO258
ZU126288
ZU154310
HI)
NO.
15
�NREC= 17774
NR6C= 17774
NPPOV=
NPROV=
124
124
NZREC=
NZREC=
242
242
UNCLASSiriEP
�MISSIONS S T A R T I N G IN
DMF
670518
670518
671006
671006
671006
671008
671008
671008
671008
671028
671023
671028
671030
671030
671119
671119
671119
671119
671124
671124
671124
671124
671230
671230
671231
671231
630112
680112
680115
680115
680128
680128
680321
680321
630321
680321
680410
680410
680418
680418
6805QS
680508
681004
681004
681004
681006
681006
681007
681007
631007
AGN
W
B
B
3
3
0
M
0
0
0
0
0
0
0
0
0
0
B
B
r>
GALS
1210
0
3000
0
0
1835
0
0
0
4000
0
0
3500
0
3000
0
1000
0
3900
0
0
0
2550
0
2000
0
26GO
0
2625
0
3900
0
2900
0
0
0
2825
0
2700
0
3000
0
3000
0
0
3000
0
3000
0
0
LAM DONG
TYP
n
c
c
c
c
D
D
C
0
D
0
D
D
0
C-
P
P
C
c
c
PRQV NO. = 16
L5G
1A
IB
1A
IB
1C
1A
IB
2A
2B
IA
18
1C
1A
IB
1A
IB
1*
IB
1A
18
2A
28
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
28
1A
IB
1A
IB
1A
IB
1A
IB
1C
IA
16
1A
16
2A
UTM
YT810620
YT790600
YT745845
YT730730
YT834816
YT820890
YT745938
YT84O020
YT870930
ZT17065Q
ZT190605
AN780720
YT765850
YT717720
ZU247023
AM740890
ZU247028
AN74C890
YT785840
YT732740
YT832735
YT699700
AN840575
AN810617
AN743890
ZU243033
4N825633
AN850*85
AN7t8683
A N6 3 0540
AN800645
AN'803721
A K8 2 3 54 4
4N848472
ANS22533
AN842485
AN'833615
AN842470
AN835610
AN303720
AN744890
ZU245040
YT855863
YT3O5305
YT745755
YU87 7123
YT928990
YU600002
YT500990
YT52O950
�04TP
681007
631102
681102
681102
681102
631102
681102
681121
681121
681121
631223
681223
681224
631224
681224
681224
6S1224
681224
681224
690726
690726
690726
690726
690829
690829
690829
690829
691028
691023
691028
691028
691031
691031
691031
691031
691031
691031
691031
691031
691031
691103
691103
691103
691103
691103
691103
691103
691103
691103
691103
4GN
B
3
(5
3
B
B
0
n
B
8
B
B
GALS
0
3000
0
2950
0
0
0
4000
0
0
2500
0
2000
0
0
0
0
3000
0
3000
0
0
0
3500
0
0
0
3000
0
0
0
2400
0
0
0
Q
0
0
0
0
TYP
1600
0
0
c
0
0
2900
0
0
0
0
LEG
28
c
c
1A
'
c
c
c
c
p
0
c
c
c
16
1A
IB
2A
28
1A
18
1C
1A
IB
1A
ie
1C
2A
2B
1A
IB
1A
IB
1C
10
1A
IB
2A
2B
1A
IB
1C
10
1A
18
1C
10
IE
2A
28
2C
20
1A
18
1C
10
IE
1A
IB
1C
2A
2B
UTM
YT64097i)
AP730015
AN819992
AN897566
AN94&58?
AN992573
8NQ 3,2525
YT791897
YT74QS30
YT740760
YT840790
YT750730
YT86Q860
YT82O81Q
YT78O794
YT760793
YT740765
AN84764Q
AN885500
AN 82 3 3 4
*
4N843605
AN8405?2
AN821540
AN841547
AN321543
ANSI 853 5
AN837474
YT910945
YT839830
YT 8O2 7 8
9
YT725768
YT5Q6959
YT5S2981
YT634964
YT676992
YT73*?998
YU7400O2
YT 743 97 6
YT813956
YT819982
YT693915
YT709878
YT698380
YT699791
YT717768
YU945083
YU905050
YU852U53
YU900135
YU941126
�UNCLASSIFIED
MISSIONS STARTING IN
DATE
691103
601115
691115
691115
700110
700110
700110
700110
700523
700523
700523
700523
700725
700725
700725
700725
700725
700725
700725
700725
700728
700728
700728
AGN
B
GALS
0
2500
0
0
1900
0
0
0
400
0
0
0
150
0
0
0
130
0
0
0
2100
0
0
DUNG
TYP
f
PROV NO. = 16
LEG
2C
14
18
1C
1A
IB
1C
10
14
IB
1C
10
1A
IB
1C
10
14
IB
1C
10
l/s
IB
1C
UTM
YU968U3
YT743903
YT804920
YT71873Q
YU960100
YU905075
YU91003Q
YU890055
YT81363Q
YT808630
YT793&07
YT79&6Q3
YT945640
YT925622
YT945633
YT935620
YT810632
YT797607
YT815630
YTSOO602
YT921S68
YT80Q79O
YT728T92
�NR6C= 18017
NREC= 18017
NPPOV=
NPROV=
33
38
NZREC=
NZREC=
85
'85
imCLASSIFItD
�D4T?
660614
660614
660614
660614
660615
660615
660615
660615
660615
660615
660615
660615
660618
660618
660618
660613
660620
66C620
660624
660624
660722
6S0722
660722
660722
660722
660722
660727
660727
660727
660727
660731
660731
660731
660816
660S16
660816
660816
660816
660816
660816
660816
660816
660816
660816
660816
66081)3
660S18
65081R
660818
660830
AGN
n
0
n
0
0
Q
0
0
0
0
n
GALS
2000
0
2000
0
2900
0
0
0
2000
0
0
0
1550
0
0
0
3000
0
3000
0
2000
0
0
0
0
0
1600
0
0
0
2050
0
0
2000
0
T¥P
D
C
p
D
16
0
C
D
C
C
C
C
6
0
0
2000
0
C
0
0
0
0
0
3000
C
0
ri
0
0
3000
2A
2P
IA
IB
2 A.
26
1A
18
IA
16
1A
IB
2 A.
2B
34
38
1A
18
2A
26
1A
IB
1C
1A
18
2f
2P
1A
lb
1C
0
n
LEG
IA
16
1A
18
1A
16
2A
28
IA
C
ID
2A
2B
2C
20
1A
IB
2A
2B
1A
UTM
ZT25010O
ZT I 4 0 5
0 8
ZT250LOO
ZT 140035
BN56053Q
6N5O0470
aN45O45O
BN 3 0 3 5
9 4
AN950310
AN89Q2&P
AN84O227
AN750160
6N12O418
BN09J042Q
8NO4Q395
AM97S317
AN84O225
AK75O16Q
ZT28CH3Q
ZT12OQ8O
(1,20
^309
BN11G225
8N11O225
8N060225
BNQ3O20O
AN99jO210
Z5 6 9 0
2 0 0
ZS21O980
AN73O040
AN78O010
ZT21O220
ZT270180
ZT210200
BM120270
BN160240
BN150220
BN060250
ZS240930
AM750930
AM74O895
ZS250900
ZS260980
4N730050
AN780015
AK78C976
ZT205140
ZT270180
ZT24Q210
ZT255180
ZS235930
�MISSIONS START ING IN
8INH THUAN
* ! * * * * *
* } • * * * *
DATF
6*0830
660830
660830
660830
660830
660830
660830
660830
660906
660906
660^06
660906
670206
670206
670604
670604
670604
670604
670604
670604
670605
670605
670605
670605
670611
670611
670613
670613
670613
670615
670615
670616
670616
670620
670620
67U621
670621
670621
670623
670623
670626
670626
670627
670627
670627
670627
670629
670629
670701
670701
AGN
G'LS
0
0
0
0
TYP
/ o
0
0
0
n
n
W
0
0
0
n
0
0
O
0
0
0
2000
0
0
0
2300
0
2790
0
0
0
0
0
1240
0
0
0
3720
0
1000
0
0
5460
0
2790
0
5400
0
2790
0
0
6510
0
2790
0
1860
0
W
0
0
f
n
c
c
D
f
n
L'
P
r
D
D
f?
5580
0
4500
r
5480
0
P
'o
D
LEG
IB
2A
2 P.
2C
3A
38
4A
4B
1A
IB
2A
26
1A
18
1A
IB
2A
28
3A
36
1A
IB
2A
2B
1A
IB
1A
IB
1C
1A
IB
1A
IB
U
IB
1A
IB
1C
1A
IB
1£
18
1A
IB
1A
IB
1A
IB
14
IB
UTM
ZT000230
ZS260950
AK740930
AM760970
ZT205220
ZT230160
ZT230230
ZT250170
BN1 10180
AN950210
AC4960240
BN150260
ZS241899
AM743899
ZS270920
AM750920
AM735920
ZS270950
AH765990
AM753945
ZT230235
ZT240160
ZT230240
ZT250167
BN180290
8N000290
BN440700
8N450540
BN4 00590
ON178273
8N015273
BM63261
BNOO3261
BN180277
BMOG3277
BN020204
AN950215
8N985288
BN17Q255
BWG0255
BN180262
BN015262
BN166265
8NQ10265
BN180240
BN010240
BN180260
6^000230
BN'l 60248
BN993243
�UNCLASSIFIED
M I S S I O N S S T A R T I N G IN'
PAT?
670701
AGN
W
670701
670702
670702
670704
670704
670706
670706
670716
670716
670718
670718
670725
670725
670727
670727
670727
670727
670731
670731
670731
670731
670731
670731
670731
670731
670731
670731
670810
670810
670811
670811
670812
670812
670812
670812
670824
670824
670902
670902
670902
670902
670909
670909
670917
670917
670917
670917
670919
670919
W
0
GALS
930
0
2790
0
4650
0
TYP
r»
r
D
D
n
0
4650
0
0
3000
0
2900
D
0
2850
D
0
•D
3000
0
0
0
2650
C
0
0
0
0
0
0
0
0
0
1850
D
0
60
00
D
0
2875
r
0 v - -. -D
1400
n
W
W
0
0
W
0
W
W
W
•li
0
o
fj
6
3000
0
2900
0
3000
0
2450
0
1500
0
. 0
0
2000
0
PROV NO.
B I N H THUAN
D
0
D
r
r
c
LEG
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
2A
26
1A
IB
2A
2B
3A
38
4A
4B
5A
5B
1A
IB
1A
IB
1A
IB
1A
IB
la
IB
1A
13
1A
IB
1A
IS
1A
IB
2A
2B
1A
IB
UTM
BN18024a
8N993248
BN180290
BNOl 0 9
20
8N181242
BN008247
BNIS0234
8H01O234
BN166216
AN985214
BN18O283
BN304283
Bm 75268
BNO13268
BN187253
BN174258
BN138258
BN005258
AM72<>926
ZS250950
ZS238957
ZS220968
ZS213990
ZT25O015
ZS268957
ZS273978
AK748957
AM727910
BN166218
BN985216
8N 180229
8NOO6229
BN 18 0220
BN060220
BN180220
BN060220
BN167212
AN950208
BN180225
BN007225
BN165212
8N010208
8N180223
BN005223
BN440700
3N445550
BN400590
8N445550
ZT226235
ZT251159
IT
�CATF
670919
670924
670924
670924
670924
670924
670924
670926
670926
670926
670926
671107
671107
680619
630619
680619
680619
680620
680620
630627
680627
680627
680627
680628
680628
680628
6S0623
680628
680629
680629
680629
680629
680629
680711
630711
630711
630711
680719
680719
680719
630719
680803
660803
680803
630803
630825
680S25
630923
680923
680923
AGN
n
n
W
yj
W
S
B
B
w
0
T
n
B
GALS
0
2000
0
0
0
0
0
1200
0
0
0
3000
0
3000
0
0
0
2800
0
2850
0
0
0
3000
0
0
0
0
2000
0
0
0
0
3000
0
0
0
3000
0
0
0
20 OJ
0
0
0
3000
. 0
1400
0
0
TYP
C
C
0
0
n
c
c
c
0
f:
D
D
C
LEG
1C
1A
IB
2A
28
3A.
36
1A
18
2A
28
1A
IB
1A
IB
1C
10
1A
IB
1A
IB
2A
28
1A
18
1C
ID
IE
IA.
18
1C
10
IE
1A
IB
2A
28
1A
IB
2A
2B
1A
IB
2A
2B
1A
16
1A
IB
2A
UTH
ZT230220
ZS216992
ZS242975
ZS272953
AM94892Q
ZS260924
AM748920
ZT226238
ZT22O163
ZT23O240
ZT24818O
BN170222
AN98S227
8^140082
8N23J6097
BN228100
6N660535
BN61O524
ZS212990
ZS273991
AN733921
ZS264920
AM745947
2S218992
ZS264977
ZS27Q918
AM745924
ZS22099G
AM74O90P
AM720900
ZS210990
ZT232098
ZTl-4,2075
ZT23.0399
ZT140085
ZT229102
ZT231094
ZT140080
ZT14Q077
ZT230097
ZT147092
ZT229104
9N&6O543
BN610530
ZT270273
ZT233257
ZT20720B
�UNCLASSIFIED
M I S S I O N S STARTING IN
!G IN
B I N t l THUAN
PP.CV NO. = 17
•fc
OiTE
630923
680925
680925
681101
681101
681101
631101
681119
681119
681119
681120
681120
681120
681120
681120
681120
631223
681223
681223
700323
7C0323
700705
70J705
700725
700725
700725
700725
700725
700725
700725
700725
700805
700SO5
700805
700805
'700827
700828
AGN
B
n
M
M
GALS
0
220
0
2700
0
0
0
3000
0
0
2250
0
0
0
0
0
2400
0
0
500
0
550
0
550
0
0
0
0
0
0
0
550
0
0
0
1 10
110
TYF
P
LEG
28
1A
16
C
C
C
C
P
s
s
s
1A
IB
2A
26
1A
16
1C
1A
IB
1C
10
2A
26
1A
16
1C
1A
2A
1A
IB
IA
IB
2A
2B
3A
38
4A
4B
1A
18
2A
P
P
26
1A
1A
UTM
ZT260147
AN300055
AN812072
AK722913
AH743020
AM770000
ZS950260
ZT219253
ZT193183
ZT249132
ZS2C0970
ZS213993
ZT230030
ZT260050
ZT250057
ZS200970
ZT265295
ZT220230
ZT263160
BN018294
BN096229
ZT220310
ZT270310
ZS251902
ZS263902
AM720920
ZS265910
ZS268918
AH742921
AM720942
ZT220310
ZT270310
ZT270260
ZT220260
AN80C070
4N890070
�NREC= 17903
NPEC= 17903
NPROV=
NPPQV=
73
73
NZREC=
UNCLASSIFIED
UN'CLSSS I p l -0
�M I S S I O N S ST4RT ING IN
£AT6
68O804
680804
630812
680820
680820
680820
680820
660823
6308'24
630327
680906
631115
681202
6S1202
681203
681204
690123
690124
690408
690626 .
&9'J627
690701
690703
690724
690922
690922
691018
691018
691101
700529
700529
700530
AGM
0
0
0
0
w
0
0
n
0
a
0
o
0
o
w
w
0
w
cats
30
30
50
50
55
300
30
40O
50
10
20
30
55
495
605
330
165
165
0
220
385
220
0
0
385
440
165
0
0
o
o
0
w
n
0
w
n
0
n
385
165
165
220
0
220
PROV NO. = 93
C A M RANH
************
TVP
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
P
C
P
P
P
P
P
P
P'
P
LEG
1A
1A
1A
1A
UTM
CP024230
CPSJ23224
1A
1A
1A
IA
1A
1A
IA
1A
1A
IA
1A
1A
1A
1A
IA
1A
1A
f f}l\^ <&.?? ft
\*K \Jff±-T;k £,£. O
ia
1A
1A
IA
1A
1A
IA
1A
1A
2A
1A
c cat 02.94
CPai8294
CPCH82<*4
CP023224
CPQt24328
CPXMJ0334
CPO.24228
CPj»,2*22&
CjPOv24228
CPO36334
Cf>OUJ2«94
CPP23228
CPQ19LQ8
CPU! 82-94
CPCH8294
CP024228
CPQ/16294
CP018294
CP036344
CP03&3L44
8^985187
CiP024228
CPQ24228
COO 3,4367
C 0034 36 7
CP018294
CP023224
CP046334
CF018294
UNCLASSIFIED
�NREC= 1310P
NREC= 18108
MPF,OV=
NPROV=
31
31
NZREC=
NZREC=
1
1
UWCjLASSIFlSO
�MISSIONS
DATE
STARTING
AGN
IN
OftLAT
************
GALS
TVP
LcG
PROV NO. =
UTM
UNCLASSIFIED
UNCLASSIFIED
�NREC= 181*0
NREC= 18140
NPROV=
NPROV=
0
0
NZREC=
NZREC=
0
0
�BINH TUY
************
TYP
GALS
LEG
r
300
'0
14
0
13
D
1A
3850
0
IB
1A
5000
c
0
IB
3000
D
1A
0
18
4000
C
1A
0
18
4000
D
1A
0
IB
p
3000
1A
0
IB
3000
0
1A
0
IB
2000
r
1A
0
IB
c
2000
1A
0
IB
2750
V
1A
0
IB
2000
D
1A
0
IB
2000
D
1A
0
IB
3000
D
1A
0
IB
0
2A
0
28
n
2000
1A
0
IB
D
2000
1A
0
18
0
2A
0
2B
2000
D
1A
0
18
0
2A
0
2B
n
2000
U
0
IB
0
2A
0
28
2000
D
1A
0
IB
2000
C
1A
0
IB
n
2000
1A
0
IB
MISSIONS STARTING IN
0.5 TE
660518
660518
660521
660521
S60523
660523
660603
660603
660604
660604
660607
660607
660612
660612
660612
660612
660613
660613
660617
660617
660618
6606'18
660622
660622
660625
660625
660627
660627
660627
660627
660703
660703
660705
660705
660705
660705
660715
660715
660715
660715
660718
660716
660718
660718
660721
660721
660728
660728
660805
660805
AGN
0
0
D
0
n
0
n
n
0
0
0
0
0
0
n
0
0
n
0
n
o
UTK
YT94705E
YT998031
YT850150
YT973031
YT85U51
YT974027
YT850150
YT970040
YT940O90
YT980040
ZT030O30
ZT140090
ZT140080
ZTO20O30
YT99G085
YT960100
YT980070
YT970110
YT95009G
YT9B0070
ZT140080
ZT080032
YT970040
YT850155
ZT150075
ZT080040
YT995030
YT960020
YT940O50
YT820140
YT970025
YT810140
ZT100060
ZT010020
YT985075
YTS60100
YT9O5067
YTS68147
YT960060
YT945085
YT92008Q
YT8<=0120
YT86015Q
YT74014Q
ZT140092
ZT030036
YT903100
YT660108
YT970040
YT670110
�MISSIONS
OftTE
660812
660812
661121
661121
661121
661121
661126
661126
661201
661201
661201
661201
670114
670114
670114
670115
670115
670115
670115
670121
670121
670121
670125
670125
670127
670127
670129
670129
670201
670201
670203
670203
670204
670204
670204
670204
670205
670205
670205
670205
670206
670206
670206
670206
670206
670306
670206
670206
670207
670207
STARTING
6GN
0
0
0
0
0
0
IN
cats
2000
0
3600
0
0
0
3600
0
3600
0
0
0
2250
0
0
1800
0
0
0
0
0
0
0
0
0
0
9
0
1800
0
0
2700
0
2700
0
2700
0
2700
0
1800
0
2700
0
2700
0
2700
0
0
1800
0
1350
n
1700
0
1800
0
0
0
0
0
0
0
2700
0
8INH TOY
* * * * * * ******
TYP
LEG
P
14
L8
1A
C
IB
2A
26
IA
e
16
1A
c
16
2A
26
1A
0
IB
1C
iA
D
16
2A
26
D
1A
18
1C
1A
P
16
0
1A
IB
P
1A
16
P
1A
18
1A
P
IB
P
IA
IB
D
1A
IB
0
1A
18
P
1A
IB
0
1A
IB
0
1A
IB
f
1A
IB
2A
28
c
1A
IB
OTM
ZTi4ooao
VT82O145
YT-9J90350
YT91042O
YT8i6044O
YT850410
¥T9#5356
¥TS 1 3430
ZTCMJ03OP
ZT1SO3OO
ZT000120
ZT'U>O12O
V$7«9*22
¥$«e7W>6
¥S»33752
ZS23 70j& 8
ZS272853
ZS2»6>9>75
ZS,2A88j66
vsaatoToo
YS8ZQ73Q
YS923758
¥575*9323
¥S^35792
ZS235972
ZS243850
VS9O3764
YS77S805
ZS220980
ZS220860
ZS224968
ZS233876
VT912250
VT899322
YS773895
¥5918763
ZS2O3974
ZS205962
V563280Q
YS8 10800
YS632C4Q
VS810838
VS304873
YS620695
YT5QC490
YT856438
YT904489
YT863434
YT926240
YT9Q2323
�MISSIONS START ING IN
oars
670207
670207
670207
670207
670212
670212
670212
670212
670212
670212
670212
670213
670213
670213
670213
670214
670214
670215
670215
670215
670215
670215
670215
670216
670216
670219
670219
67021?
670219
670220
670220
670221
670221
670301
670301
670302
670302
670302
670302
670302
670303
670303
670305
670305
670306
670306
670308
670308
670308
670308
AGN
n
0
0
0
0
0
0
0
0
0
Q
O
0
0
0
n
0
0
3
B
n
BINH TUY
*:*********#*
TYP
GALS
LEG
2400
D
1A
0
16
0
2A
0
2B
0
27CO
1A
0
IB
2700
D
1A
0
IB
2700
P
1A
0
18
0
1C
1A
2700
0
0
IB
D
2500
1A
0
IB
2550
D
1A
0
IB
2400
C
1A
0
IB
0
2A
0
2B
2700
1A
C
0
IB
2000
0
1A
0
IB
2700
D
1A
0
IB
0
2A
0
2B
2700
C
1A
0
18
D
2700
1A
0
IB
2700
0
1A
0
IB
p
1600
1A
0
IB
0
1C
3600
0
1A
0
IB
4500
0
1A
0
IB
5400
P
1A
0
IB
1A
500
e
0
IE
2700
0
1A
0
18
1800
0
1A
0
IB
UTM
YS790930
YS780930
YS790880
YS780880
YT980230
YT963280
YS620812
YS820312
YS615890
YS780890
YS816855
YS 765883
YS774924
YS 86684 7
YS827832
ZS23197Q
ZS236867
ZS242870
ZS240915
ZS253870
ZS252900
YT890470
YT984326
YS92O758
YS 765636
YT 9 4230
6
YT963277
YT898321
VT91524Q
XT984321
XT884459
YS7<»Q860
YS880760
YS788835
YS828693
YS810I29
YS896765
V S3 1090 6
YS80086Q
YS83370Q
YS615870
YS8C0370
YS7**5855
YS620855
ZTIQ030Q
ZTIQ0120
YS820810
YS630blO
¥S820iHO
VS63031O
�MISSIO NS START ING IN
OATF
670309
670309
670309
670309
67!>309
670309
670309
670309
670309
670309
670312
670312
670316
670316
670317
670317
670410
670410
670410
670427
670427
670502
670502
670515
670515
670520
670520
670530
670520
670520
670520
670613
670613
670616
670616
670616
670616
670616
670616
67061R
670618
670630
670630
670702
670702
670705
670705
670708
670708
670709
AGM
0
B
0
B
S
B
0
w
w
w
w
0
0
0
0
0
0
n
n
G
GALS
2700
0
0
2700
0
0
2700
0
2700
0
1300
0
1800
0
0
0
2790
0
0
1860
0
1860
0
1860
0
2790
0
0
2790
0
0
4650
0
2730
0
0
0
0
0
2600
0
2790
0
2790
0
5580
0
4000
0
3000
BINH TUY
************
TYP
LEG
n
IA
IB
1C
1A
D
IB
1C
n
1A
IB
P
1A
IS
1A
D
18
1A
0
IB
0
D
r
0
D
r
p
c
r
n
r
D
n
- n
2A
28
IA
IB
1C
IA
18
1A
IB
1A
IB
1A
IB
1C
IA
IB
1C
1A
IB
1A
IB
2A
26
3A
36
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
PROV NO,
UTM
YS800S60
YS62086Q
YS620ti70
YS8Q08&Q
YS620860
YS620870
YS 7 6 8
^80
¥592 0754
*S62Qa8Q
VS76038O
YS905760
YS 7 6 9 9
76
tsa«6ao2
YS6333O2
XDa48640
XC«9436AO
Y5790B40
¥ S3 10 730
YS7S8779
YS880T67
YSIVS?*©
YS9O0760
YS78O700
YS883767
YS789782
ZS270850
ZS220«60
ZS220890
YT980360
YT89O460
YT 8 2 0420
YS910787
YS718787
Y? 9 79 45 8
YT891420
YT867423
YT859434
YT918424
YT900425
YS7S8860
YS830699
YS170964
YT660039
YS795890
YS858855
YT643138
YT733300
YT912235
YT923088
ZT003010
18
�DATE
67070S
670709
670709
670711
670711
670713
670713
670715
670715
670719
670719
670720
670720
670725
670725
670728
670728
670801
670801
670322
670822
670822
670822
670825
670825
670P25
670825
670825
670825
670825
670825
670826
67082&
670826
670826
670911
670911
670916
670916
67091B
670918
670921
670921
670921
670921
670924
670924
670924
670924
670930
ftGM
W
0
0
W
0
W
W
0
0
W
0
(J
W
GALS
0
0
0
4000
0
3000
0
3000
0
2650
0
6000
0
5950
0
TYP
30 00
P
0
5000
0
2000
0
0
0
3870
0
3000
0
2000
0
1000
P
0
E
0
n
P
P
C
P
D
D
0
0
W
1000
0
0
n
0
0
0
0
0
r>
p
1000
0
6000
0
2000
0
5000
0
2000
0
0
0
3000
0
3000
0
4800
D
P
P
P
C.
p
D
P
LEG
IB
2A
2B
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1ft
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
IA
IB
1A
18
1A
IB
1A
16
1A
IB
1A
IB
LA
IB
2A
2B
1A
18
1A
IB
IA
UTM
YS970907
YS847996
YS924V85
YT740300
YT656156
YS838881
YS868756
YS8I7965
YS661039
YT66Q04O
Z5060999
YS894994
YT&S42QO
YT95PO53
VS8D38A4
YS328738
ZSO64995
ZT150267
ZTOeOlBO
ZT160249
ZT09D150
VS877760
¥5843032
¥S877t6Q
YS843832
YS815T55
¥5640755
YS 81575 5
¥5640755
ySft63755
¥5833829
YS833829
YS815757
¥S632?57
YS865844
YS9p5805
YS630770
ZS2QOS8Q
AM728874
ZS2O586O
ZS280850
Y 579,7859
YS626859
YS800822
YS632821
YT976323
�UNCLASSIFIED
MISSIONS STfRT IMG IN
BINH TUY
:*JS #** t.
DtTP
670930
670930
670930
671013
671013
671013
671013
67101 r
671017
671013
67101G
671021
671021
671021
671021
671024
671024
671026
671026
671026
671026
671026
671026
671026
671026
671026
671026
671028
67102B
671023
671023
571031
671031
671129
671129
671130
671130
680116
600116
630318
680318
680316
6 80 31 6
680321
600321
680322
630322
630325
680325
680325
AGN
GALS ^
TYP
0
0
B
W
0
0
0
B
R
B
W
0
n
n
0
W
0
0
1200
0
0
0
3900
0
'3600
0
4000
0
0
0
4000
0
3900
0
0
0
3600
0
0
0
0
0
3700
0
0
0
7950
0
3000
0
3000
0
2900
0
4850
0
1000
0
3900
C
P
P
0
W
W
8000
0
6000
0
2950
L6G
18
24
28
LA
IB
2A
28
1A
IB
16
IB
1A
IB
2A
r
c
c
c
0
c
c
c
D
r
r
0
W
PROV NO. = 1 8
*****
r
r
n
2B
1A
IB
1A
IB
2A
2B
1A
IB
1C
2A
2B
2C
LA
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
UTM
YT820430
YT91539C)
YT935355
YT924512
YT923544
YT942540
YT928525
YS8O4790
YS632787
YS795780
YS638780
YT8450OO
YS 89 799 2
¥ 8 9 9
5 4 9 4
YS 89898 5
YS319968
YT659043
ZT220460
ZT190390
ZT160570
ZT040340
ZT124444
ZT188413
ZT078448
ZT083444
ZT148390
ZT084359
ZT24O430
ZT040350
ZT050410
ZTI6045O
YS8O0766
YS636766
YT814S04
YT814914
YT914974
YT954914
YT646132
YT678192
YS760887
YS615888
YS780887
YS615888
YS600626
YS62O826
YS8&0772
YS690772
YS780868
YS612863
YS313349
�MISSIONS
CUTE
680325
630325
680325
680325
680404
680404
630413
63O413
680417
630417
680421
680421
630506
630506
680527
630527
680604
680604
680619
6 806 IS
700309
700314
700929
700929
700929
7O0929
700929
700930
700930
7O0930
701119
7-O1119
701119
701119
701119
701119
701119
701208
701208
701208
701208
701208
701208
701208
701208
701208
701208
701208
70120G
701208
STARTING
V3N
W
0
W
0
o
w
0
W
W
0
0
6
B
PI
B
IN
GALS
0
0
6000
0
6000
0
6000
0
5800
0
5700
0
5800
0
4000
0
6000
0
3000
0
40
100
220
0
0
0
0
110
0
0
3400
0
0
0
0
0
0
150
0
0
0
0
0
0
0
0
0
0
0
0
BINH TUY
*****;«:******
T¥P
0
P
LEG
16
1C
1A
ie
D
1A
IB
1A
IB
1A
IB
IA
D
1A
D
IA
IB
1A
IS
iA
16
IA
iA
IA
2A
3A
4A
5A
IA
2A
3ft
IA
IB
1C
ID
IE
IF
1G
IA
IB
1C
ID
IE
IF
1G
1H
11
1J
IK
1L
1M
P
•
P
D
0
S
S
C
'
C
C
C
ie
is
UTM
¥5850750
¥5831810
YS74Oa97
YS615897
YSdO0742
Y $63 0742
¥5798910
¥584*748
¥5810774
Y5632774
YS7BO375
¥S6O58?5
YS81Q779
¥563-2778
YS3O4892
YS8&2753
YS79789Q
VS84675Q
YS760863
YS6O5863
¥1894560
¥1894560
ZTUP22S
ZT1 14244
ZTIJ382O8
ZT 104 194
ZTQ9Q200
ZT105256
ZT106245
Ztl 14234
ZT 15051 8
Z! 132 43 7
ZT135466
ZT138462
ZT15O435
ZT2O8425
ZT250370
ZT201406
ZT172426
ZT177442
ZT180442
ZT129448
ZT123447
ZT128448
ZT112473
ZT129490
ZT118486
ZT116490
ZT114495
ZT134505
�IG IN
MISSIONS STARTING IN
DATE
701208
701208
701208
701208
701208
701209
701209
701209
701209
701209
701209
70120^
701209
701209
701209
701209
7O1209
701209
701209
701209
701209
701209
701209
701210
701210
701210
701210
701210
701210
701210
701210
701210
701210
AGN
GALS
0
0
0
0
0
113
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
. 0
0
107
0
0
0
0
0
0
0
0
0
BINH TUY
************
TY°
LEG
IN
10
IP
1Q
IR
C
1A
IB
1C
10
IE
IF
IG
1H
11
1J
IK
1L
1M
C
IN
10
IP
1Q
IR
1A
16
1C
ID
IE
IF
IG
1H
II
1J
PROV NO. = 18
UTH
ZT133541
ZT168552
ZT150550
ZT152558
ZT185555
ZT127437
ZT136484
ZT137490
ZT134455
ZT131431
ZT138432
ZT156455
ZT155442
ZT165448
ZT168456
ZT176437
ZT177450
ZT18245'V
ZTI62440
ZT187446
ZT182448
ZT184426
ZT196422
ZT150540
ZT150545
ZT150549
ZT157543
ZT155535
ZT153538
ZT1 80579
ZT082467
ZT087470
ZT153423
�NREC= 17757
NREC= 17757
NPPTV=
NPROV=
139
139
MZR£C=
NZPEC=
244
244
UNCLOSE IFI'-iD
�MISSIONS STARTING IN
DATE
651021
651021
651021
651022
651022
651024
651025
651025
651026
651026
651026
651026
651027
651028
651028
651030
651030
651030
651030
651030
651102
651102
651103
651103
651106
651106
651112
651113
651113
651113
651113
651114
651116
651116
651117
651117
651119
651119
651120
651124
651124
651124
651124
651125
651125
651216
651216
651217
651217
660410
iGN
0
GALS
3000
0
0
0
3UOO
0
0
0
0
0
1000
1700
3OOO
1800
0
2000
LONG KHANH
TYP
f
LTG
1A
IB
1C
r
1A
18
1A
c
c
c
c
1A
1A
1A
IB
1A
0
D
0
0
0
0
0
0
2000
3000
1400
2000
0
1800
18
1A
1A
IA
iA
C
c
c
c
c
ie
1A
IB
1C
1A
IB
1A
18
1A
0
0
0
3000
0
a
2000
a
2000
0
3000
2000
0
0
0
0
0
0
0
0
20QO
2000
0
2000
0
0
0
1500
0
0
a
3000
2000
c
c
c
c
c
c
c
c
c
c
c
4000
0
0
2700
0
n
4000
0
1000
0
•
IB
1A
IA
18
2A
26
IA
IA
IB
1A
16
1A
IB
f
1A
1A
18
2A
2B
1A
IB
1A
c
r-
1A
IB
1A
0
0
0
0
PROV NO. = 19
D
ie
UTH
YT270620
YT350530
YT360430
YT15O320
YT110470
YT580590
YT570580
VT160330
YT120320
YT180410
YT255280
YT245500
VT580530
YT110420
YT150320
YT1502S5
YT 140325
YT36O530
¥T 365 5£0
YT430580
¥T3102?0
YT31O360
YTO9Q400
ft 18 0530
VT2OO55O
YT33072Q
¥T12049O
tTl§5315:
¥TQ«J5400
Y7O80395
¥T1 104-70
YTJOsOfoOO
YTOS043O
YT1SO52Q
¥T24>058O
YT33076O
¥TO«5420
VT2O5&44.
YT3Q050O
YT31026Q
¥1325350
YT030445
YT090435
¥Ta85420
YT21055O
YTl 89590
YT255450
Vf?250580
¥f 330 J2&
YTUQ32Q
�UNCLASSl<-it:U
LONG KHANH
******
******
LEG
TYP
GALS
18
0
1A
D
2000
18
0
1A
p
2000
IB
0
IA
C
3000
16
0
1A
V
2600
IB
0
1A
27CO
D
IB
0
1A
D
3000
IB
0
IA
C
1000
IB
0
1A
0
1800
18
0
IA
D
1900
IB
0
1A
0
3000
IB
0
1A
0
3000
IB
0 V ...l:..
D
1A
2000
IB
0
2A
0
2B
0
1A
0
2000
18
0
2A
0
28
0
1A
0
2000
IB
0
1A
D
3000
IB
0
1A
D
4000
IB
0
1A
D
1000
1A
n
2000
1A
D
27CO
18
0
1A
D
2700
IB
0
1A
0
3600
18
0
P
1A
3600
IB
. 0
c
1A
3600
IB
0
IA
c
2700
PRO\T
MISSIONS ST4RT ING IN
DATF
660410
660423
660423
660425
660425
660504
660504
660504
660504
660505
660505
660505
660505
660508
660508
660511
660511
660511
66051 1
660517
660517
660517
AGN
0
0
0
0
0
0
0
0
0
0
0
6 60 5 1 7
660520
660520
660520
660520
660520
660520
660520
660520
660524
660524
650526
660526
660604
660604
660613
660616
661016
661016
661017
661017
661020
661020
661022
661022
661024
661024
661024
0
n
0
o
0
0
0
0
0
w
w
w
ri
1
UTH
YT180320
VT180270
W80333
YT175275
YT18Q330
YT529096
YT650105
YT 524 101
YT655112
YT 522104
YT655116
YT650108
YT775150
YT160Z85
YT160330
YT655111
YT826154
YT655U1
VTS26154
YT850148
¥1708123
YT850148
YT708123
YT578134
YT623139
YT520105
YT533117
YT650105
YT710U9
YT720131
YT655U1
YT7O2119
YT867136
YT850154
YT668110
YT750150
YT950065
YT150290
YT150290
YT330360
YT330510
YT360490
YT210490
YT382409
YT382600
YT360390
YT360550
YT300290
YT300487
YT050270
�MISSIONS START ING IN
DATr
661024
661025
661025
661025
661025
661025
661025
661026
661026
661027
661027
661029
661029
66103Q
661030
661030
661030
661101
661101
661101
661101
661102
661102
661103
661103
661103
661103
661104
661104
661104
661104
661105
661105
661107
661107
661108
661108
661108
661108
661108
661108
661109
661109
661110
661110
661112
661112
661112
661112
661113
AGN
0
0
0
w
0
w
-
w
w
w
w
0
n
0
0
0
w
w
w
w
'•:•!
w
w
w
w
w
LONG KHANH
*********##+
GALS
TYP
LEG
0
18
li
D
1800
0
18
e
1800
1A
0
IB
1A
1800
0
0
IB
1800
1A
c
0
18
n
3600
1A
3
IB
3600
0
1A
0
16
0
1A
3600
0
16
3600
1A
0
16
0
n
1A
3600
0
IB
'o
1A
3600
0
16
r
1A
2700
0
IB
1A
1800
0
0
18
1A
E
1800
0
IB
14
2700
C
0
IB
1A
5400
D
IB
0
0
1A
4500
IB
0
3600
C
1A
0
IB
2700
v.
1A
IB
0
2700
n
1A
0
16
3600
1A
0
IB
0
0
1A
1800
IB
0
1A
3600
r
0
IB
D
2700
1A
0
IB
IA
3600
D
0
IB
n
1A
27CO
UTM
YTO57480
YT40039S
YT4O059/0
YT 170370
YT17P560
YT49041O
YT49061JQ
VT330360
YT33052O
Y73253*8
YT3255SO
YT5.35440
YT535690
Yf 2 70290
YT2 704J90
YT24O370
YT240570
YT38040O
YT 3 0 . 0
859
YT290290
VT29O49Q
YT35639Q
YT3 56596
Y7353387
YT353605
YT3O6297
YT3Q6475
YT3,O3290
YT303508
YT380410
YT3 80600
YT49441O
YT494666
YT390390
YT395632
YT330360
YT330510
YT5O0410
YT500640
YT580530
YT580760
YT21037O
YT210593
YT400400
YT400640
YT321355
YT323580
YT515440
YT518648
¥7361390
�DAT?
661113
661113
661113
661114
661114
661114
661114
661115
661115
661116
661116
661117
661117
661117
661117
661117
661117
661118
661118
661118
661118
661119
661119
661121
661121
661122
661122
661123
661123
661125
661125
661126
661126
661126
661126
661127
661127
661127
661127
661129
661129
661216
661216
661216
661216
661216
661216
661216
661216
661216
AGN
W
n
D
0
0
C
0
W
0
0
n
0
Q
0
0
0
0
0
0
G
0
O
GALS
0
2700
0
2700
0
2700
0
2700
0
1800
0
2700
0
1800
0
900
0
2700
0
2700
0
2700
0
2700
TYP
f
0
n
r
D
D
r
0
0
D
D
C
6
2700
0
3600
0
2700
0
3600
0
3600
0
3600
0
0
0
3600
0
3600
0
0
0
4500
0
0
0
4500
D
0
0
D
D
P
D
D
r
c
LEG
IB
IA
IB
IA
18
1A
18
1A
IB
1A
IP
1A
IB
1A
IB
1A
IB
1A
16
IA
16
IA
18
1A
IB
U
18
IA
IB
1A
IB
1A
IB
IA
, IB
1A.
18
2A
2B
It
IB
IA
IB
2A
2B
1*
IB
2A
28
1A
UTM
YT361580
YT344383
YT344570
YT3S7398
YT400621
YT384396
YT383573
YT3S7396
YT397593
YT350390
YT350560
YT386388
YT390553
YT408395
YT41354Q
YT403395
YT413540
YT370395
YT370560
YT365394
¥T3?65560
YT405396
YT405563
YT340380
VT340540
YT410393
YT4O9562
YT386395
YT390570
YT530438
XT530593
YT428380
YT428540
YT349386
YT389560
YT346385
YT393393
YT346550
YT395460
YT500420
YT50060Q
YT342415
YT412U5
YT412423
YT320423
YT 3 2 543 5
YT400435
¥1325445
Y-T4£S5445
YT342430
*
�UNCLASSIFIED
MISSIONS STARTING IN
OAT C
661216
661216
661216
661220
661220
661226
661226
661226
661226
661226
661226
661226
661226
661226
661226
670102
670102
670103
670103
670103
670103
670104
670104
670105
670105
670105
670105
670105
670105
670108
670108
670109
670109
670110
670110
670114
670114
670201
670201
670203
670203
670204
670204
670205
670205
670206
670206
670207
670207
670207
AGN
0
0
0
0
0
0
w
w
B
8
8
W
0
0
w
0
0
0
n
0
w
n
LOMG KHANH
************
TYP
GALS
LEG
0
IB
0
2A
0
28
3600
0
1A
IB
0
D
1A
3600
0
18
0
2A
0
2B
D
1A
3600
0
18
IA
27CO
0
0
16
0
. 2A
0
2B
D
3600
1A
0
18
D
2700
1A
0
IB
3600
D
IA
0
IB
3600
C
1A
0
18
3600
D
1A
0
IB
D
3600
1A
0
16
D
1A
3600
0
IB
2700
r
' 1A
0
IB
2700
D
14
0
IB
1800
D
1A
0
IB
0
1A
1800
0
18
1800
D
14
0
16
0
1800
1A
0
IB
1
2700
D
1A
0
IB
D
2700
1A
0
IB
P
4500
1A
0
IB
D
5400
1A
0
IB
2700
D
1A
PRCV NO. = 19
UTM
YT41Q430
YT358477
YT41Q477
YT 15,0850
YU45650
YT340462
¥1410462
¥1340450
YT410A50
YT3404&5
YT4i0475
VT34O465
YT41O465
YT3-4G474
VT410474
VT2OO370
YT2OS570
VT22O370
VT220515
YT523438
YT523618
YT3QO330
YT300530
YT340440
YT37043Q
YT37O430
YT370423
Y737O422
YT370412
YT170370
YT170550
YT576532
YT5T2730
YT320350
YT320530
YT3 10290
YT3 10490
YT620590
YT630750
YT562520
YT560714
YT46038O
YT462i>52
YT413391
YT416570
YT527437
YT527620
YT270430
YT270600
YT573529
�DATF
670207
670212
670212
670213
670213
670216
670216
670216 .
670216
670217
670217
670217
670217
670221
670221
670221
670221
670221
670221
670223
670223
670223
670223
670223
670223
670224
670224
679225
670225
670225
670225
670225
6,70225
670226
670226
670226
670226
670226
670226
670226
670226
673226
670226
670227
670227
670227
670227
670227
670227
670227
6GN
D
0
0
:o
n
0
0
0
0
0
ft
0
0
0
0
n
n
0
0
o
0
n
0
0
GALS
0
2700
0
2700 ~
0
1800
0
2700
0
1500
0
5400
0
2700
0
2550
0
27CO
0
810Q
0
0
0
8100
0
5400
0
5400
0
4500
0
2700
0
2700
0
2700
0
2700
0
1800
0
1800
O
2700
0
2700
0
27CO
0
2700
TYP
L5G
18
D
1A
-n
IB
1A
IB
C
LA
UTM
YT569710
YT433381
YT433600
YT536466
YT5367Q7
YT310310
IB
D
0
1A
IB
IA
YT22337Q
YT223570
YT206434
14
18
IA
IB
¥T2C>3370
YT19B60Q
YT2J6294
YT27647Q
YT1T2482
YT172646
YT160380
YTi6059(i
YT15O3AO
te
D
0
0
C
c
r
D
D
D
P
0
"D
P
0
r
D
c
c
D
IA
IB
1A
IB
IA
IB
2A
2B
i-A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
LA
IB
IA
IB
1A
IB
1A
IB
IA
IB
1A
18
1A
YT1^>036Q
¥1160550
YT17236O
YT13336Q
YT|33550
YT195430
YT^OO^QQ
VT2i 0*3=0
YT2056OO
YT14036Q
YTt4O56O
YT5Q,041O
YT5O060Q
YT245370
YT24543O
YT233430
YT290320
YT2-9050Q
YT441388
YT441590
YT218430
YT218593,
YT250450
YT25060Q
YT21043Q
YT21O600
YT225430
�UNCLASSIFIED
M I S S I O N S S T A R T I N G IN
DATE
670227
670228
670228
&GN
670228
6 7022 3
670228
670228
670228
670228
670304
670304
670304
670304
670316
670316
670316
670316
670317
670317
670317
670317
670406
670406
670406
670406
670406
670406
670414
670414
670415
670415
670415
670415
670421
670421
67Q421
670421
670425
670425
670429
670429
670502
670502
670503
6705O3
670504
670504
670506
670506
670507
0
GALS
LONG KHANH
TYP
0
0
2700
0
D
0
0
n
2700
5400
4200
3
1800
0
0
0
900
0
1A
16
1A
18
1A
IB
IA
18
2A
28
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
0
D
D
0
0
1 800
n
0
0
930
0
D
W
1860
D
0
0
2790
D
0
0
2790
P
0
0
2790
D
0
v»
3
M
w
w
w
2790
C
0
2790
C
0
2790
C
0
5700
D
0
2300
D
0
1860
D
0
W
w
w
n
1860
D
0
2790
0
1860
0
r
0
2790
1A
D
0
3
YTU036Q
YTU0570
IA
18
0
0
1A
C
0
0
UTM
YT225593
IB
0
2700
LEG
IB
IB
0
3600
PROV NO.
. D
YT6605«0
YT660740
YT 15 0660
YT325660
YT450380
YT450580
YT500670
YT 32 0670
YT50Q720
YT314720
YT268370
YT268470
YT25O370
YT250395
YT263370
YT263530
YT263370
YT263530
YT106360
YT106520
YT 106 360
YT 106520
YT120360
YT12Q520
YT113363
YT1 13532
YT264372
YT267530
YT196370
YT193520
YT540470
YT540646
YT 55 0490
YT549647
YT600570
YT6Q0750
YT130670
YT13O492
YT579560
YT576773
YT319345
YT319520
YT500619
YT335619
YT291325
YT2S4486
YT270710
19
�MISSIONS STARTING IN
DATE
670507
670508
67U503
67050<5
670509
670509
67050S
670510
670510
670510
670510
670513
670513
670514
670514
670515
670515
670516
670516
670517
6 705 1 7
67J518
670518
670519
670519
670520
670520
670521
670521
670521
670521
670522
670522
670522
670522
670524
670524
&70525
670525
670526
670526
670523
670528
670608
67060S
670613
670613
670614
670614
670615
AGN
W
W
.i
W
W
fc
'fl
W
W
w
w
N
w
0
ri
0
w
w
w
0
0
0
0
D
n •
GALS
0
4650
0
1860
0
2790
0
2790
0
1860
0
2790
0
1860
0
2790
0
2790
0
2790
0
3720
0
2790
0
2790
0
2790
0
2790
0
1860
0
1860
0
2550
0
4650
0
2790
0
2730
0
2690
0
4650
0
5580
0
3720
tONb KHANH
************
TYP
LEG
IB
D
1A
IB
D
1A
n
is
U
18
C
1A
D
1A
13
1A
IB
1A
18
1A
18
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
18
1A
18
1A
IB
r
c
r
c
0
0
D
D
D
D
n
p
0
0
D
0
p
ia
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
r.
D
r
1A
IB
1A
16
1A
UTM
YT270530
YT290720
YT29C53Q
YT300723
YT3O0562
YT498637
YT3.J.4637
¥1500661
YT320661
YT5Q0687
¥13006,87
YT552503
YT550670
YT43iO«6AQ
YT9Q76.00
YT42038Q
YT42Q553
YT294330
YT298503
YT424380
YT424546
YT440337
YT44O570
YT515440
¥T5 1 5 , 0
60
YT315335
YT313518
YT486337
YT43655Q
YT480372
YT485557
YT470380
YT4T055i)
YT47O330
YT47055Q
YT593570
VT592725
YT444388
YT 44 4 56 3
YT453384
YT453567
YT5a44i2
YT5ll57a
YT215370
YT215430
YT282293
YT282460
YT570528
YT57O7ie
YT607580
�MISSIONS STARTING IN
OiT^
670615
670616
670616
670617
670617
670618
670618
670619
670619
670619
670619
670619
670619
6706?!
670621
670628
670628
670702
670702
670704
670704
670704
670704
670717
670717
670717
670717
670720
670720
670720
670720
670723
670723
670723
670723
670723
670723
670723
670728
670728
670730
670730
670730
670730
670730
570730
670730
670730
670731
670731
AGN
n
0
0
0
w
0
n
W
W
0
0
W
W
0
W
u
0
W
W
H
0
n
h
tONG KHANH
************
LEG
TYP
GALS
IB
0
p
1A
4650
IB
0
IA
P
6510
18
0
1A
2700
D
IB
0
1A
C
3720
IB
0
1A
D
2790
IB
0
D
IA
1860
18
0
1A
r
3720
18
0
1A
D
2790
IB
0
0
1A
6510
IB
0
1A
3720
0
IB
0
1A
D
2600
IB
0
D
1A
5900
IB
0
1A
D
2500
IB
0
1A
C
3000
IB
0
1A
V
1000
0
IB
D
1A
2500
IB
0
2A
0
28
0
6
2C
C
1A
6000
IB
0
1A
3000
D
IB
0
D
1A
2700
IB
0
0
2000
1A
IB
0
C
IA
1000
IB
0
1A
D
3.0
00
IB
0
D
1A
2000
ie
0
UTM
YT6Q7750
YT 50 067 8
YT31867S
YT597572
YT597750
YT257370 •
Y7257540
YT530437
YT530600
YT530437
YT530600
YT240370
YT240430
YT500715
YT320715
YT506412
YT510576
YT5fc5548
YT565718
YT630593
YT632779
YT5Q0621
YT334621
YT585566
YT589750
YT2B6308
YT287500
YT180360
YT190521
YT 180360
YT190521
YT235370
YT235430
YT228370
YT228430
YT230310
YT257370
YT257530
YT254290
YT254508
YT236283
YT23837O
YT218277
YT21C37O
YT213277
YT218370
YT251277
YT249370
YT143490
YT 13 5340
*
�PAT?
670731
670731
670731
670731
67O806
670806
670806
67Q806
670806
670806
670806
670806
670807
670807
670807
670807
670.807
670807
670813
670813
670813
670813
67Q813
670813
670814
670814
670814
670814
670S14
670814
670814
670814
670815
670515
670815
670815
670815
670815
670S15
670815
670817
670S17
670817
670817
670Q18
670818
670818
670818
670822
670822
AGN
0
0
M
0
0
W
0
0
w
0
0
ri
W
Q
W
d
0
0
'.•(
0
V*
w
GALS
1000
0
5900
0
5600
0
0
0
3000
0
0
0
1950
0
3000
0
1450
0
4000
0
5000
0
1000
0
2000
0
1000
0
4000
0
1000
0
5000
0
3000 ~
0
1000
0
0
0
1000
0
4000
0
2000
0
1000
0
2000
0
TYP
e
D
p
p
D
0
0
D
0
P
c
r
D
D
r
~~P
0
D
D
n
0
D
tcG
1A
16
1A
18
1A
IB
2A
26
1A
16
2A
26
1A
IB
1A
IS
1A
IB
1A
IB
1A
IB
1A
IS
1ft
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
18
IA
IB
UTM
YT143490
YT135340
YT226524
YT234278
YT24228D
YT24237Q
YT259370
YT2592SO
YT186263
YT187433
YT2 593,70
YT259280
YT186263
YT167433
YT186263
YT187433
YT2U276
YT21237Q
YT1 48494
YT125304
YT1675OO
YT166320
YT16T500
YT 146320
YT1 26290
YT126460
YT126290
YT126460
YT1 90263
YTl 90430
YT190263
YT190430
YTO4928Q
YTQ48452
YT228528
YT232370
YT228528
YT232370
VQ726494
V0733512
YT100280
YT100470
YT100280
YTJ.00470
YT184263
YT184440
YT184263
YT184440
YT197267
YT197435
�UNCLASSIFIED
MISSIONS STARTING IN
DATE
670822
670822
670822
670822
670822
670822
670824
670324
670824
670624
670829
670829
670829
670829
670830
670830
670830
670330
670330
67O830
670901
670901
670901
670901
670901
670901
670902
670902
670902
670902
670903
670903
670908
670908
670911
670911
670913
670913
670913
670913
670914
670914
670914
670914
670915
670915
670915
670915
670918
670918
AGN
0
0
W
0
0
0
W
0
W
0
0
0
W
W
0
0
0
0
0
n
0
0
0
0
GALS
4000
0
3000
0
0
0
1000
0
3000
0
7000
0
3000
0
1000
. 0
4000
0
3000
0
3000
0
2000
0
3000
0
2000
0
2000
0
3000
0
3000
0
3000
0
6000
0
3000
0
3000
0
2950
0
5000
0
3000
0
2000
0
LONG KHANH
TYP
D
D
D
D
t>
D
C
P
D
D
P
0
0
PROV NO. = 19
LEG
1A
IB
1A
IB
2A
28
1A
IB
1A
IB
1A
18
u
IB
1A
16
IA
IB
1A
ie>
IA
16
It.
16
1A
IB
1A
IB
UTM
YT197267
YT197435
YT229285
YT229370
YT23I370
YT232285
YT158282
YT15C457
YT158282
YT I 5845 7
YT150283
YT130450
YT14ia8O
YT14145O
YT22353O
YT246370
YT223530
YT2A6370
YT21853G
YT2 1 3 7
8.0
YT207282
YT201433
YT542473
YT542640
YTQ-98285
YTQ9*J4.80
YT2Q5275
YT205450
0
P
D
0
0
D
r,
D
D
0
D
18
IA
IB
1A
18
IA
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
1C
1A
18
1A
IB
YT-11A4&0
YT2-05276
¥1205450
YT112280
VT112453
YTZQ-8530
YT20:8346
YT24O5X8
VT235355
YT266290
YT26637O
YT269530
YT269360
YT13450Q
YT134327
YT223280
YT217470
YT157283
YT157452
YT23'5>5101
YT233430
�UNCLASSIFISD
MISSIONS
D4T5
670919
670919
670922
670922
670922
670922
670924
670924
670925
670925
670926
670926
670926
670926
670927
670927
670927
670927
67J930
67Q930
671002
671002
671003
671003
671004
671004
671004
671004
671004
671004
671005
671005
671005
671005
671005
671005
671005
671005
671006
671006
671006
671006
671008
671008
671008
671008
671003
671008
671008
671009
STARTING
AGN
n
0
0
0
0
0
0
w
0
Q
0
0
0
0
0
0
n
0
0
0
0
0
0
0
IN
GALS
3000
0
2000
0
20CO
0
4800
0
2000
0
4550
0
2250
0
2000
0
1300
0
3000
0
2830
0
3300
0
2550
0
0
0
2800
0
3000
0
3000
0
2800
6
1930
0
6000
0
5000
0
5750
0
3000
0
2475
0
0
4000
LONG KHANH
TYP
C
V
r
0
0
D
D
0
D
n
0
D
r
D
c
0
D
D
D
D
0
D
0
r
PROV
LEG
1A
18
1A
18
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
18
1A
IB
1A
18
1A
13
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
13
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
UTM
YT216330
YT216370
YT16450O
YT164335
YT543475
YT545650
YT213530
YT2 13365
YT270310
YT27039Q
YT612580
YT61175Q
YST5C915
YS 75093 Q
YT226281
YT226396
YS 7 70921
YS770980
YT50066Q
YT325660
YT668573
YT668756
YS7279H
YS72 7979
YT102230
YT1O2376
YT095365
YTO92280
YT1 12280
YT112373
YT000478
YT16O478
YTQ00462
YT170462
YT000492
YT170492
YT000459
YT1 89459
YT000455
YT185455
YTOP0488
YT170A88
YTOOO498
YT18O498
YTOO0481
YT175481
YT232283
YT232370
YT233233
YT775925
NO.
19
�UNCLASSIFIED
MISSIONS STARTING IN
!G IN
D4TF
671009
671009'
67101
67101
671011
671011
671011
671011
671011
671011
671011
671012
671012
671012
671012
671013
671013
671014
671014
671014
671014
671015
671015
671015
671015
671016
671016
671016
671016
671017
671017
671017
671017
671017
671017
671018
671018
671018
671018
671018
671018
671020
671020
671020
671020
671020
671020
671020
671020
671020
•VGN
W
n
W
K
kl
il
n
0
o
K
0
O
0
W
0
•ft
w
0
0
LONG KHANH
GALS
0
0
7000
0
2000
0
0
2450
0
0
0
7000
0
3900
0
8000
0
3950
0
4OOO
0
3000
0
4000
0
2750
0
4000
0
3900
0
4000
0
5650
0
3600
0
7000
0
4000
0
5000
0
TYP
1200
D
0
3500
,0
0
0
2000
PROV NO, = 19
*
LEG
C
16
1C
IA
IB
1A
13
1C
1A
16
2A
26
1A
18
1A
IB
IA
IB
1A
IB
1A
IB
IA
IB
1A
IB
14
16
1A
16
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
0
IB
14
0
0
D
P
D
D
D
P
0
e
D
0
C
c
D
D
D
D
n
IB
IA
IB
1A
IB
2A
26
1A
UTM
YT775C.73
YT795SI43
Y T 2 1 52 7 7
¥1212448
YT26731G
YT265280
YT26737Q
YS744915
YST44990
YS7409IA
¥5*40980
YT2 15277
YTZ:12448
YT 28832 5
YT288500
YT 2803,20
Y T 27849Q
YT 29 I 329
YT29.1504
YTGGO4.64
YT 170465
YT223281
YT223377
YTGOQ471
YT170471
YT 15531 5
YT15541Q
YTOOO484
YT17Q4S4
YT500682
YT 3 206.82
YT592568
YT592737
YS 75691 6
YS 756 98 5
YT2803fcO
' YT280500
YT5AO620
YT320620
YT192265
YT192442
YTOO0475
YT180475
YTOO0475
YT180475
YT295423
YT295510
YT270512
YT287430
YT268720
iJKCl. *SS IF
�DATP
671020
671020
671020
671021
671021
671022
671022
671022
671022
671022
671022
671023
671023
671023
671023
671024
671024
671024
671024
671026
671026
671027
671027
671027
671027
&71028
671028
671029
671029
67102S
671029
671029
671029
671030
671030
671031
671031
671101
671101
671101
671101
671102
671102
671102
671102
671103
671103
671103
671103
671103
4GN
Q
W
W
Q
H
0
W
0
0
W
Q
0
0
W
0
0
0
0
n
W
W
0
W
u
GALS
0
2000
0
4000
0
4000
' 0
0
0
6150
0
4000
0
3900
0
4000
0
4000
0
2900
0
4000
0
7800
0
7925
0
3350
0
1925
0
925
0
3500
0
4000
0
4000
0
4000
0
4000
0
8000
0
4000
0
2000
0
6000
TYP
D
n
9
D
D
D
P
b
D
0
D
0
P
D
D
D
0
0
r>
LEG
IB
1A
IB
1A
IB
1A
18
2A
23
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
D
\t
D
IB
1A
18
r
0
1A
IB
1A
IB
0
IA
UTH
YT270535
YT268720
YT270535
YT562518
YT560705
YT22029Q
YT220413
YT234381
YT234330
YS733987
YS590987
YT650590
YT651767
YT642595
YT642762
YT672580
YT678780
YT000494
YT17O494
YS750983
YS5S0983
YT5QQ685
YT302685
YT49i5654
YT325654
YT 560520
YT560690
VT683580
YT683640
Y&672947
YS59J0947
YS672947
YS59O947
YS733910
YS733980
YTOO0468
YT 1754.68
YT000451
YT151451
YT672574
YT682753
YT5O0712
YT320712
YS760974
YS610974
YT4653B1
YT464541
YT614584
YT615750
YT614584
�OATS
671103
671104
671104
671104
671104
671104
671104
671104
671104
671105
671105
671106
671106
671106
671106
671106
671106
671106
671106
671106
671106
671103
671138
671108
671108
671109
671109
671109
671109
671112
671112
671113
671113
671113
671113
671113
671113
671116
671116
671116
671116
671116
671116
671116
671116
671117
671117
671118
671118
671119
AGN
W
0
W
W
GALS
0
4000
0
3600
0
0
0
0
0
4000
0
2000
TYP
D
0
D
18
0
O
0
0
w
0
0
0
0
0
w
0
•fi
•>
0
n
0
v»
0
r)
G
2000
0
300
0
3000
0
4000
0
4000
0
3700
0
3700
0
1600
0
2500
0
4000
0
4000
0
6
0
4000
0
3900
0
2000
0
900
0
4850
n
D
D
0
Q
D
0
D
0
D
n
1A
IB
1A
IB
1ft
16
IA
ie
1A
IB
1A
IB
1A
18
1A
18
1A
18
IA
IB
1A
IB
1A
IB
0
D
C
D
r-
• ,o
4000
0
4000
L£G
16
iA
18
1A
16
1C
2A
2B
2C
IA
D
n
2A
23
IA
IB
1A
IB
U
IB
1A
IB
1A
IB
1A
1R
1A
UTM
YT61S750
YT512576
YT512773
YT574782
YT574725
YT568720
YT56.6791
YT563780
YT563760
YT633600
YT62877Q
YI000441
YT16O442
YTQ.QO441
YT160442
YT640596
YT645751
YT640596
YT645751
YT5Q07OQ
YT3107OQ
YT000467
YTIT0468
YTi62438
YT&64578
YT472728
YS6659S38
YS590938
YT583590
YT532697
YT473380
YT473540
YT284498
YT180493
YT180495
YT24O495
YT556504
YT556680
YT545431
YT545630
YT551503
YT55164JO
YT551503
YT551680
YT642594
YT653760
YT660S81
YT66^750
YT617588
�UNCLASSIFIED
M I S S I O N S STARTING
IG
IN
LONG KHANH
PRQV NO.
t' + $ "*»*•»• i 5^ Si A jfc
AGN
671119
671120
671120
671120
671120
671120
671120
671121
671121
671121
671121
671122
671122
671123
671123
671124
671124
671124
671124
671124
671124
671124
671124
671125
671125
671125
671125
671125
671125
671125
671125
671126
671126
671126
671126
671128
671128
671128
671128
671128
67112B
671128
671126
67112C
671128
TYP
0
0
4000
0
0
5000
C
n
O
0
4000
c
0
0
6000
0
4000
D
n
0
c
w
7000
D
0
8000
D
0
9
7925
D
0
VI
4000
P
0
0
w
4000
0
0
4000
0
0
0
6000
0
w
2900
0
w
2000
D
r
t
0
0
3000
0
0
0
o
5800
0
0
6000
D
0
0
2000
D
0
3000
C
0
0
2850
W
1850
D
0
[,.
0
0
1003
n
0
0
671129
671202
671202
671203
GALS
3000
I
0
\n
3000
D
0
5000
C
LEG
IB
1A
IB
1A
18
1A
IB
IA
16
1A
18
1A
18
IA
IB
IA
IB
1A
IB
IA
IB
1A
IB
IA
18
14
IB
IA
IB
IA
IB
1A
IB
1A
IB
1A
IB
1*
IB
1A
18
IA
IB
1A
16
1A
18
1A
IB
1A
UTM
YT617765
YT482387
YT482534
YT44738B
YT448551
YT475383
YT477536
YT4984Q9
YT498572
YT529438
YT529615
YT513413
YT513590
YT5.2 343,7
YT523603
YT4573SO
YT457554
YT4|8386
YT4iS543
YT34O377
YT34Q550
YT3.12290
YT300281
YT144284
YT466391
YT4&6181
YT 46:6 551
YT352396
YT3S2rx&l
YT257501
YT234330
YT5QQ689
YT330689
YT481386
YT481585
YT700552
YT700635
YT500703
YT315700
YT500703
YT315700
YT260467
YT241319
YT.520601
YT350601
YT4-98634
�DfiTE
671203
AGN
671204671204
671205
671205
671205
671205
671206
671206
671207
671207
671208
671208
671209
671209
671210
671210
671211
671211
671212
671212
671213
671213
671213
671213
671213
671213
671213
671213
671213
671213
671216
671216
671223
671223
671224
671224
671228
671228
671229
671229
6/1229
671229
68O10.7
630107
6301 J7
630107
680111
680111
630111
Q
W
w
w
0
0
0
0
0
W
0
w
n
W
0
0
C
n
0
0
0
0
W
W
GALS
0
6000
0
6000
0
3000
0
3000
0
3000
0
3000
0
2700
0
5500
0
5000
0
5000
0
4900
0
1000
0
3000
0
1000
0
2000
0
6000
0
5000
0
6000
0
5000
0
2900
0
5900
0
4800
0
925
0
5S50
0
0
TYP
C
C
1
n
V. . .. -lp
D
C
D
D
C
C
0
r
D
0
r
0
D
D
D
0
C
C
r
r
LEG
IB
1A
IB
1A
IB
1A
ie
1A
16
1A
IB
1A
IB
1ft
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
16
1A
IB
1A
IB
1A
18
2ft
UTM
YT310634
YT513582
YT513750
YT531626
YT352626
YT635600
YT631763
YT50065Q
YT320650
YT5Q0608
YT320612
YT500640
YT332640
YT 50062 9
YT3Q8629
YT50O646
YT327646
YT500610
YT330610
VT490601
YT310601
YT4905S2
YT304582
YT490582
YT304582
YT5.0070&
YT326706
YT500599
YT310599
YT5i00599
YT310599
YT 50069 5
YT297695
YT500667
YT332667
YT489590
YT310590
YT490586
YT3U5&6
YT274705
YT274534
YT48&573
YT323573
YS757978
YS5'?6978
Y5757978
YS59697S
YS667942
YS590942
YS590953
�DATE
680111
680113
680113
630115
680115
630117
630117
680118
6 891 IS
630119
63O11?
630119
633119
680120
680120
6S0120
680120
630121
680121
680121
680121
680125
683125
680127
680127
630127
630127
680129
680129
630206
630206
680322
630322
680324
680324
630331
680331
6&0405
680405
630727
680727
630727
680727
630727
630731
680731
630731
680731
680808
680808
AGN
T¥P
GAtS
0
0
D
26
IA
IB
•p
1700
1A
0
W
n
4300
le
0
6000
P
0
n
6000
W
3000
0
0
,
(3
0
0
0
0
5500
0
0
0
0
0
w
1000
0
0
6000
P
0
0
w
w
4000
D
0
8000
0
3350
P
e
0
D
8000
D
0
0
1800
0
0
W
4000
0
W
5000
D
P
0
W
3000
3'OGO
w
2500
1A
18
D
1A
IB
1A
Ib
1C
1A
18
1ft
IB
1C
ID
1A
13
w
r\
0
C
0
0
1900
0
385
0
D
P
. 0
0
H
2000
0
0
YS738969
YS730963
YS590963
1A
IB
1A
16
1A
IB
2A
2B
1A
18
2A
28
IA
18
1A
IB
IA
IB
IA
IB
1A
18
1*
18
1A
IB
1A
Ifi
1A
IB
D
0
0
tea
YT 32057:6
YT490595
¥1310595
Y 56,65937
YS590937
Y $5989,17
YST439i3
YS74393Q
¥5767916
YS71676SO
YT5176OO
YT51776G1
Y751760O
YT5 ITTibQ
¥T 13 76,80
YT13751Q
YT500560
YT32&56S
YS7369&6
YS62Q966
YTSQ()724
YT327724
YT50Q672
YT332674
YS7S0958
¥576,0975
YS590975
YS 58 59.6 7
ZU24Q575
ZU131455
YT677271
YT5242?!
¥T739001
YT733184
YT599098
YT612112
YT615113
YT6O8097
YS791970
YT791120
�D4T^
680930
6B0930
680930
6B0930
681013
631013
681013
631013
681014
681014
6S1015
681015
681016
681016
681016
631016
6S1016
681016
681026
681026
681023
681028
68112<;
681129
681129
631129
631129
681202
681202
631203
681203
681206
681206
681203
681208
681210
6S1210
681210
681210
681210
681210
681212
681212
681213
681213
631214
681214
681214
6S1214
681214
AGN
P!
i-i
w
w
w
w
w
w
w
w
w
W
W
w
w
w
w
w
w
w
w
w
GALS
70
0
0
0
6000
0
4000
0
5000
0
4000
0
6000
0
3000
0
5000
0
5000
0
5600
0
60CO
0
0
3000
0
3000
0
5300
0
5000
0
6000
0
6000
0
6000
0
0
0
9000
0
6000
0
550
0
0
0
6000
TYP
P
LFG
1A
IB
1C
10
C1
0
D
D
D
D
D
D
r
0
t
p
P
0
D
D
D
r
P
p
1A
IB
1A
18
1A
18
1A
IB
1A
18
1A
18
1A
IB
1A
16
1A
ie
IA
IB
1C
1A
18
1A
IB
1A
IB
1A
IB
IA
IB
iA
IB
IA
IB
2A
2fi
IA
IB
1A
IB
1A
IB
1C
10
D
1A
UTM
YT603107
YT&08107
YT60C103
YT6031Q3
YT655308
YT526232
YT741010
YT73T173
YT667293
YT527215
YT6236Q2
YT 596460
YS798972
YT798120
YT658306
YT528229
YT702000
YT702170
YT735O10
YT 73 5 1-8.0
Y763S331
YT552267
YT596599
YT58353Q
YT533460
YT640328
YT522265
YT719OO9
YS590946
YS7a?990
YT787130
YT7 17030
YT71T175
YT483336
YT6i8480
YT745O10
YT743183
YT770072
YT70O030
YT666023
YS559987
YT615fell
YT549444
YS794990
YT794118
YT5V7i>yd
YT610097
YT610106
YT6O010i>
YT610612
�UNCLASSIFIED
MISSIONS STiRT ING IN
DATE
661214
631214
631214
681214
681214
681214
681214
681214
631214
681217
681217
631218
681218
681218
681218
681218
681218
681219
681219
681219
681219
681219
681219
681219
631219
681220
681220
681227
681227
681227
631227
681227
6fll227
631227
681227
681228
631228
681231
631231
631231
681231
690404
690914
690914
690914
690914
690917
690^17
690917
690917
LONG KHANH
PROV NO. = 19
£ * * * * *
* * * * * *
AGN
GALS
0
W
W
W
W
W
W
W
W
W
W
1
W
W
W
W
W
Q
n
3000
0
0
0
6000
0
0
0
6000
0
3000
0
0
0
5000
0
3000
0
3000
0
0
0
4000
0
2000
0
5000
0
5000
0
0
0
5000
0
6000
0
3000
0
0
0
800
3000
0
0
0
6000
0
0
0
TYP
r:
0
L
P
p
0
D
D
D
0
P
0
n
D
P
r
r
Leo
IB
IA
•IB
2A
28
IA
IP
2A
2B
U
IB
1A
IB
2A
26
1A
18
IA
IB
IA
16
2A
2B
IA
IB
IA
16
IA
IB
1A
13
2A
2B
1A
IB
IA
18
IA
IB
2A
2B
1A
1A
16
2A
2B
1A
IB
2A
2R
UTM
VT54043f.
VT727053
yT685O35
YT63F5Q28
YS59O988
YT77401S
¥T75toOaa
¥57169^3
YS 590 93 3
YT660606
¥Ti«)446,7
YTTO3536
YT63O486
YT6284S8
YT701538
YT73OQiO
YT730iai
YT627490
¥14^8395
YT6835S68
¥76 1 OS19
YT60S522
YT68057Q
YTT22020
YT 722177
YT652616
YT591465
YT605614
YT528423
YT693550
YT6215O1
YT6Z0505
YT691555
YT655611
YT595463
YT682500
YT602615
YT 68 4 56 6
YT612517
YT627491
YT699541
YT603102
YT199543
YT262488
YT263400
YT243378
YT418563
YT364575
YT363437
YT3S0410
�UNCtASSIFIaC
PROV N O . = 1 9
MISSIONS
r>ATC
690926
6 0 2
9 9 6
690926
6 0 2
9 9 6
691003
691003
691003
691007
691007
691007
691007
691008
691008
691008
691016
691016
691016
691017
691017
691317
691017
691019
691019
691019
691019
691103
691103
691103
691106
691106
STARTING
AGM
H
LONG KHANH
TYP
GAtS
7000
r>
0
0
0
IB
1C
ID
1A
IB
1C
1A
IB
0
0
D
7800
0
0
0
0
0
0
5300
W
0
0
4 0
0 0
W
1C
0
6 0
0 0
0
ID
IA
n
IB
1C
1A
IB
1C
n
1A
IB
0
0
0
W
5000
2A
p
3 0
0 0
28
D
0
0
W
6 0
0 0
D
0
0
0
0
0
0
0
3 0
0 0
P
0
0
0
0
6 0
0 0
0
0
0
4 0
0 0
0
4000
0
0
0
1 A
i^
IB
1C
1A
IB
1C
10
2A
2B
2C
1A
IB
1C
1C1A
18
1C
10
n
1ft
IB
0
0
3
28
IA
IB
2A
0
0
0
»t
LCG
IA
r
6000
0
69 HO 6
691106
691100
691106
691106
691110
691110
691110
691110
691117
69111 r
691117
691117
6-9112?.
691122
691122
691125
69112-5
691125
691125
IN
1C
0
1A
lb
1C
10
UTM '
YT203546
YT27546Q
YT273430
YT245373
YT2O75SO
YT265496
YT268400
YT 198542
YT215523
VT257487
YT26Q4OQ
¥T 58 1 532
YT502604
YT443539
YT403564
YT357525
YT357435
YT4O8561
YT363522
YT367443
YT381420
YT272423
YTST^AOi)
YT2-*4363
YT255276
YT493<>00
YT4(>a5<>7
YT350516
YT2ft6400
Y-T2383163
YT23S340
YT2443!OO
YT259402
YT233365
YT241300
YT221517
YT25348O
VT"? tvAi-AA.
T - £.y* f+v*r
YT231369
YT579&76
YT49059A
YT4205fc4
YT411557
YT5B1584
YTSQ1599
YT41056'>
YT5ROSS5
YT506606
YT47ia6QO
YT4235>75
�MISSIONS STARTING IN
D-'.TS
f.91222
691222
691222
691222
691226
t>'H226
691226
691228
691228
691228
7O032S
GAtS
2000
0
3
0
4700
0
0
2900
0
0
100
LONG KHANfi
************
I.EG
TVP
1A
0
16
1C
10
l£
IB
1C
1A
IB
1C
1A
PROV NO.
UTN
YT415552
YT365510
VT579573
VT48959O
YT460573
YT473513
19
�NREC= 17079
NREC= 17079
NPRPV=
NPROV=
430
480
NZREC=
NZREC=
581
581
UNCLASSIFIED
�PHUOf. LONG
M I S S IONS START ING IN
**##%*:*#****
1ATF
651020
651020
651020
651020
651021
651021
651022
651022
651023
651023
651023
651023
651023
651023
651024
651031
651101
651102
651102
651102
651102
651119
651119
651216
651216
651216
651216
661031
661031
661102
661102
661104
661104
661201
661201
661201
670112
670112
670202
670202
670202
670202
670410
670410
670410
670410
670413
670413
670413
670413
AGN
0
0
GALS
1400
Q
1750
TYP
C
f
IB
0
0
18OO
0
0
0
0
2500
0
500
0
0
1100
0
0
0
0
0
0
1000
1800
1600
2500
C
f
f,
0
o
2600
a
0
a
2700
0
3
3600
e
c
c
0
2700
0
6300
D
C
0
c
D
D
0
0
5400
D
0
0
1860
0
0
0
2790
0
0
2790
0
0
2790
0
IB
1C
te
2A
2B
IA
ta
UTM
YT5109at)
YT53a73Q
YT510980
YT520?ap
vuai 11230
YU4O33.1O
YT5009OO
Yt51O78Q
YU29Q190
YU36026O
Y03«Q26JE>
YU5*32OO
YU53G200
YU46Q3OO
Y*6QQ8«0
vmoaeoid
YT530830
YT6609OO
YT66073Q
Yisoosao
YT55O730
VTO5O665
YTOS5565
D
n
p
IA
Yfisasao
IB
0
6
0
1C
1A
1A
1A
1A
0
1800
1A
IB
c
c
t
0
0
16
1A
0
0
0
3600
IA
16
1A
c
0
0
0
1500
LEG
IA
16
1A
YT320710
YT5O095Q
YT600SQO
YT09247S
YT090270
VTG68270
YT.Q6745Q
YT08T2TO
YTO87430
YT275903
YT270851
YT2509O5
YT0412?0
YT044459
YT239430
YT239600
YT244430
YT244645
YT140680
YT140510
YTO41653
YT206705
YT208693
YT205545
YT155682
YT156537
2A
2B
1A
IB
1A
IB
1A
IB
1A
18
1C
1A
IB
1A
16
1A
16
1A
18
1A
IB
1ft
IB
1A
lb
�DATF
670413
670413
670413
670413
670414
670414
670609
670609
670614
670614
670623
670623
673628
67062S
67062S
670629
670702
670702
670702
670702
670703
670703
670714
670714
67J714
670714
f»70719
670719
670721
670721
670726
670726
670726
670726
670726
673726
670728
670723
670823
6 7032 8
67082S
670828
670920
670920
670925
670925
670926
670926
670927
670927
AGN
0
0
0
w
w
w
0
0
w
0
0
0
w
w
'ri
w
GALS
TYP
1860
P
0
2790
0
2790
0
4650
0
2790
0
3680
0
6510
0
4650
0
5485
0
900
0
6200
0
3000
0
2000
0
30OO
0
3000
0
5000
0
n
D
P
D
B
0
•D
P
R
D
P
0
P
0
0
0
1000
0
w
0
5900
p
6
V
29 50
0
r
D
1000
p
w
0
w
w
w
0
2000
0
3000
0
60CO
0
30OO
'0
6000
0
P
p
a
0
0
L5G
1A
13
1A
IB
1A
ie
1A
IB
1A
IB
IA
18
1A
IB
IA
IB
1A
18
1A
IB
1A
13
1A
18
IA
IB
1A
IB
1A
18
1A
18
1A
IB
IA
IB
1A
1
8
IA
18
IA
18
IA
IB
1A
IB
1A
18
IA
IB
UTM
YT160633
Y716O470
YT193697
YT I 9 3520
YT 11 967 5
YTU65QO
YT080430
YT078617
XU913170
XT915923
XU93012O
X 193,0940
YT0976AQ
YTQ934SO
Yf664444
YTO64619
YTOB3470
YTOS 3.6,62
Y708347G
YT&S36!&,2
YT175690
Yfl 7555,5:
YT072430
¥7073610
YT0724io
YT073619
mi 00300
YU2 72077
YU105313
V^«8li-6
YTQ87469
YT 08 5^3 2
Yfoi8T4ii9
YTi085*32
Y 1036644
YTQ3 746,0
YU1003.1&
Y.t>^56365
YT22/'881
YT227370
¥1227881
YT2273JO
YTQ44653
YTQ4O48Q
YU104303
YU257377
YU103314
YU253331
YU1003O2
WZ 70378
�UNCLASSIFIED
MISSIONS STARTING IN
D'vTE
671006
671006
671006
671006
671006
671006
671013
671013
671013
671013
671013
671013
671013
671015
671015
671016
671016
671020
671020
671021
671021
671022
671022
671022
671022
671029
671029
67102S
671031
671031
671101
671101
671102
671102
671102
671102
671102
671102
671103
67U03
671103
671103
671104
671104
671105
671105
671105
671105
671109
671109
AGN
3
PHUCC LONG
GALS
TYP
1700
C
0
0
0
0
0
3
•n'
W
W
w
w
w
w
B
W
vl
'A
W
cJ
W
W
W
1600
0
0
2b50
0
2000
0
4000
0
3000
0
4000
0
2700
0
4000
0
0
0
4000
0
0
4000
0
4000
0
3600
0
0
0
3000
0
3725
0
3900
0
4000
0
4000
0
W
n
4000
0
3900
0
PROV NO.
LEG
IA
IB
2A
26
3A
36
C
1A
IB
1C
D
D
0
P
0
P
i-
e
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
2A
28
1A
16
1C
D
1A
0
1A
18
C
P
n
D
P
r
p
C'
18
1ft
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IS
1A
IB
1A
IB
UTM
YU360400
YU400320
YU36Q4t»0
YU360348
YU3613&4
YU374340
YU330440
Y4I2A0420
YU2G0350
YT131677
¥ T.I 3 1503
YT141680
YT141517
XO938il2O
27938940
YU1 00290
Y037425S
YU321438
YU204363
X4J933.118
XT933940
X*j*Q53l20
XU95B050
XT948970
XT944957
YQ352392
YU311339
YU230290
XU929120
XT932940
YT475900
YT475720
XT942830
XT942743
VT944770
XT943831
YT442922
YT442744
YT448934
YT448762
YT437919
YT437759
YT498890
YT499720
YT468918
YT468753
YT431917
YT431757
YT517S90
YT51972B
UfJCLA.SSI
21
�M I S S I O N S S T A R T I N G IN
DUE
6I11L1
671111
671112
671112
671113
671113
671113
671113
671114
671114
671115
671115
671115
671115
AGM
M
GALS
4OOO
rf
3850
W
3600
tV
4000
0
4000
671116
•A
671116
671117
671117
671117
671117
671 11H
671116
671121
671121
»S7U22
671122
671123
671123
671123
671123
671123
671123
671123
671123
671127
671127
671129
671129
671130
671130
671130
671130
671130
671130
671130
671130
671201
671201
671201
671201
0
0
0
PHUOC LONG
************
TYP
tEG
IA
oIB
1A
e
18
1A
c
IB
IA
0
18
0
w
0
3750
0
0
4000
0
0
340O
0
4000
0
0
40 OO
0
0
4000
w
a
w
4000
0
V
p
c
p
p
i>
p
0
M
4000
0
2900
p
0
4000
0
0
W
3000
0
Q
3000
0
D
Q
3900
0
2900
0
3000
0
3000
0
2000
0
2000
0
n
n
0
V,
X
IA
18
iA
0
6
IA
18
1A
18
D
0
n
IA
18
14
18
P
D
0
4000
1A
18
18
1A
18
1A
0
4000
IA
IB
IA
IB
r
p
r
c
D
r
IB
1A
IB
1A
IB
1A
IB
1A
16
1A
18
1A
ie
1A
ie
1A
IB
IA
IB
1/s
IB
PROV NO.
UTM
XU948UO
VT940958
YT479900
YJ480730
XT55063.3
XT9 50740
¥U1003i7
YitZ613.88
Y?48093O
YT4SQ760
XT94589I5
XT*13946
VT01 5.640
Y*ai5465
XT938?a6
XT91&617
ri&l 8890
¥T6iS7ia
YT537890
YT547727
Ym.OQ3i'o
¥4^63382
rU331483
YU2153TO
YUlOOi253
YU250361
Y«1OO3A8
YU2603TB
YT492890
YT492T13
XT-9,5Q930
XT9 19950
YT521S9Q
YT521720
YU341478
YO224.3fc4
YT069658
YTOfc9-*95
YT4&2925
YT452738
YT 503890
YT503735
YT63ia90
YT631726
YT211691
YT201527
YU338430
YU213354
YU100315
YU257384
21
�piT*:
671203
671203
671204
671204
671204
671204
671205
671205
671205
671205
671206
671206
671207
671207
.671208
671208
671208
671208
67120B
671206
671209
671209
671210
671210
671210
671210
671210
671210
671210
671210
671211
671211
671211
671211
671212
671212
671212
671213
671213
671213
671213
671214
671214
671214
671214
671214
671214
671215
671215
671215
acN
0
w
0
0
w
n
0
w
w
0
w
Itf
w
Q
0
GALS
3000
0
3000
0
3000
0
2000
0
3000
0
3000
0
500
0
2000
0
TYP
1000
0
0
2000
0
3000
0
3000
0
r
D
r
p.
0
r
r
e
i>
0
D
r
1000
0
2000
0
2000
0
P
f)
0
1950
C
w
0
3000
0
c
,-J
30 ao
0
0
0
0
3000
0
2000
r
0
w
'fl
w
•J
0
o
3000
0
3000
0
5800
0
3000
0
3000
r
E
0
n
c
"- . .. _[
LEG
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
18
1A
18
IA
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
16
1A
IB
1A
IB
1A
18
1A
18
1A
IS
1C
1A
IB
IA
16
IA
IB
1A
le
1A
16
1A
16
IA
UTH
YT471920
YT471750
YT509890
YT50S730
YT484920
YT 48 4 750
YT560390
YT56Q710
XU924120
XT927936
• YT642890
YT632730
YT465920
Yf 46 5 87 5
YU343477
YU2323A8
YT539890
YT539720
YT539890
YT539720
XU942UO
XT942924
YU336431
YU213356
YT 55 2 884
YT558716
Y it 55 2 884
YT558716
YT1006TO
YT10I496
YT53688O
YT536600
YT4.9289to
YT4?2715
XU944120
XT9A59S7
X.T9329&1
YTA36920
YT436745
YT50CS90
YT500704
XT945707
XT924619
YT459 :*23
YT459756
YTQ47645
YTO,40445
YT557390
YT557730
YT053647
�M I S S I O N S STARTING IN
DAT if
671215
671216
671216
671216
671216
671217
671217
4fJN
0
W
0
671217
671217
671217
671218
671218
671218
671218
671218
671216
671218
671216
67121&
6712'18
671213
671218
67121B
671218
671219
671219
671219
671219
671221
671221
671221 .
671'221
671222
671222
671222
671222
671222
671222
671222
671222
671223
671223
671223
671223
671224
671224
671226
671226
671226
671226
0
0
w
6
a,
Q
0
W
n
0
0
n
w
Q
0
vd
GALS
0
3000
0
2700
0
5800
0
0
3000
0
3000
0
3000
0
2950
0
0
0
3000
0
0
0
5800
0
2900
0
3000
0
5000
0
3000
0
2900
0
3000
0
3000
0
3000
0
3000
0
2700
PHUOf LONG
************
TYP
LEG
IB
.
1A
r
18
1A
p
16
1A
p
p
0
IB
n
w
2850
0
300J
0
2850
0
YT621?07
1A
0
XUi9j521,2*)
XT94 39531
18
1A
IB
1C
10
1A
IB
D
D
1C
10
D
1A
D
IB
1A
C
0
r
c
D
D
D
n"
r
0
0
IB
1C
1A
'IB
1A
UTM
YT053465
YT435905
YT435725
Yti2693fli
YU1053O8
XT930753
XT872758
XTB72648
VU26Q3&2
YW0031!
YT621S90
D
Pi
n
\
ie
1A
IB
1A
IB
1A
16
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
16
1A
ic
it
IB
1A
IB
X790072/0
XT9;OQ73,6
XT926736
.XT925720
XT927734
XT*QQ7;i4
XT900759
XT928750
YT15167Q
YT1 51V?5
YJ4>70925
YT472T46
YU336483
Yili2 10362
YT525890
YT550T20
YT121667
YT118503
YT5<*lft90
YT541710
YT619890
YT619715
YU270373
YU107306
YTZ03678
YT2 03500
YT515B90
YT515702
X 18^1609
XT888760
YT433920
YT433747
YU270376
YU115306
VT901607
VT898760
�r>4TS
671226
671226
671227 '
671227
671227
671227
&71223
&71228
671230
671230
671230
671230
671230
671230
671231
671231
671231
671231
671231
671231
630 103
680103
680104
680104
680104
680104
680104
6SQ104
680105
680105
630105
680105
680105
680105
660105
680105
680105
680105
690106
680106
680106
680106
680107
680107
660107
630107
680107
630107
680108
680 10P,
AGN
0
GALS
4000
0
3000
7YP
P
0
C)
0
0
r
5000
0
W
o .
3000
0
•1
3000
Q
0
W
5650
{>
0
0
3000
0
0
tf
0
1000
0
2000
n
-
n
0
0
6000
D
0
0
1900
D
0
0
3000
D
0
0
3000
P
0
0
6000
0
0
W
1000
t>
0
0
3000
D
0
W
30 OO
P
0
p
4000
D
0
W
3.0OO
0
3000
H
5800
B
0
D
0
n
0
0
2600
0
0
•N
5700
r
0
n
3000
D
0
,-l
6000
0
[.
LFG
1A
IB
1A
IB
1A
16
1A
16
1A
IB
1A
18
IA
lb
1A
18
1A
IB
IA
IB
1A
10
IA
IB
IA
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
1ft
IB
1A
16
1A
10
1A
IB
1A
IB
1A
It*
l£
IB
UTM
YT190683
YT191520
¥1219690
YT21952Q
YT147t>74
¥T 148500
YT511R9O
YT5 12724
¥T488»90
YT48373Q
YT87fcfeQO
YT876757
YT642890
YT642723
YT 18 068 0
YT179515
YT180680
YT179515
¥TQ92t»59
YTO9 154)0
YT632890
¥T63 0,700
YT601890
YT601715
YT43T920
¥1437750
YT54089Q
YT5:407flO
¥1562il!99
¥1562732
YT 46 5,92 7
YT465754
YT:6'28(j=90
¥1628730
¥7562899
V-T 56 278.2
¥T4;65927
YT465754
¥15,24.390
YT52472Q
¥1445920
YT445748
YT 54 9890
YT550772
YT608B90
YT60ST2Q
YT478930
YT478755
XTS82590
XT882760
�DATE
680108
680108
680108
680108
680109
680109
680109
680109
68010S
680110
680110
680110
680110
680111
680111
680112
630112
6S0113
680113
680113
680113
630113
680114
680114
680114
630114
680114
680114
680114
680114
680114
680114
680115
680115
680116
630116
680116
680117
680117
680117
680117
680118
68011P
680119
680119
680119
680 11<;
680119
680119
680121
4GN
n
0
w
w
GALS
3000
0
5850
0
2900
0
2900
0
TYP
D
D
0
n
0
u
w
w
w
w
w
W
W
W
W
w
w
w
0
w
n
B
0
3000
0
2700
0
5900
0
3000
0
5700
0
0
2700
0
6000
0
6000
0
0
0
2950
0
0
0
6000
0
6000
0
0
3000
0
3000
0
,2925
0
7850
0
4000
0
4000
0
3000
e
r
p
p
D
D
D
fi
r
D
D
D
r
r
c
0
LEG
1A
IB
1A
18
IA
18
1A
IB
1C
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
1C
1A
18
IA
18
1A
18
2A
2B
1A
IB
2A
2B
1A
IB
1A
IB
1C
1A
IB
IA
IB
1A
16
1A
16
1A
IB
r
1A
IB
£
If:
UTN
YT624890
YT625720
XT920610
XT921760
YT48292O
YT482760
XT915959
XT9529O2
XT915959
Y750ia90
YT5.Q1730
YT425900
YT425741
XT9156UO
XT915750
YJ64489O
Y 16 4 4 720
>!T8 55606
XT855534
XT8.5164-S
YT64GS9O
YT64Q77O
YT5Q5G90
YT505712
XT868546
XT868660
XT873652
XT 873590
XT924743
XT925752
XT958752
XT956743
YT527383
YT527700
YT858530
YT658655
XT8626QO
YT501890
YT501728
YT052657
YT052491
YT52B890
YT528724
XT896600
XT892758
X7462927
XT462742
XT999550
YT058676
YT5b3897
�DATE
680121
&80121
680121
680121
630121
6S0121
680122
680122
680122
630122
630123
680123
680123
680123
680123
68Q123
630125
680125
680125
680125
680127
683127
680128
680128
680129
63Q129
680202
680202
630206
68O206
680208
680203
680313
68031 S .
680320
680320
660321
680321
680321
680321
630323
630323
630323
680323
680327
630327
680402
680402
680403
680403
AGN
vi
0
0
B
0
0
0
0
w
w
0
w
0
VJ
0
w
ft
n
0
w
w
w
w
w
GALS
0
0
8000
0
4000
0
6000
0
4800
0
4000
0
8000
0
3000
0
40OO
0
4000
0
7000
0
8000
0
4000
0
4000
0
3000
o —•
12000
0
6000
0
6000
6
8000
0
3850
0
3750
0
4000
0
5700
0
6000
0
6000
0
TYP
n
p
D
r
0
D
r
0
P
P
0
n
P
p '
P
c
D
P
0
D
D
0
C
L '
LEG
16
1C
1A
16
1A
IP
1A
16
IA
ie
1A
18
1A
16
1A
It)
1A
ie
1A
ifi
1A
16
1A
IE
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
18
1A
18
1A
IB
1A
IB
1A
IB
UTM
YT583Sld
Y15658Q5
¥7106667
YTJ06489
¥11066.67
YT1064&9
Y?566a9.U
¥1566713
XTS9S550
YTQS6676
YT613890
YT615721
YT4559g5
YT 45 5 75.9
YT20869O
¥1208517
Y7 1 1 467:O
YT1145J.5
Yf 114670
YT114S15
XT91 06S7
XTQ70697
YT2237O0
YT323510
YT595d9O
YT595720
XT942674
YT 10567 4
¥T 0*8 06,3,0
XT 90 062?
YT122t>?Q
YT1224SO
YT530S70
¥T"5337Oi?
YT100677
XT930677
YT635890
YTi&36720
YT 55 5 890
YT 555704
X T 9 2 8940
XU925120
XT91O695
XT070693
YT581890
YT581722
YU3 57486
YU240372
VU32&15Q
YU300005
�DATE
680405
680405
680406
680406
680407
630407
6 8040 S
630408
630408
680408
6(30409
680409
680410
680410
630411
680411
680411
680411
680412
680412
680414
680414
680415
6H0415
630415
680415
680416
680416
680417
680417
680416
680418
680418
680418
680419
660419
680420
680420
680420
630420
630420
680420
680421
680421
680421
680421
6SD423
680423
680424
680424
AGN
W
•A
'ft
W
0
w
0
0
w
w
Q
o
0
0
0
0,
0
0
0
0
w
G
w
w
0
GALS
6000
3
3000
0
3000
0
5900
0
3000
0
6000
0
6000
0
5950
0
3000
0
6000
0
2000
0
4000
0
4000
0
3000
0
5500
0
3000
0
5000
0
6000
0
5700
0
6000
0
3000
0
6000
0
300
0.
0
6.0
00
0
3000
0
T¥P
D
D
0
D
D
P
P
0
P
D
P
D
f
D
0
D
0
P
D
n
0
D
c
r
P
LHG
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
15
1A
18
1A
18
1A
13
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
ia
1A
IB
UTM
YW325150
YU258303
YT080631
YT915610
YU370507
YM254393
XT9Q0687
YT070667
YT135676
YT136495
YT10Q668
XT930668
YU331148
YU302010
YU331500
Yl>2«8299
YT494890
YT494707
YU320150
YT455926 .
YT459756
YT630890
YT63072Q
YU321150
Y4U261305
YT62&a7Q
YT629720
YT 1006,2 8
XT920633
YT412840
YT412&65
YT 54 4 890
YT 54 4 720
YT166680
YT166510
YT100652
YT93O657
YU377496
YU260380
YT439922
YT439747
YT620890
YT615730
YT469752
YT540869
YT535720
XT92Q627
YT056627
�MISSIONS STARTING IN
DAT?
680425
680425
680425
680425
680426
680426
680427
680427
680427
640427
680428
680428
630428
630428
680428
660423
680430
68O430
6S0430
680430
680430
6S0430
680430
680430
630501
680501
680501
680501
630502
6S0502
680503
630503
680503
680503
680504
630504
680505
650505
680506
680506
680507
630507
680509
680509
680510
680510
660510
680511
680511
680511
AGN
rt
PHUQC CONG
GALS ************
TYJP
LgG
IA
1000
fi
0
0
5000
8
6000
0
t)
n
0
0
6000
O
W
30OO
W
3000
0
C1
c
c
0
0
6000
0
B
9000
0
W
3000
c
c
p
0
0
3000
0
0
w
w
3000
0
0
2000
D
0
B
5000
P
0
0
5200
0
0
5000
C
c
0
0
50OO
D
0
0
2000
C
0
0
w
w
9000
0
7000
P
0
3000
0
0
r
3000
r
c
0
W
3000
0
0
9000
0
0
rj
3000
D
r
p
0
0
3UOO
r
IB
IA
IB
"
1A
18
1A
18
1A
18
1A
18
1A
16
1A
18
1A
16
1A
18
IA
IB
1A
16
1A
IB
1A
18
IA
IB
IA
IB
1A
IB
1A
IB
1A
IB
1A
ie
1A
IB
1A
IE
IA
IB
1C
1A
IB
1A
UTW
YT<H9890
YT6*9Jf)5
YT649&9Q
Yt649795
YU330148
Yy302Q07
Yf454gi25
¥1455735
YT5-3889O
YT598T2O
Yf42iaaO
¥1421710
YT10Q662
XT935622
Y 732 4! 51
YT2633O7
YT424S95
YT424720
YT44O920
YT 440 740
VT4409ZO
YT440740
YU383495
YM263377
YU325152
YU3030O5
XT960643
YT 10064 3
YT493761
YT320722
YT 100648
XT930646
YT416759
YT32O734
XT940657
XT110657
YT4869O5
YT4U6727
YT100637
YT930637
YT610B90
YT610713
YU331488
YU206367
YT423B79
YT403798
YT320745
YT508890
YT508T10
YT50&890
,.
,
*
�DATE
630511
630513
680513
680514
680514
630515
680515
680516
680516
680517
680517
680517
680517
680517
630517
660517
680517
680517
680517
680520
600520
680520
680520
680522
630522
630523
630523
630523
680523
630525
680525
690525
680525
680530
680530
630531
630531
680531
680531
680601
630601
630601
680601
680603
6B0603
630604
630604
630604
630604
630605
6GN
GALS
TYP
0
0
3000
C
0
0
2750
P
0
w
3000
P
0
w
5000
C
0
w
6000
0
w
2750
C
p
0
0
0
0
2000
D
0
w
1000
C
0
0
6000
w
3000
P
0
P
0
w
30O.O
p
0
w
6000
0
w
30 GO
p
e
0
w
60OO
M
3000
D
0
D
0
w
3000
C
0
w
59OO
P
0
yi
6000
C
0
W
6000
D
0
W
6000
C
0
'it
6000
0
0
W
w
w
2000
. 0
2000
D
P
0
2000
n
LEG
IB
1A
IB
1A
16
1A
IB
IA
IB
IA
18
1A
18
2A
28
1A
IB
IA
IB
1A
IB
1A
IB
1*
18
1A
18
1A
IB
1A
IB
1A
18
1A
IB
1A
16
1A
IB
1A
16
U
IB
1A
IB
IA
16
IA
IB
IA
UTM
YT508710
YU350490
YU230370
YT55489O
YT554768
XT955752
XT955836
YU338482
YU212358
YU3755QI
YU253380
YT04Q7O2
XT918702
XT^727l?
YT63171?
YT481791
¥T 32 074 9
YT481791
YT3.20740
¥U3;65'476
YU25533Q
XU949OAO
XU&4912O
¥L*3,91482
Yt|i267358
Yf4S97?7
Y131O737
Ytioo^as
Xt9:3O633
yTp706.82
XT^OO<6S2
YT637830
yT637*QO
YT467787
YT32O746
YU2553>55
YUO:99283
^T9|64770
XT964885
YU2603.65
YU1203O2
¥026 036 5
YW120.302
Y1U280354
Y,U1.34,265
Y1! 0,2 6 720
XT978720
Y744O'J22
YT320T42
YT147643
�UNCLASSIFIED
M I S S I O N S S T A R T I N G IN
OftTE
680605
680605
680605
630608
680608
680603
680608
680609
680609
680609
680609
680610
630610
630611
630611
680611
680611
680612
680612
680612
680612
630615
630615
680616
680616
630725
680725
680825
680825
680928
680928
681002
6S1002
681003
681003
681005
6S1005
681008
631008
681009
681009
68 1009
681010
631010
631010
681010
681010
631010
681010
681012
4 GN
W
'A
y
W
W
W
w
n
W
W
W
w
w
w
w
0
0
0
w
w
G&LS
0
2700
0
5000
0
60 CO
0
3000
0
3000
0
3000
0
3000
0
0
0
5000
0
5150
0
3000
0
3000
0
3000
0
3000
0
3000
0
3000
0
40OO
0
2000
0
3000
0
2750
0
0
3000
0
PHUOC LONG
TYP
D
D
D
r
0
D
D
P
f
D
D
r
0
e
c
c
0
0
D
D
0
w
n
3000
0
0
0
5700
11
D
*
PRGV N O , = 2 1
tEG
IS
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
16
1A
IB
2A
28
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
ID
1A
IB
1C
1A
IB
1C
It
IB
2A
28
1A
UTM
YTU3692
YU258359
YU103286
YU375504
YU253383
YT488703
YT 32 074 4
XTS31639
XT1Q0638
YT504890
YT504760
YTM2639
YTJ140638
XT952703
YT030703
YT030706
XT 96 6 7 6
0
YU374478
YU260370
YT564890
YT564770
YT 51 4799
YT350T58
XT490771
XT325733
YU130276
XU970276
YT637890
YT63 740O
YU310373
YU158302
YT 15569 7
YT194549
YT178685
YT178530
YT190688
YT190530
YT4967&6
YT333729
XT959728
XT96<=7SO
XT969f)89
XT960727
XT 95 0670
VT915590
XT970890
XT940<;^0
XT950'^70
X1950930
YT1376&7
�Pi IT
631012
681023
681023
681025
681025
631027
681027
681031
661031
631103
631103
631104
631104
681104
631104
681107
631107
681112
631112
681121
631121
681123
631123
681130
68113Q
681201
681201
631201
631201
631203
631203
631205
681205
681205
631205
691206
631206
631206
631208
681208
631208
631203
631209
681209
631209
661209
631211
631211
681212
631212
ASN
w
n
w
n
0
0
0
Cl
w
n
0
0
w
H
1
'ft
W .
W
0
r}
w
w
0
GALS
0
6000
0
2000
0
5000
0
5700
0
3000
0
3000
0
30OO
0
4000
0
20OO
0
30OO
0
3800
0
6000
0
3000
0
0
0
3000
0
500O
0
0
0
&000
0
0
60 CIO
0
3000
0
3000
0
2000
0
4800
0
3000
0
TYP
p.
D
LFG
18
IA
IB
1A
18
gj«
Q936
XT956726
IB
YTI95540
Yy$0l479
YU275350
C
IA
10
YU159300
r
&
1A
D
IA
16
1A
YU39Q306
Yti^ 1336.8
IB
0
n
D
1A
IB
1A
16
1A
18
9
1A
IB
1A
IS
1A
16
2A
28
1A
IB
1A
IB
YT330T27
YU5Q120B
¥03513,08
1A
16
D
8Q50Q769
963:40732
0
E
0
D
2A
i-'
2B
1A
IB
1C
1A
16
IA
0
IB
1ft
V
IB
1A
C
16
1A
D
IB
1A
0
D
ie
YI#04.Q2Q
YUS931T6
YU59Q020
YT199339
YT1357*9
YT139768
YT2OO837
YT438922
YT438756
YT) 8 7 85 3
YT13O790
YT1537B,7
YT2O7&25
YT433871
YT412790
YT3.38747
YU595177
YT6428S7
YT&42737
YT473926
YT473354
YT473V26
YT4733S4
YT493890
YT45376J
YT631752
�D?,TE
681214
681214
681215
681215
681215
631215
681216
681216
681216
681216
681216
681216
681216
631216
681217
681217
681218
681218
631220
681220
681221
691221
681222
681222
681222
681222
681223
681223
6S1226
681226
681226
681226
6S1226
681226
631226
681226
681228
68122S
681228
6S1228
631228
681231
681231
690228
690228
690220
6S.0223
690301
690301
690301
ftGN
W
W
W
n
W
w
W
0
w
w
w
0
w
0
n
Q
0
0
w
vi
*l
'ft
n
W
GALS
3000
0
6000
0
3000
0
5000
0
3000
0
6000
0
3000
0
5800
0
6000
0
5000
0
5000
0
5000
0
6000
0
3900
0
2000
0
5900
0
3000
0
6000
0
6000
0
0
50OO
0
60
00
0
9000
0
9000
.0
8000
0
H
8000
TYP
0
D
r
P
0
D
r
p
p
c
p
f!
0
C
p
0
p
p
p
D
D
P
n
D
n
LEG
1A
18
1A
IP
1A
IB
1A
ie
1A
IB
1A
IB
1A
16
1A
18
1A
16
1A
IB
1A
IB
1A
13
1A
18
1A
IB
1A
19
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
IB
1A
18
14
18
1A
IB
IA
IB
U
UTW
YT494770
YT330732
YT493777
YT330738
VT442920
VT442747
YT486930
YT486770
YT462925
YT462752
YT462925
YT462752
YT486930
YT4C6770
YT633888
YT633750
YT 565889
YT5658IO
YT 505 890
YT503760
YT65C890
YT650740
YU565224
YU419318
YU658H1
¥U5O62Q4
YT496890
YT497758
YU600170
YU6OC020
Y1I613156
YU460240
YU500209
YU3553O3
YT481928
YT481755
YT473927
YT47587Q
YT47576O
XW4321 1
XU372185
YT5O8890
YT508760
YT»60t.50
YTa,60490
YT49278Z
YT330743
YT454924
YT4;547">a
YT144676
�DATE
690301
690303
690303
690304
690304
690304
690304
690305
690305
690305
690305
690305
690305
690306
690306
AGN
690308
690306
690308
690303
690309
690309
690309
690309
6903 1 1
690311
6^0312
690312
690312
690312
0
690313
690313
690313
690313
690313
690314
690314
690315
690315
690315
690316
690316
690317
690317
690317
690317
690318
690313
690319
690319
69031?
0
W
W
0
H
W
W
n
W
n
0
0
0
0
o
0
0
0
0
0
n
GALS
TYP
0
7000
r
0 V .-.—
9000
f
0
8000
13
0
4000
0
0
0
4000
fj
0
0
6000
P
0
8000
P
0
8000
D
0
6000
r
0
0
0
7000
D
0
0
6000
0
7000
D
0
D
5000
0
4000
D
0
0
D
6000
0
D
5000
0
0
P
6000
0
8000
r
0
c
7000
0
5000
0
,0
6000
c
0
7000
D
LEG
IB
1A
18
!A
18
1A
IB
1ft
IB
1C
1A
IB
1C
IA
18
1A
IB
IA
IB
1A
18
2A
26
1A
18
IA
IB
IA
IB
1A
IB
1A
IB
1C
1A
IB
1A
IB
1C
IA
IB
1A
IB
1A
16
1A
IB
1A
IB
1A
UTM
YT144510
XT94Q73Q
XT950893
YT212693
YT212550
YT433921
YT433745
XT960740
XT95O67Q
XT9 10530
XT948726
XT 95 7 780
XT 95 7 9
0 0
Y4J323363
YM173294
YU.6O9170
YU6O9020
YT447922
Y1447747
XT9.67884
XT92S9SQ
XT935977
XU935O30
YU503.212
YU370304
YT205690
YT205550
YU563218
YU4253,LO
YU179291
YU3.40369
YT422374
YT402800
YT330758
YT173.684
YT173532
YT425875
YT405797
YT330755
Yt62683b
YT629752
YT067659
YT067483
YU615163
YU6 15020
YT041645
YT041538
YT638333
YT638738
YT15267S
�UNCLASSIFIED
04T =
690319
690320
690320
690322
&90322
690323
690323
690324
690324
690325
690325
690327
693327
690328
690328
690326
690328
690329
690329
690401
69040 1
690402
690402
&90402
690404
690404
690404
6-90404
690405
690405
690405
690406
690406
690408
690408
690403
690408
690410
690410
690410
690410
690411
690411
690412
6-50412
690412
690412
690412
690412
690412
AGN
0
0
3
0
n
0
0
0
M
0
',J
0
0
0
n
0
0
n
0
n
0
PHUQC LCNC
************
TYP
LEG
GALS
0
IB
fi
5000
1A
0
IB
4000
1A
D
18
0
3000
1A
D
18
0
8000
D
1A
0
IB
1A
C
3000
18
0
3000
1A
0
16
0
1A
7000
D
0
IB
1A
8000
r
0
18
1A
5000
r
18
0
8000
LA
0
0
IB
p
8000
1A
0
IB
0
1C
5000
1A
t>
0
IS
<j
5000
IA
0
IB
5000
1A
0
0
ia
0
1C
D
1A
700
.0
IB
0
IA
4000
0
ia
0
40OO
0
0
IB
IA
2000
D
18
0
2A
0
28
0
5000
D
IA
IB
0
50OO
1A
fj
IB
0
0
1C
1A
C
4OOO
18
0
0
1C
2A
0
P R O V NO. = 21
MISSIONS STARTING IN
u
UTH
YT152512
YT217693
YT217557
YT058&36
YT058496
YTQ74590
YT074428
YT08259Q
YT082430
YT181685
YT181528
YT51ia90
YT5U767
YTQ46651
YTp465t>5
YU362311
YU597174
Y1154-679
YI154514
XT940725
XT92565&
YW5.55186
YM618813.8
YU6l6aOO
¥1626752
Y : tl706a3
YT190530
YT053655
YTO534.98
vmpo ii 8
VT541810
YT542889
YT5437/95
YT16369O
YT163512
YT166d29
YT0236JO
YTQ58673
YTCJ38693
YT0176J9
�DATE
690412
690413
690413
690414
690414
690415
690415
690416
690416
590417
690417
690418
69041S
69041S
690418
690418
690413
690418
690418
690418
690418
690420
690420
690420
690420
690420
690420
690422
690422
690423
690423
690426
690426
690428
690428
690423
690428
690428
690423
690430
6V0430
690430
690502
690502
690502
690502
690505
690505
690537
690507
AGN
0
0
0
0
0
0
n
•
0
0
0
0
0
0
n
0
•T
0
n
GALS
0
5000
0
6000
0
6000
0
2000
0
5000
0
6000
0
0
0
60CO
0
0
0
0
0
2000
0
2000
0
1000
0
6000
0
4000
0
5000
0
2000
0
0
0
0
0
6000
0
0
3000
0
0
0
5000
0
6000
0
TYP
D
D
0
o
0
0
c
p
p
0
p
p
D
D
P
C
D
r
LEG
28
1A
IB
1A
IB
IA
13
IA
IB
1A
18
IA
IB
2A
26
1A
IB
1C
2A
2B
2C
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
2A
2B
2C
1A
IB
1C
IA
IB
1C
ID
1A
1R
1A
16
UTM
YTQ76707
YT223694
YT223557
YU170297
YU330372
YT138675
YTf 13 849 9
YT 180685
YT 18052 6
YT603888
VT603743
YTQ19634
Y7083703
YTO24626
YT071674
YT191846
YT164833
YT126790
YT203831
YT172827
YT155737
YT039642
YT03951O
Y(U61914Q
YU6 19050
YH422436
YU425455
YT2 0 6 0
79
YT207550
Y TO 1765 2
YT017580
YT105590
YT107434
YT189850
YT160836
YT12&7?6
YT201334
Y.T170820
YT142789
YT948700
YT9406TO
YT8'96580
YT617338
YT614370
YT614300
YT622752
YT226694
YT226560
YT132675
YT132500
�MISSIONS STARTING IN
OiTE
690511
690511
690511
690512
690512
690517
690517
690517
690519
690519
690521
690521
690521
690521
690524
690524
690525
690525
690526
690526
690527
690527
690528
690528
690528 •
693528
690529
690529
690601
690601
690603
690603
690604
690604
690606
690606
690606
690606
690607
690607
690614
690614
690615
690615
AsiN
690616
690616
690616
690616
690616
690618
0
n
0
0
0
0
0
0
0
0
0
0
0'
0
o
0
0
0
0
0
D
0
0
GALS
6000
0
0
8000
0
9000
0
0
9000
0
4000
0
3000
0
7000
0
7000
0
5000
0
6750
0
2000
0
2000
0
9000
0
8000
0
6000
0
2700
0
4000
0
0
0
4000
0
4000
0
3000
0
6000
0
4000
vO
0
5000
PHUOC LONG
**;**Jf If f, *i$ ***
TYP
D
0
D
D
D
D
D
D
D
D
0
t1
D
D
D
D
D'
.C
D
D
D
D
D
LEG
1A
IB
1C
1A
IB
1A
IB
1C
1A
IB
1A
IE
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
16
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1C
1A
UTM
XT930694
XT923658
XT885580
YT168681
YT168531
XT942700
XT930640
XT902580
YT096650
YT096478
YT085663
YT085490
YU602170
YU602020
YT121670
YT121500
YT053653
XT948526
YT061656
XT951524
YT233696
YT233576
YT329719
YT248699
YT060552
XT890552
YT244699
YT244580
YT060527
XT650527
YT123673
YT123504
YT089664
YT089558
YT033551
YT060551
XT890551
YT033551
YT103666
YT103468
YU187287
YU352374
YU565208
YU430295
YT188687
YT188530
YT430870
YT410800
YT330750
YT325714
'*
j
�DtTE
690618
690618
690613
690813
690818
690818
690P16
690818
6S0819
690819
690819
69J819
690820
690820
690820
690821
690821
690823
690823
690823
690823
690825
690825
690826
690826
690826
690826
690827
690627
690828
690628
690828
690B28
690328
690828
690830
690330
690830
690905
690905
690921
690921
690922
690922
690923
670923
690?25
690925
690926
690926
AGN
0
n
0
c
0
0
0
0
0
0
o
0
0
Q
0
0
n
U
0
0
0
0
GALS
0
0
5000
0
2000
0
3000
0
4000
0
4000
0
8000
0
0
12000
0
8000
0
7000
0
9000
0
12000
0
liooo
0
4000
0
9000
0
0
8000
0
0
3000
0
0
4000
0
5900
0
5000
0
5900
0
5800
'0
6000
0
TYP
r
D
0
D
r
D
r
D
c
D
D
D
D
D
D
D
n
D
r
D
D
c
LEG
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IE
1C
1A
ie
1A
IB
1A
16
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
UTM
YT282703
YT194590
YT596954
YT601770
YU368363
YU222293
YT510960
YT415816
YU593138
YT519986
YT671906
YT490906
YT608919
YT606800
YT619750
YU579190
YU416297
YT674898
YT460898
YU370360
YU230292
YT674892
YT490892
YU371373
YU232298
YT660918
YT480918
YT507964
YT412820
YU415423
YU341364
YU245316
YT515914
YT513800
YT530767
YT524914
YT524800
YT537769
YU411275
YU411440
YU421366
YU263293
YU421271
YU422450
XT935698
YT112649
YU4272&8
YU427440
YT045579
XT878625
�04T:
690930
690930
691001
691001
691001
691002
691002
691007
691007
691007
691008
691008
691009
691009
691010
691010
691010
691010
691010
691010
691011
691011
691012
691012
691012
691012
691013
691013
691013
691013
691014
691014
691014
691015
691015
691015
691015
691015
691016
69 10 It
691016
691016
691017
691017
691013
691018
691018
691018
691018
691018
AGN
0
0
0
0
0
n
0
0
0
Q
0
0
0
Q
0
Q
W
0
to
0
H
n
W
GALS
7000
0
36
110
74
6000
0
220
8000
0
3000
0
4000
0
220
0
6000
0
6000
0
5000
0
6000
0
6000
0
310
5200
0
0
220
6000
0
110
5600
0
0
0
50
5500
0
TYP
0
s
s
s
D
S
0
D
n
s
D
D
C
1A
IB
D
1A '
IB
1A
IB
1A
1A
IB
2B
1A
1A
IB
1A
1A
18
2A
2B
1A
1A
IB
1C
IA
IB
1A
1A
D
s
D
S
D
S
D
5
D
0
W
Q
0
W
W
4000
0
110
40
5000
0
0
3000
LEG
1A
IB
1A
1A
1A
1A
IB
1A
1A
IB
1A
IB
1A
IB
IA
13
1A
IB
IA
IB
D
S
5
D
P
1A
IB
1C
1*
UTM
YT046584
XT879630
YU236187
YU254168
YU264107
YT101646
XT931693
YT250980
YT044593
XT867635
YU411373
YU242292
YU413273
YU418450
YU267095
YU237083
YT506964
YT431863
YU598U7
YU527936
YT054595
XT88S638
YT664926
YT469924
YU407280
YU407454
YU250150
YT560967
YT518953
YT433677
XU9 90140
YU400285
YU398453
YU260090
YU148311
YU235398
YU245404
YU267426
YU260170
YT526928
YT528800
YT542770
YT635935
YT470935
YU258174
XU930080
YU617158
YU563060
Y7 5 44 99 5
YT074639
•,
*
�MISSIONS STARTING IN
D4TE
691018
691020
691020
691020
691020
691020
691020
691020
691020
691021
691021
691021
691021
691021
691021
691021
691023
691023
691023
691024
691024
691024
691025
691025
691025
691025
651025
691025
691025
691025
691026
691026
691026
691026
691027
691027
691027
691028
691028
691023
691028
691028
691028
691029
69102S
691029
691029
691029
691029
691030
AGN
W
W
W
W
H
,1
W
w
'it
-A
H
H
0
W
0
W
a
w
PHUOC LONG
*****#****##
TYP
GALS
L?G
0
IB
D
6000
1A
0
IB
0
1C
0
ID
e
6000
1A
0
IB
0
1C
0
ID
7QOO
D
1A
0
IB
. 0
1C
p
5000
1A
0
IB
0
1C
0
ID
P
7000
1A
0
IB
0
1C
D
5300
1A
0 .
IB
0
1C
D
9000
1A
0
IB
0
1C
0
ID
D
1A
5300
0
IB
0
1C
0
ID
9000
D
1A
0
IB
D
7000
1A
0
IB
9000
D
1A
b
IB
0
1C
5000
D
1A
0
IB
3000
D
1A
0
IB
D
3SOO
1A
0
IB
F
1A
4400
0
IB
8600
D
IA
0
IB
r
8600
1A
0
18
r.
4200
in
UTM
XT916684
YU154309
YU238395
YU250399
YU271423
YU618157
YU564060
YU563047
YT538996
YU392487
YU359447
YU263366
YT514930
YT516830
YT511797
XT525767
YU478244
YU383296
YU290296
YU628138
YU608054
YU586017
YU270425
YU282440
YU289453
YU383548
YT006610
YT02561S
YT046658
YT053670
YU420484
YU297360
YT665912
YT479905
YT543930
YT542801
YT558769
YU618143
YT548996
YU618143
YT548996
YT513957
YT418816
YT265995
YT288973
YU631130
YT56S995
YT088644
XT924690
YT113675
o
�Q4TE
691030
691030
691030
691031
691031
691031
691031
691031
691031
691031
691101
691101
691101
691101
691101
691102
691102
691102
69 110 2
691102
691102
691104
691104
691104
691104
691104
691105
691105
691105
691105
691106
691106
691106
691107
691107
651107
691107
69110(3
691108
691108
691106
691109
691109
691109
691109
691109
691109
691109
691109
691109
4GN
W
W
8
H
W
0
W
W
W
W
W
W
0
W
W
W
0
W
GALS
0
5000
0
3000
0
2800
0
0
0
0
5000
0
5000
0
0
5-000
0
5000
0
0
0
5000
0
5000
0
0
6000
0
6000
0
6000
0
0
6000
0
5000
0
4000
0
4000
0
6000
0
0
0
0
0
6000
0
0
TYP
p
0
r
D
D
D
D
D
D
0
D
D
D
D
D
D
L£-G
IB
1A
IB
1A
IB
1A
IB
2A
2B
2C
1A
IB
1A
IB
1C
1A
IB
1A
IB
1C
ID
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
D
D
1A
IB
1C
ID
2A
26
1A
IB
1C
UTM
YT113505
YU395286
YU395452
YU428364
YU273293
YT610943
YT560958
YT478947
YT433924
YT460830
YU424473
YU303353
YT 53 492 9
YT534802
YT548773
YT073635
XT915679
YU624146
YU599096
YU593077
YT543967
YU383278
YU388460
YT548940
YT548804
YT562775
YU412370
YU251292
YT063595
XT904642
YT557940
YT558815
YT570781
YT630937
YT462S37
YT075629
XT916673
YT438843
YT332771
YU378300
YT378470
YU273421
YU290438
YU296450
YU340497
YU353503
YU391542
YU628139
YU604100
YU60408S
.
'
�UNCLASSIFIED
MISSIONS STORTING IN
PAT1!
691109
691110
691110
691110
691110
691110
691111
691111
691111
691111
691111
691111
691111
691111
691111
691112
691112
691112
691112
691112
691112
691113
691113
691113
691113
691113
691113
691114
691114
691114
691115
691115
691116
691116
691116
691116
691116
691116
691117
691117
691118
691118
691118
691113
691116
691119
691119
691119
691119
691120
AGN
B
W
0
n
0
0
0
0
0
0
0
0
0
0
n
n
B
0
0
PHUCC LONG'
************
GALS
TYP
LEG
ID
0
1A
1500
C
IB
0
0
1C
5300
C
1A
IB
0
14
6000
r
0
IB
0
1C
10
0
6000
1A
0
18
0
1C
0
0
ID
0
IE
5600
D
1A
0
13
1A
3000
D
18
0
0
1C
0
ID
n
1A
4600
0
IB
0
1C
10
0
1A
5000
D
0
18
D
1A
2800
0
18
0
1C
D
1A
3300
0
IB
220
S
1A
0
IB
110
1A
S
18
8
1A
6000
D
0
IB
D
1A
6000
0
IB
P
2700
1A
0
IB
3000
D
1A
0
IB
0
1C
r
1800
1A
0
IB
1800
D
1A
0
Ib
3600
D
1A
PRGV NO. = 21
UTM
YT562997
YT500970
YT480890
YT570730
YU399480
YU271357
Y0160307
YU239338
YU253395
YU2B7433
YT616933
YT595939
YT580943
YT463938
YT439926
YT490838
YT333766
YU643127
YU598020
YU594020
YU645126
YU290438
YU339489
YU3475Q3
YU409568
YT507764
YT335724
YT552950
YT552314
YT565780
YU373301
YU373470
YU240070
YU250075
YT245971
YT246979
YU164305
YU290430
YT492834
YT333760
YU415295
YU415448
YT107673
YT108618
YT109505
YT506768YT335728
YT506768
YT335728
YT075629
�UNCLASSIFIED
MISSIONS STARTING IN
DATE?
691120
691120
691120
691121
691121
691121
691122
691122
691122
691123
691123
691123
691123
691124
691124
691124
691124
691124
691124
691125
691125
691126
691126
691126
691126
691126
691127
691127
691127
691127
691128
691126
691128
691128
691129
691125
69112S
691129
691130
691130
691130
691130
691202
691202
691202
691202
691202
691203
691203
691203
AGN
0
0
0
0
n
w
0
0
w
0
0
0
3
0
0
0
0
0
0
0
0
Q
PHUOC LONG
*************
TYP
LEG
GALS
IB
0
1A
3800
r
IB
0
1A
c
4000 IB
0
1C
0
r
1A
5000
IB
0
1C
0
1A
4000
c
IB
0
1A
3400
C
IB
0
1A
110
s
IS
0
1A
4000
D
0
IB
1A
2600
D
IB
0
s
1A
110
IB
0
1A
D
4000
IB
0
D
1A
3000
IB
0
1C
0
D
1A
3000
0
IB
P
1A
3000
IB
0
D
1A
3700
18
0
1A
4000
D
0
IB
P
4000
1A
IB
6
2A
0
0
2B
1A
4000
D
IB
0
1A
4000
D
IB
0
16
4000
0
IB
0
1C
0
1A
4000
D
IB
,0
1A
35
S
IB
0
1A
S
70
P R Q V NO. =
UTM
XT916668
YT494829
YT333755
YT067612
XT990622
XT909651
YT573946
YT573870
YT570781
YU383300
YU3S3470
YT509929
YT512764
YU235065
YU235070
YU296427
YU413547
YT072619
XT916667
YU237065
YU237070
YU176302
YU297424
YT066607
YT024619
XT910652
YT505928
YT505762
YT064601
XT904649
YU548203
YU405293
YU641910
YU642740
YT256706
YT256610
YT253608
YT253693
YU181299
YU302419
YT503773
YT333733
YU568205
YU494255
YU428300
YT503777
YT334738
YT360972
YT348971
YT381926
21
�UNCLASSIFIED
MISSIONS STARTING IN
nsT'T
691203
691203
691203
691203
691204
691204
691204
691204
691204
691204
691205
691205
691206
691206
691206
691206
691206
691207
691207
691208
691208
691209
691209
691210
691210
691211
691211
691212
691212
691213
691213
691213
691213
691213
691214
691214
691214
691215
691215
691215
691215
691216
691216
691216
691216
691216
691217
691217
691217
691217
AGN
0
0
0
W
0
0
0
0
r|
0
0
0
0
0
0
n
0
0
0
. 0
W
TYP
GALS
D
4000
0
0
0
s
110
0
0
D
4000
0
0
3600
D
0
3000
D
0
0
4000
D
0 "- • -. -:.
P
4000
0
r
4000
0
p
4000
0
2300
D
0
3900
D
0
3000
D
0
C
4300
0
0
P
3000
0
3000
D
6
0
5000
0
2400
0
5000
0
3000
0
0
5000
0
3000
0
PROV NO,
PHUCC LONG
P
LEG
1A
IB
2A
2B
1A
IB
1C
1A
IB
1C
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
IB
1A
IB
1C
1A
IB
n
1A
p
IB
1A
lb
P
1A
0
IB
1C
1*
IP
IA
r.
1H
UTM
YT193692
YT183584
YT193537
YT197733
YU260170
YU260180
YU270170
YU563228
YU430307
YU428358
YU427397
YU408567
YT592947
YT460944
YT433929
YT088590
YT088419
YT497823
YT333746
YU307344
YU426464
YU290432
YU367507
YT071614
XT917655
YT650877
YT466882
YT501785
YT333745
YU564222
YU440297
YU433322
YT203694
YT203550
YT522913
YT5248QO
YT542770
YT-495826
YT334751
YU430361
YU282292
YU298424
YU414542
YT592951
YT460945
YT436932
YT501810
YT333730
YU307337
YU428457
21
�MISSION'S STARTING IN
D4TE
691219
691219
691220
691220
691221
691221
691221
691221
691222
691222
691223
691223
691224
691224
691226
691226
691227
691227
691229
691229
691229
691229
691229
691229
691229
691230
691230
691230
691230
691231
691231
700102
700102
700102
700102
700102
700103
700103
700103
700103
700105
700105
700107
700107
700107
700107
700108
700108
700110
700110
AGN
r.
,0
0
G
0
0
rj
0
0
G
0
0
0
0
0
G
C
0
0
n
n
0
G
PHUCC LONG
************
TYP
LEG
GALS
P
4000
1A
0
IB
r
5000
1*
0
IB
D
4000
1A
0
18
P
It
3000
0
IB
5000
D
1A
0
IB
4000
D
1A
0
18
3000
'D
1A
0
18
P
1A
3000
0
IB
4000
C
1A
0
IB
D
4500
1A
0
IB
3000
n
1A
0
IB
0
2A
0
26
0
2C
D
5000
1A
0
IB
1900
D
1A
0
IB
3000
D
1A
0
IB
4000
P
1A
0
IB
3000
D
IA
0
IB
0
1C
D
4000
1A
0
IB
D
1A
3003
0
IB
5000
D
1A
0
IB
D
5000
1A
IB
0
1A
3000
D
0
13
r,
3000
1A
0
IB
3800
r
14
IB
0
UTM
YU265362
YU392488
YT499794
YT333754
YT498819
YT333741
YU301421
YU415537
YT 502782
YT333742
YT084614
XT919658
YU305332
YU427455
YT500739
YT333749
YT501814
YT333738
YT359925
YT388797
YT240670
YT238578
YT233580
YT236624
YT237670
YT633937
YT633753
YT212696
YT212555
YT502778
YT334738
YU422397
YU403567
YT640920
YT520830
YT510800
YT656874
YT466877
YU293428
YU411550
YT376954
YT409793
YU283362
YU409487
YT654870
YT465874
YT673903
YT500903
YT38395S
YT418797
�PiTE
70JU2
700112
700112
700112
700113
700113
700113
700113
700114
700114
700114
700114
700114
700117
700117
700117
700117
700117
700118
700118
700116
700118
700118
700120
700120
700120
700120
700121
700121
700122
700122
700123
700123
700124
700124
700124
700124
700124
700127
700127
700127
700127
700127
700127
700127
700127
700131
700131
700131
700131
AGN
8
G&LS
4000
TYP
n
0
0
0
W -
4000
D
0
0
0
W
2000
D
0
0
0
0
W
3000
D
0
W
2700
D
0
0
W
4000
D
0
0
W
3000
D
0
W
3900
W
3000
LEG
1A
IB
1C
1C
1A
IB
2A
2B
1A
18
2A
2B
2C
1A
IB
1A
IB
1C
1A
18
1C
1A
IB
D
Ik
IB
D
1A
IB
0
0
W
2000
D
0
W
2000
D
0
ri
5000
D
0
W
4600
0
0
W
8
3000
0
0
700
0
0
0
0
0
0
D
n
0
0
30.00
0
0
0
D
.
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1C
1A
IB
1C
10
IE
IF
1G
1H
1A
IB
1C
ID
UTM
YT 184668
YT193640
YT190569
YT195540
YT213646
YT213556
YT217557
YT2 17646
YT492925
YT474895
YT475870
YT508850
YT507810
YU302418
YU415533
YT643912
YT643T96
YT634748
YT569943
YT483925
YT446848
YT084600
YT084430
YT658866
YT467871
YU264294
YU425372
YU561238
YU476289
YU293293
YU432358
YT618850
YT449330
YU247300
YU399373
YT570940
YT492925
YT451845
YT519S51
YT515944
YT500930
YT494930
YT487367
YT493863
YT50682?
YT50S820
YT633938
YT633929
YT636919
YT639767
,.
,
�MISSIONS STARTING IN
OATt
700131
700131
700201
700201
700201
700201
700201
700203
700203
700203
700204
700204
700205
700205
700207
700207
700207
700207
700207
700207
700207
700209
700209
700210
700210
700210
700212
700212
700212
700213
700213
700214
700214
700216
700216
700219
70021s?
700219
700219
700220
700220
700220
700223
7J0223
700223
700223
700223
700223
700308
700308
AGN
0
W
W
0
0
0
0
0
n
r>
0
0
c
0
0
0
0
a
r;
GALS
3000
0
3000
0
1900
0
0
3000
0
0
3000
0
3000
0
3000
0
0
0
0
0
0
2000
0
2200
0
0
100
0
0
3800
0
80
0
3000
0
3000
0
3000
0
2300
0
0
2000
0
2000
0
0
0
3000
0
PHUOC LCWG
**4t* *******
TYP
LEG
P
1A
18
1A
D
IB
D
1A
113
D
D
D
D
D
D
s
D
s
D
D
D
1C
1A
IB
1C
1A
IB
1A
IB
1A
IB
1C
10
IE
IF
1G
1A
IB
1A
IB
1C
1A
2A
3A
1A
IB
1A
2A
1A
IB
14
IB
1A
IB
D
P
r
D
1A
IB
1C
IA
IB
1A
IB
1C
ID
1A
IB
UTM
YU264292
YU426371
YU256294
YU408369
YT533930
YT533800
YT546771
YT647912
YT647794
YT635742
YT519956
YT522785
YT461940
YT459770
XT497969
XT494926
XT476896
XT480377
XT522350
XT527830
XT528799
YT487842
YT332773
YU590127
YU590022
YT546996
YU255120
YU194175
YT243973
YU431365
YU279294
YT132993
YT073945
YT588958
YT589776
YT323923
YT360756
YU393382
YU242303
YU578111
YU573024
YU527007
YU434342
YU290292
YU582U3
YU582062
YU566023
YT543997
YU379292
YU414450
,
.
�UNCLASSIFIED
MISSIONS STARTING IN
DATE
700308 •
700308
700308
700308
700308
700308
700308
700308
700303
700308
700310
700310
700313
700313
700313
700316
700316
700316
700316
700317
700313
700318
700319
730319
700319
70031?
700320
700320
700323
700324
700324
700325
700325
700325
700329
700329
700329
700329
700329
700331
700331
700402
700402
700403
700403
700403
700404
700404
700404
700404
AGN
a
0
0
0
0
o•
0
0
0
0
0
0
0
T
0
T
0
n
0
o
0
PROV NO. = 21
PHUOC LONG
GALS
TYP
2700
D
0
0
0
0
0
0
0
0
0
2700
0
0
5
100
D
3000
0
D
1000
0
D
1300
0
110
S
D
2900
0
D
330
0
0
0
0
2000
0
80
's
0
3000
0
. .0
2 700
0
0
3
110
3000
P
0
0
0
S
100
0
r
1800
0
110
s
50
s
£
60
..
30.00 ' -. _., D
0 *'
0
0
LEG
1A
IB
1C
ID
IE
IF
1G
1H
11
1J
1A
IB
1A
1A
18
1A
IB
1A
IB
1A
1A
IB
1A
IB
2A
2B
1A
IB
1A
1A
IB
1A
IB
1C
1A
1A
IB
2.A
26
1A
2A
1A
IB
1A
IA
1A
1A
IB
2A
2B
UTM
YU581122
YU583039
YU590073
YU582055
YU588038
YU582021
YU562015
YU559007
YU541003
YU523000
YU376292
YU411459
YU002147
YU430370
YU271293
YU432361
YU286294
YU432361
YU286294
YT024986
YT650392
YT497820
YT329720
YT231698
YT328717
YT232696
YU375292
YU403435
YU247360
YT215651
YT053614
YU383292
YU397362
YU415458
YT254984
YT242670
YT242532
YT244577
YT244670
YT165313
YT130782
YT348937
YT3S3776
YU324323
YU413345
YU376358
YT246582
YT243702
YT260700
YT260656
�oiTE-:
AGN
700407
700407
700409
700411
700411
700411
700411
700412
700412
700413
700413
700413
700413
700415
700415
700416
700416
700416
700416
700417
70041 ?
700418
700413
700418
700418
700419
700419
700422
70Q422
700422
700422
700423
700423
700424
700424
700426
700426
700426
700427
700427
700428
700423
700430
700430
700430
700430
700501
700501
700502
700502
0
GALS
3000
0
110
0
110
0
110
0
TYP
D
0
0
0
n
a
3000
S
F
F
D
D
D
13
1*
F
2000
0
D
0
0
rt
w
2900
0
0
0
0
6500
D
0
2500
D
0
0
0
iV
3000
0
0
VJ
2900
0
0
0
W
0
3000
D
0
fl
3000
p
0
W
3000
D
0
0
W
w
w
3000
0
2900
D'
C1
0
3000
. D
0
0
0
w
w
3.0
00
0
3000
0
l.A
IB
1A
IB
1A
13
1A
IB
1A
IB
2A
28
1A
IB
1A
IB
2 A.
2B
1A
IB
1A
18
1C
10
1A
IB
1A
18
1A
IB
1C
1A
IB
1A
IB
1A
IB
2A
26
1A
0
110
0
4400
1A
IB
0
0
LEG
1A
IB
1A
1A
IB
IB
UTM
YT231698
YT069663
YU243356
YT260926
YT274928
YT130783
YT165320
YT155685
YT155515
YT265998
YT286970
YT331925
YT366757
YU458293
YU290293
YT189743
YT091743
YT091745
YT189745
YT 15 251 2
YT152683
YT193692
YT193650
YT197626
YT197547
YU382218
YU552219
YU385252
YU403350
YU403368
YU415423
YT209695
YT207545
YT378957
YT413974
YU371293
YU395400
YU412460
YT225562
YT225698
YT333927
YT368757
YT228699
YT228575
YT232530
YT232645
YT328926
YT362753
YT404974
YT439607
.
.
�UNCLASSIFIED
MISSIONS S T A R T I N G IN
1
OAT ;
700503
700503
700503
700503
700504
700504
700505
700505
700506
700506
700506
700506
700506
700507
700507
700507
700500
700508
700509
700509
700509
700509
AGN
W
W
W
W
W
fi
W
W
4
GALS
3000
0
0
0
2300
0
3000
0
3000
0
0
3000
0
3000
0
0
3000
0
2500
0
3000
0
PHUCf LCNG
PROV
TYP
D
LEG
1A
IB
1C
ID
D •
1A
D
0
D
0
D
D
D
IB
1A
18
1A
IB
1C
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
UTM
YT218646
YT218656
YT219556
YT219646
YT346938
YT382768
YT318706
YT153670
YU243306
YU336300
YU394378
YT162682
YT162513
YT374954
YT383900
YT412775
YT130504
YT130676
YT358947
YT344787
YU406371
YU256298
UNCL4SSIFI--D
UNCLASSIFI50
NO.
21
�NREC= 16568
NREC= 16563
NPPOV=
NPRQV=
695
695
NZREC=
NZREC=
877
877
UNCLASSIFIED
UNCLASSIFIED
�DATF
651029
651029
651029
651029
651031
651031
651103
651103
651104
651104
651104
651105
651105
651120
651120
651122
651122
651124
651124
660909
660909
660909
660909
661102
661102
661102
661102
661113
661113
661115
661115
661115 •
661115
661115
661115
661115
661115
661117
661117
661117661117
661117
661117
1
661H ;
661119
661122
661122
661122
661122
66112?
SGN
0
0
0
0
0
0
0
0
0
0
0
0
w
w
0
0
w
w
•1
8INH LONG
************
TYP
LEG
GALS
1A
1900
C
IB
0
1C
0
ID
0
1A
3000
C
IB
0
1A
1900
C
0
IB
1A
C
150
1A
C
2000
0
IB
1350
1A
C
1A
1750
C
1A
3000
C
IB
0
n
IA
3000
IB
0
1A
0
2000
IB
0
D
1A
4000
IB
0
2A
0
2B
0
2700
D
1A
IB
0
2A
0
28
0
1800
D
1A
0
IB
1A
3600
D
0
IB
2A
0
0
2B
1A
2700
D
IB
0
0
2A
0
26
1A
1800
D
0
IB
2A
0
0
2B
0
3£
0
36
1800
D
1A
0
IP
0
3600
1A
0
IB
2A
0
0
2R
r>
2700
1ft
PROV NO. = 22
MISSIONS STARTING IN
UTM
XT880535
XT380600
XT850660
XT850530
XT840540
XT865600
XT870540
XT920690
XT560700
XT870545
XT870600
XU870050
XT835585
XU865075
XU925075
XT870610
XT930720
XT780620
XT850520
XT767660
XT767750
XT762750
XT763693
XT773660
XT773T50
XT753750
XT758660
XT830680
XT930730
XT749660
XT749750
XT7 77660
XT777750
XT755660
XT753750
XT774750
XT777673
XU740050
XT720990
XT750990
XU750050
XT710990
XT760990
XT757990
XU757050
XU830000
XU830040
XU920000
XU92U010
XT780660
�DATE
661123
661203
661203
661203
661203
670110
670110
670111
670111
670111
670111
670113
670113
670114
670114
670120
670120
670121
670121
670126
670126
670126
670126
670126
670126
670126
670127
670127
670127
670127
670127
670127
670127
670129
670129
670129
670129
670131
670131
670212
673212
670212
670212
670212
670212
670213
67J213
670214
670214
670214
AGN
0
0
W
w
w
w
W
W
0
0
a
0
w
0
w
H
w
vi
a
0
0
0
GALS
0
2700
0
2700
0
2700
0
2700
. 0
2700
0
2700
0
2700
0
1800
0
2700
0
2700
0
0
2700
0
2700
0
2700
0
0
0
2700
0
0
1800
0
2200
0
2600
0
1800
0
900
0
2700
0
2700
. 0
2700
0
0
TYP
n
n
D
.
D
p
r
c
D
n
D
n
r
0
D
D
D
C
n
n
D
D
D
LEG
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
2A
28
1A
18
1C
1A
IB
1A
IB
1A
IB
1A
13
1A
IB
1A
IB
1A
IS
1A
IB
2A
UTM
XT780750
XT930790
XT825645
XU920045
XU830045
XT76C995
XT697995
XU680172
XU670000
XT650910
XU650110
XU820176
XU870134
XU830030
XU920030
XU820180
XU625180
XT650910
XU647098
XT930720
XT890660
XT830710
XT742660
XT742750
XT630930
XT630060
XT735660
XT785750
XT780750
XT780660
XT628542
XT697657
XT697531
XU880140
XU830180
XT 700600
XT620550
XT640930
XU655160
XT627960
XU627056
XT627960
XU627056
XU830036
XU920036
XT645928
XU645095
XU888147
XU855170
XU877135
.
'
�D4TE
670214
670215
670215
670215
670215
670215
670217
670217
670217
670217
670218
670218
670218
670216
670223
670228
670228
670302
670302
670303
670303
670303
670307
670307
670307
670311
670311
670315
670315
670315
670315
670326
670326
670326
670331
670331
670331
670331
630102
680102
680102
680102
630103
630103
630106
680106
680106
6B01U6
630109
680109
AGN
0
0
0
0
0
0
0
0
0
0
0
0
0
0
w
H
H
-,-i
GALS
0
2700
0
1800
0
0
2700
0
2100
0
2700
0
0
0
2700
0
0
2700
0
2700
0
0
2700
0
0
1300
0
1800
0
0
0
2800
0
0
2790
0
0
0
6900
0
6000
0
5000
0
5700
0
, 0
0
4850
0
TYP
D
D
D
D
D
n
r
D
D
D
0
p
0
r
D
p
LEG
26
IA
IB
1A
IB
1C
1A
18
1A
IB
1A
IB
2A
2B
1A
IB
1C
1A
IB
1A
IB
1C
1A
18
1C
1A
18
IA
18
2A
28
1A
IB
1C
1A
IB
1C
ID
1A
IB
1A
IB
1A
IB
D
r
1A
18
2A
2B
1A
IB
UTM
XU833170
XU915022
XU83C018
XT640950
XU640090
XU661175
XT625964
XU625030
XT640940
XU640080
XU658180
XU658100
XU653180
XU653110
XT930790
XT830720
XT830650
XU830010
XU920010
XT6155&0
XT700652 '
XT700580
XT930760
XT833704
XT835652
XU920030
XU830030
XT630540
XT700580
XT700590
XT620550
XT930730
XT840720
XT840650
XT930760
XT330700
XT900730
XT930750
XT886590
XT883760
XT905&00
XT909760
XT890600
XT892756
XT052530
XT852647
XT848643
XT648605
XT832530
XT83263J
,
�UNCLASSIFIED
MISSIONS
01TF
630109
680123
680123
680125
680125
680126
630126
680202
680202
680203
630203
680320
680320
680323
680323
680323
680323
630401
680401
680403
680403
680405
680405
68040S
680409
680414
680414
680415
680415
630416
630418
680419
680419
680419
680419
680423
680423
680425
630425
680504
680504
680507
630507
630509
680509
680510
680510
680510
630510
680511
STARTING
AGN
W
W
0
•4
W
W
W
W
W
W
H
W
W
W
W
W
W
W
W
tl
W
W
W
U4
BINH LONG
G4LS
0
3000
0
8000
0 '
4000
0
5800
0
6000
0
5800
0
5000
0
0
0
3000
0
3000
0
3000
0
550
0
5500
0
3000
0
5880
0
2900
0
6000
0
3000
0
3000
0
2925
0
3000
0
6000
0
5800
0
0
0
2<?30
TYP
D
C
c
D
C
D
D
D
D
D
D
D
0
D
D
D
C
D
C
D
C
C
0
PROV
LEG
1C
1A
IB
1A
IB
1A
18
1A
IB
1A
18
1A
13
1A
IB
1C
10
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
13
1A
18
1A
IB
1A
IB
1A
IB
1A
13
1A
IB
2A
2B
1A
•
UTH
XT880673
XU635070
XU637186
XU658023
XU650185
XT905610
XT901760
XT913945
XU910116
XU640020
XU642180
XT489612
XT603747
XT570758
XT622764
X.T635794
XT623880
XU9 06020
XU904110
XT488619
XT600750
XT560753
XT621877
XU650010
XU647072
XT917947
XU917093
XT600749
XT634896
XT610960
XU645115
XT560746
XT630859
XT607967
XU645120
XT498656
XT559669
XT632893
XT605752
XT599755
XT568709
X.U643020
XU645185
XT922950
XU92212J
XT623934
XU648014
XU644016
XT620940
XU899051
NO.
22
�UNCLASSIFIED
MISSIONS STARTING IN
D1TF
6S0511
680512
680512
680518
630518
680518
680518
680519
68051"?
680519
680519
680522
680522
6S0523
680523
680523
680523
680525
630525
680526
680526
680527
680527
680531
680531
680603
680603
630612
680612
680614
630614
630302
680802
680802
680802
681230
681230
681230
681230
681230
631230
631230
681230
690112
690112
690112
690113
690113
690113
690114
ASM
W
W
w
U
w
w
w
ft
w
w
w
w
0
W
w
0
'j
GALS
0
4500
0
6000
0
0
0
2500
0
0
0
5400
0
3000
0
0
0
3000
0
3000
0
3000
0
3000
0
3000
0
3000
0
3000
0
600
0
0
Q
4000
0
0
0
5000
0
0
0
8500
0
0
8700
BINH LONG
TYP
D
D
D
n
D
D
D
D
D
0
C
D
k
D
0
D
1?
0
0
0
7000
n
PRQV NO.
LEG
IB
IA
IB
1A
16
2A
2B
1A
IB
2A
2B
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
18
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
2A
2B
1.4
16
1C
1A
13
1C
1A
UTM
XU898107
XT838633
XT872586
XT842640
XT842530
XT862537
XT862600
XT846605
XT846525
XT895605
XT895670
XT413953
XU635020
XT645748
XT616873
XT630891
XT630789
XT904642
XT905703
XT899611
XT898750
XT600752
XT629890
XT494647
XT559663
XT604970
XU630185
XT622730
XT609864
XT625790
XT613870
XS726696
XS674696
XS701667
XS711681
XT598392
XT602975
XU624053
XU628050
XT496643
XT557653
XT494634
XT558654
XT630753
XT648800
XT636870
XU650020
VU660120
XU650130
XU624050
22
�UNCLASSIFIED
MISSIONS
STARTING
DATE
690114
690114
690114
690114
690114
6°011f690116
690116
AGN
690121
690121
690121
W
9
0
IN
BINH LONG
PRCV NO. =
GALS
0
0
9000
0
0
5700
0
0
************
9000
0
0
D
TYP
0
D
LEG
IB
1C
1A
IB
1C
1A
IB
1C
UTM
XU650120
XU624186
XT914937
XU912017
XU385110
XT370750
XT870670
XT830630
1A
18
1C
XT836530
XT836610
XT910678
,
'
f:
UMCLiSS!FI=D
U.NCL/..SSIFI-;!)
22
�EC= 17879
N * E C = 17879
NPCQV=
NPROV=
103
103
NZREC=
NIREC=
156
158
UNCIASS!FI=D
S*:-! PI'";)
�MISSIONS ST£RT ING IN
DfT?
651109
651109
AGN
0
651111
0
651111
651111
651111
651118
651118
651118
651118
651118
651118
651122
651122
651224
651224
660P21
660821
660821
660821
660821
660821
660821
660821
660821
660821
660825
660825
660825
660825
660825
660825
660825
660825
660825
660825
660904
660904
660904
660904
660^04
660904
660910
660^ 10
560910
660910
660910
660910
660910
660910
0
0
0
0
W
f>
W
W
vJ
GALS
3000
0
3000
0
0
0
3000
0
2000
0
0
0
3000
0
3000
0
4000
0
0
0
0
0
4000
0
0
0
3600
0
0
0
3000
0
0
0
0
0
4000
0
0
0
0
0
W
3300
0
0
0
0
0
0
0
BINH DUONG
************
TYP
~ """Dc
c
r
D
C
D
n
D
D
D
r
LrG
1A
IB
1A
IB
1C
10
1A
IB
1A
IP
1C
ID
1A
IB
1A
18
1A
13
2A
2B
3A
3B
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
2A
2B
3A
3B
1A
IB
2A
2B
3A
3B
U
IB
2A
2B
2C
2D
2E
2F
UTM
XT908006
XT912137
YT030563
YT050665
XT910620
XT910540
YT050665
YT002563
YT000395
YT080430
YT070340
YT130310
YT000395
YT090420
XT905065
XT904133
XT715254
XT675280
XT655325
XT620330
XT580340
XT535380
XT680340
XT550388
XT602332
XT532381
XT70841t)
XT730340
XT726316
XT715255
XT603348
XT603393
XT670390
XT730340
XR726315
XT675305
XT708408
XT670390
XT656387
XT617330
XT603380
XT540380
XT358724
XT70834B
XT6S0340
X.T&58324
XT6P0332
XT615365
XT620385
XT657388
',.
,
�04 Tc
660930
660V30
660930
660930 661004
661004
661004
661004
661021
661021
661023
661023
661025
661025
661025
661025
661028
661028
661031
661031
661107
661107
661116
661116
661116
661116
661124
661124
661125
661125
661201
661201
661201
661201
661201
661201
661202
661202
661203
661203
661203
661205
661205
661205
661205
661206
661206
661206
661207
661207
AGN
W
W
W
W
W
W
0
0
W
D
0
0
G
3
0
3
Q
•J
W
W
W
.
GALS
27CO
0
0
0
3600
0
0
0
3600
0
1800
0
1800
0
1600
0
3600
0
2700
0
2700
0
1800
0
SOO
0
3600
0
2700
. 0
1800
0
1800
0
Q
0
1800
0
1SOO
0
0
2700
0
2700
0
2700'
. 0
0
1800
0
TYP
D
D
C
D
C
0
C
C
0
C
D
C
D
D
D
C
D
.
n
D
D
D
LEG
1A
IB
2A
2E
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
14
IB
2A
26
1A
IB
1A
IB
1C
1A
18
1A
IB
1A
IB
1C
1A
IB
UTM
XT76Q4S6
XT805488
XT763505
XT805515
XT770660
XT770750
XT763750
XT763660
XT670280
XT580427
XT026270
XT026479
XT544354
XT481583
XT805505
XT763517
XT765215
XT606370
XT766217
XT630333
YT000270
YT013535
XT650390
XT510390
XT650390
XT510390
XT490440
XT670290
XT514366
XT695366
XT550640
XT440495
X.T770220
XT740304
XT610225
XT615285
XT670278
XT488440
XT550640
XT560610
XT475500
XT550640
XT460500
XT550640
XT410630
XT470500
XT460560
XT540680
XT4R0500
XT480670
\
,
'
�HAT1"
661209
661209
661209
AGM
ii
661210
661210
661230
661230
670104
670104
670106
670106
670107
670107
670109
670109
670110
670110
670111
670111
670112
670112
670112
670112
670128
670128
670129
67G129
670201
670201
670201
670204
670204
670205
670205
670214
670214
67U214
670217
670217
670213
670218
670213
670218
670219
67U219
670219
670219
670224
670224
670224
W
W
W
W
W
W
W
W
• rt
~)
0
0
f)
W
0
0
0
0
0
0
0
0
GtLS
2700
0
0
3600
0
3600
0
2700
0
3600
0
2700
0
1800
0
2700
0
2700
0
1200
0
2700
0
2700
0
2700
0
1800
1800
0
2700
0
2700
0
2700
6
0
1800
0
2700
0
2100
0
2700
0
0
0
2300
0
0
TYP
C
n
n
D
n
D
D
D
D
0
D
LEG
IA
13
1C
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
D
n
1A
IB
1A
IB
1A
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
IB
1A
16
1A
IB
1A
[•
1C
ID
1&
D
D
D
D
D
D
D
0
n
IB
IB
2A
UTM
XT450500
XT5U0630
*T548642
XT460500
XT510630
XT460500
XT510630
XT884470
XT833524
XT470530
XT505630
XT500630
XT450500
XT530600
XT480510
XT446510
XT479578
XT510590
XT530620
XT523576
XT547640
XT902464
XT750536
XT810450
XT810530
XT830450
XT830530
XT880250
XT856460
XT856520
XT767233
XT703305
XT923520
XT910617
XT449506
XT557635
XT500626
XT 546 36 9
XT664369
YT040650
YT043450
XT719336
XT704403
XT906436
X*909436
VT904443
XT9C7443
NTS 10640
XT550640
YT480570
�PATF
670224
670224
670224
670227
670227
670227
670227
670227
670227.
670301
670301
670302
670302
670303
670303
670306
670306
670306
670306
670306
670307
670307
670307
670307
670312
670312
670316
670316
670316
670316
670318
670318
670313
670318
670318
670318
6 703 IS
670319
670319
670319
67031<3
670319
670321
670321
670321
670324
670324
670324
670324
670326
^Gf-j
n
0
0
n
0
0
0
6
a
0
3
0
0
8
n
n
n
Q
n
GALS
0
5200
0
2700
0
0
0
0
0
4700
0
2700
0
5400
0
2700
0
0
3200
0
1800
0
0
0
1800
0
2700
0
0
0
900
0
1800
0
2700
6
2700
0
0
0
2700
0
2700
0
0
1800
, 0
2700
0
2800
TYP
n
D
P
D
D
D
D
D
r
D
D
D
D
D
D
D
0
n
LEG
2B
1A
IB
1A
IB
2A
26
3i
38
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
18
1A
IB
2A
2B
1A
18
1A
IB
2A
2B
1A
IB
1A
•
18
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1C
1A
IB
1A
It!
P
1A
UTM
XT505625
XT713363
XT550363
XT810530
XT810490
XT830530
XT830450
XT820470
XT820530
XT700400
XT550370
XT900460
XT750534
XT720370
XT530375
XT670297
XT727300
XT768214
XT710360
XT510370
XT770220
XT740300
X.T760300
XT770250
XT457500
XT503620
XT760220
XT730330
XT7 10340
XT700410
YT040640
YT040490
YT040640
YT040490
XT994640
XT994480
XT880520
XT870600
XT880610
XT890520
XT915520
XT903613
XT930520
XT920620
XT930550
XJ040650
YT 867958
>T900470
XT750530
XT826466
.
'
�UNCLASSIFIED
BINH DUONG
************
LEG
TYP
GALS
IB
0
UD
2790
IB
0
1A
D
930
IB
0
1C
0
ID
0
1A
D
930
IB
0
1C
0
ID
0
1A
;
P
1860
IB
0
1A
C
2790
IB
0
1A
P
5300
IB
0
1A
D
5580
IB
0
It
D
2790
IB
0
1A
D
2790
IB
0
1A
n
2790
IB
0
1A
C
2790
IB
0
1A
D
2790
IB
0
1A
D
2790
IB
0 V . -. -..
1A
D
2790
IB
0
1A
D
2550
IB
0
1A
D
5950
IB
0
2A
0
2B
0
1A
D
2000
IB
0
2A
0
2B
0
1A
C
3000
IB
0
1A
P
6000
IB
. 0
1A
D
5060
IB
0
1A
1000
n
PROV NO. = 23
MISSIONS STARTING IN
OiTE
670326
670403
670403
670406
670406
670406
600
746
670406
670406
670406
670406
670409
670409
670409
670409
670411
670411
670411
670411
6 704 12
670412
670412
670412
670412
670412
670412
670412
670415
670415
670608
670608
670618
6 70618
670702
670702
670706
670706
670706
670706
6 7070 P
670708
670708
6 70 70 3
670711
670711
670715
670715
670719
670719
670719
AGN
0
0
W
W
0
0
0
0
0
0
0
0
W
<j
0
M
.W
W
W
W
0
UTN!
XT826523
XT837446
XT837525
XT760234
XT650318
X.T650364
XT710389
XT760234
XT650318
XT650364
XT710389
XT982540
XT981635
XT932540
XT932622
XT969550
XT969632
XT945548
XT945626
YT025636
YT025480
XT885520
XT873603
YT16463S
YT162514
XT894530
XT877617
YT037270
YT037450
XT970360
XT980440
YTQ00360
XT999440
XT990430
XT990360
XT986437
XT986530
XT996530
XT996620
XT980430
XT980360
XT981320
XT9S1264
YT028646
YT028467
YT015&40
YT010455
YT020455
YT020640
YT020455
�OAT?
6 707-1 =
670721
670721
670725
670725
670725
670725
671004
671004
671004
671004
671004
AGN
n
TYP
0
4000
D
0
•ti
w
B
671-004 '
671004
671004
671004
671004
680402
630402
680402
630402
6S0404
680404
680404
680407
680407
680407
680408
680408
680408
680408
680409
680409
680416
680416
680417
680417
680502
68050?
680511
630511
680526
680526
680601
630601
680607
680607
680616
630616
6S0616
GALS
W
W
w
w
w
w
w
w
w
w
w
w
w
2850
0
5800
0
6000
0
0
0
0
0
0
0
0
0
5650
0
0
0
3000
0
0
5700
0
0
6000
0
0
0
6000
D
P
C
D
DD .
D
D
0
3000
0
2950
0
3000
0
6000
0
4600
0
3000
0
3000
. 0
5000
0
0
D
P
p
0
n
c
P
D
LEG
IB
1A
IB
1A
16
1A
IB
1A
IB
2A
2B
3A
3B
4A
4B
5A
5B
1A
IB
2A
26
1A
18
1C
1A
IB
1C
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
13
1C
UTM
YT020640
YT057460
YT057640
XT962625
XT962530
YT003655
YT003480
XT516330
XT572350
XT587342
XT6 12342
XT515371
XT574344
XT572330
XT595326
XT610320
XT655300
XT868503
XT750533
XT750537
XT794543
XT840500
XT760535
XT818535
XT746285
XT680283
XT600226
XT868503
XT750533
XT750537
XT794543
XT699520
XT691350
XT681520
XT664334
XT734288
XT589259
XT714520
XT707356
XT734290
XT589262
XT748269
XT600223
XT855512
XT777542
XT488608
XT535638
XT730296
XT671294
XT587267
�UNCLASSIFIED
M I S S I O N S STARTING IN
DATE
630616
630616
630621
680621
681026
681026
681026
681113
681113
681113
681113
681113
681124
681124
681124
681124
681124
681124
681124
631124
681126
681126
681202
681202
681202
63120?
681202
681213
681213
631215
681215
681217
681217
681218
681218
681220
681220
681228
681228
681229
681229
681229
681231
631231
681231
690107
690107
690112
690112
690113
AGN
W
W
H
W
W
g
W
P
W
W
W
W
0
W
W
W
W
n
Q
GALS
3000
0
6000
0
2600
0
0
5000
0
0
4350
0
6500
0
0
0
0
0
0
0
6000
0
1500
0
0
0
0
6000
0
4000
0
6000
0
3000
0
5000
0
5000
0
9000
0
0
8000
0
0
9000
0
9000
0
3000
PROV NO. = 23
BINH OUGNG
TYP
D
D
D
r
p
F
r>
p
D
D
D
D
D
D
r
C'
D
r<
LEG
1A
IB
1A.
IB
1A
IB
1C
1A
IB
1C
1A
IB
1A
IB
1C
ID
IE
IF
1G
1H
1A
IB
1A
IB
1C
ID
IE
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
18
1C
1A
IB
it
IB
0
1A
UTM
XT489601
XT550640
VT477585
XT555634
YT116370
YT045343
XT950343
XT688523
XT657439
XT667340
YT101372
XT955372
XT656176
XT662176
XT664173
XT698193
XT697195
XT711210
XT705210
XT656176
YT121362
XT950362
XT662175
XT665173
XT697193
XT710210
XT707210
YT080377
X.T950377
YT103369
XT952351
YT030568
XT880568
YT035545
XT867530
YT030570
XT860570
YT010557
XT370557
XT749230
XT689268
XT680299
XT749220
XT680260
VT669300
YT033510
Y7033343
YT042510
YTQ42343
YT625506
l~
�DAT!:
690118
69011S
690118
690118
690118
690120
690120
690120
690120
690122
690122
690123
690123
690127
690127
690127
690127
690128
690128
6^013 1
690131
690209
690209
690209
690209
C
6 ,0211
690211
690212
690212
690212
690212
690220
690220
690223
690223
690225
690225
690306
690306
690307
690307
690309
690309
69031G
690313
690313
690326
&90326
690331
690331
AGN
W
0
W
a
rt
w
w
w
w
B
W
0
w
w
w
w
:i
w
w
n
w
,-i
GALS
0
2000
0
0
0
8000
0
6000
0
9000
0
7000
0
5000
0
5000
0
7000
0
3000
0
1595
0
5000
0
300
0
5000
0
0
0
5000
0
3000
0
9000
0
7000
0
6000
0
6000
0
7000
0
0
8.0
00
0
950
0
TYP
D
0
0
D
D
C
D
D
P
V
n
F
D
n
c
o
n
p
D
n
D
K
LEG
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
18
1A
IB
1A
IB
1A.
IB
1A
IB
1A
IB
2A
28
1A
IB
1A
IB
,
1A
IB
1A
13
1A
IB
1A
IB
1A
IB
1C
1A
IB
IA
IP
UTM
YT625350
YS123552
YS051524
YS051493
XS953555
YT016350
YT017360
YT052505
YT052350
YT072480
XTS48343
YT072480
XT94S343
XT603230
X'r603400
XT980552
XT880552
YT036546
XT880546
YT028530
YT028350
YT805127
XT809082
YT075475
XT955341
XT994516
YT060680
YT028535
XT980589
XT914589
YT980589
YT029530
XT910580
YT026530
YT026360
YT117372
XT950372
YT038540
XT866540
YT0505UO
YT060300
YT030564
XT880564
XT735287
XT673239
:<T587260
XT970526
" T800526
XT770174
XT669242
•,
t
*
�D4Tr
690402
690402
690412
690412
690412
690412
690424
690424
690425
690425
690425
690427
690427
690427
690429 .
690429
690429
690430
690430
690430
690430
690430
690508
690508
690508
690508
690509
690509
690509
690509
690511
690511
690511
690511
690514
690514
690517
690517
690517
690517
690518
690518
690523
690523
690524
690524
690531
690531
690602
690602
4GN
W
3
0
0
0
. 0
0
0
0
0
0
0
0
0
0
0
0
GALS
9000
0
250
.0
0
0
1100
0
5000
0
0
3000
0
0
6000
0
0
300
0
0
0
0
6000
0
0
0
6000
0
0
0
7000
0
0
0
6000
0
9000
0
0
0
8950
0
5000
0
7000
0
8500
0
3333
0
TYP
0
E
F
D
0
0
Vv
P
D
D
D
D
D
' r*
r;
c
n
LEG
1A
IB
1A
IE
1C
ID
1A
IB
1A
18
1C
1A
IB
1C
1A
IB
1C
14
13
2A
3A
4A
1A
IB
2A
28
1A
IB
2A
2B
1A
IB
1C
ID
IA
IB
1A
18
1C
ID
1A
IB
1A
IB
IH
IB
1A
IB
1A
IB
UTM
YT015550
YT015342
XT635227
XT653230
XT665242
XT675230
XT784490
XT788520
XT693531
XT659450
XT669360
XT629381
XT596295
XT610228
XT607400
XT607365
XT651237
XT580311
, XT620318
XT606334
XT613330
XT652318
YT022587
XT914587
XT915593
XT970593
YT032533
YT000532
XT980530
XT350524
YT037533
YT007533
XT980533
XT860533
YT030561
XT37056l
XT911577
YT035577
YT080577
YT080577
XT888565
YT060565
XT890556
YT060556
XT878573
YT060573
YT060539
YT380540
VT914534
YT020585
�DATE
690604
690604
690607
690607
690607
690617
690617
690617
690617
690617
690617
690617
690617
690619
690619
690620
690620
690620
690620
690620
690620
690620
690620
690620
690620
690620
690622
690622
690623
690623
690623
690627
690627
690707
690707
690707 .
690707
690707
690707
690707
690707
690707
690716 .
690716
690716
690716
690716
691113
691113
691117
AGN
0
0
0
0
0
0
0
0
0
GALS
4000
0
5000
0
0
1250
0
0
0
0
0
0
0
100
0
1000
0
0
0
0
0
0
0
0
0
0
6000
0
850
0
0
100
0
800
0
TYP
D
D
s
S
s
D
p
s
s
0
0
0
0
0
0
s
0
0
0
0
280
55
55
1A
IB
1A
IB
6
0
500
0
0
0
LEG
1A
IB
1A
IB
1C
1A
IB
1C
IP
2A
2B
2C
2D
F
S
' f
1C
ID
IE
IF
2A
3A
3B
3C
3D
1A
IB
1A
IB
1C
1A
IB
IE
1A
IB
1C
ID
2A
2B
2C
2D
1A
IB
1C
ID
IF
1A
1A
1A
UTM
YT033524
YT045524
YT691520
YT663447
YT677343
XT588310
XT605318
XT614314
XT585300
XT620267
XT650270
XT650253
XT620253
XT615227
XT598263
XT592280
XT605300
XT636307
XT636305
XT605296
XT592280
XT623283
XT638268
XT650269
XT650253
XT638254
YT035547
XT882547
XT750176
XT769150
XT750150
XT615227
XT598263
XT696210
XT640210
XT640227
XT654228
XT665240
XT680178
XT693185
XT668176
XT680173
XT640210
XT640227
XT654228
XT665240
XT696210
XT528588
XT596270
>T575275
,
.
*
"•5
�D4TF
691206
691206
691206
691206
691210
691210
691210
691210
691212
691212
691212
691213
691213
691214
691214
691215
591215
691215
691215
691215
691216
691216
691216
691216
691216
691219
691219
691219
691219
691219
691219
691219
691219
691222
691222
691222
691222
691222
691223
691223
691224
691224
691224
691224
691224
691224
691224
691226
691226
691226
A ON
n
3
0
0
Q
0
0
0
0
n
0
GSLS
110
0
110
0
4500
0
0
0
4000
0
0
110
0
5000
0
550
0
0
0
0
220
0
0
0
0
660
0
0
0
0
2000
. 0
0
1100
0
TYP
F
F
D
D
E
D
S
S
s
r
s
6
0
0
0
0
1100
0
330
0
0
0
0
0
0
4800
0
1320
0
0
D
LEG
1A
IB
1A
IB
1A
IB
1C
ID
1A
IB
1C
1A
IB
1A
IB
1A
IB
1C
ID
IE
1A
IB
1C
ID
IE
1A
IB
1C
ID
IE
1A
IB
1C
14
IB
1C
ID
IE
1£
IB
S
c
5
1A
IB
1C
ID
IE
1A
IB
1A
IB
1C
UTM
XT726V+4
XT749416
XT984490
XT787520
XT6C0422
XT657445
XT680452
XT768436
XT600440
X.T685483
XT732512
XT480590
XT495635
XT600427
XT763489
XT632173
XT692164
XT701212
XT668243
XT60422't
XT632173
XT692164
XT701212
XT668243
XT604224
XT632178
XT692164
XT701212
XT668243
XT604224
XT702533
XT671450
XT671400
XT632178
XT692164
XT701212
XT668243
XT604224
XT600418
7T680448
XT632176
XT692164
XT701212
XT668243
XT604224
XT60043T
XT754496
XT632173
X7692164
XT701212
,
*
�UNCLASSIFIED
M I S S I O N S STARTING IN
D*T":
691226
691226
691227
6<U227
691227
691227
691227
691230
691230
691230
691230
691230
691231
691231
691231
691231
691231
691231
691231
700102
700102
700102
700102
700102
700103
700103
700103
700103
700103
700104
700104
700104
700105
700105
700105
700105
700105
700106
700106
700106
700106
700106
700106
700106
700109
700109
700109
700109
700109
700109
AGN
0
0
n
0
0
0
0
0
GfeLS
0
0
220
0
0
0
0
1320
0
0
0
0
88
0
0
0
0
5000
0
440
0
0
0
0
440
0
0
0
0
2800
0
0
880
0
0
B I N H PUDNG
TYP
5
S
c
D
S
S
D
S
6
0
0
3
B
0
110
0
0
0
0
5000
0
4300
0
. 0
3000
0
0
5
P
D
D
P R O V NO.
UTM
XT663243
XT604224
XT632178
XT692164
XT701212
XT668243
XT604224
1A
XT632178
XT692164
IB
XT701212
1C
XT668243
ID
XT604224
IE
XT632178
1A
XT692164
IB
XT701212
1C
XT668243
ID
XT604224
IE
1A
XT603440
XT730513
IB
XT632178
1A
IB
XT692164
1C
XT701212
ID
XT663243
IE
XT604224
1A
XT632178
IB
XT692164
XT701212
1C
ID ' XT668243
IE
XT604224
1A
XT708528
18
XT679450
1C
YT679400
1A
XT632178
XT692164
IB
XT701212
1C
XT668243
ID
XT604224
IE
1A
XT632178
XT692164
IB
XT701212
1C
ID
XT668243
IE
XT604224
1A
XT600433
IB
XT758492
XT705530
1A
XT674450
IB
XT675400
1C
1A
XT95959B
IB
XT8K2545
2A
VT881548
LFG
ID
IE
1A
18
1C
10
IE
23
�UNCLASSIFIED
MISSIONS START ING IN
BINH DUONG
* * * * S.3JT***
• » *
DATE
700109
700111
700111
700111
700111
700111
700111
700111
700111
700113
700113
700113
700113
700113
700115
700115
700115
700116
700116
700116
700116
700116
700116
700116
700116
700116
700116
700116
700117
700117
700117
700117
700117
700119
700119
700119
700119
700119
700120
700120
700120
700120
700120
700121
700121
700121 •
700121
700121
700123
700123
AGN
0
8
0
W
0
W
W
0
Q
GALS
0
550
0
0
0
0
3000
0
0
1210
0
0
0
0
4600
0
0
770
0
0
0
0
5000
0
0
0
5000
0
990
0
0
0
0
1320
0
TYP
S
0
0
0
0
LEG
2B
1A
IB
1C
D
5
C
S
D
D
5
S
a
0
0
880
0
0
0
0
880
0
0
0
0
825
PROV NO.
*
s
c
s
ID
IE
1A
IB
1C
1A
IB
1C
ID
IE
1A
IB
1C
1A
IB
1C
10
IE
1A
IB
2A
28
1A
IB
1A
IB
1C
ID
IE
1A
IB
1C
ID
IE
1A
IB
1C
ID
IE
1A
IB '
1C
10
IE
It
IB
UTM
XT956599
XT632178
XT692164
XT701212
XT668243
XT604224
XT600429
XT654451
XT734508
XT632178
XT692164
- XT701212
XT668243
XT604224
XT696533
XT665445
XT665400
XT632178
XT692164
XT701212
XT668243
XT604224
XT947601
XT870558
XT872554
XT953599
XT947601
XT870558
XT632178
XT692164
XT701212
XT668243
XT604224
XT632178
XT692164
XT701212
XT668243
XT604224
XT632178
XT692164
XT701212
XT668243
XT604224
XT632178
XT692164
XT701212
XT668243
>T604224
V
T632178
XT692164
UMCLSSSI
23
�OAT1:
700123
700123
700123
700126
700126
700126
700126
700126
700126
700126
700126
700126
700127
700127
700127
700127
700127
700128
700123
700 12S
700128
700123
700202
700202
700202
700202
700202
700203
700203
700203
700203
700203
700203
700203
700203
700203
700203
700203
700204
700204
700204
700204
700204
700204
700204
700205
700205
700205
700205
700205
AGN
B
8
0
G£LS
0
0
0
110
0
0
0
0
3000
0
0
0
110
0
TYP
s
0
s
0
8
B
0
M
P
0
C
0
0
495
0
0
0
0
. 880
0
0
0
0
247
0
0
0
0
3000
0
0
0
0
0
330
0
0
0
0
1300
0
55
0
0
0
0
s
s
s
D
s
D
S
LEG
1C
ID
IE
1A
18
1C
ID
IE
1A
IB
1C
ID
1A
IB
1C.
ID
IF
1A
IB
1C
ID
IE
1A
18
1C
ID
IE
1A
IB
1C
ID
IE
1A
IB
2A
2B
3A
33
1A
IB
1C
10
IE
1A
IB
1A
IB
1C
10
IF
UTM
XT701212
XT66B243
XT604224
XT632178
XT692164
XT701212
XT668243
XT604224
XT692532
XT680436
XT662455
XT658400
XT632178
XT692164
XT701212
XT668243
XT604224
XT63217C
XT692164
XT701212
XT668243
XT604224
X.T632178
VT692164
XT701212
XT668243
XT604224
XT632173
XT692164
XT701212
XT668243
XT604224
XT770477
XT705452
XT712450
XT770472
XT770469
XT723450
*T632178
XT692164
XT701212
XT668243
XT604224
XT600415
XT680445
>'T632173
XT692164
XT701212
XT668243
XT604224
�MISSIONS S T A R T I N G IN
OAT C
700205
7J0205
700205
700205
700206
700206
700206
700206
700206
700207
703207
700207
700207
700207
700210
700210
700210
700210
700216
700216
700216
700216
700216
700216
700303
700303
700303
700303
700309
700309
700309
700314
700314
700314
700401
700401
700401
700401
700403
700403
700403
700403
700403
700403
700406
700406
700406
700406
700406
700406
AGN
0
8
Q
0
0
0
0
0
0
0
o
0
GALS
3000
0
0
0
440
0
0
0
0
770
0
0
0
0
3000
0
0
0
3000
0
0
0
0
0
2700
0
0
0
2000
0
0
1300
0
0
2500
0
0
0
385
0
0
0
220
0
3000
0
0
' 0
0
0
PROV NO. = 23
SINK DUONG
TYP
!>
LEG
1A
IB
S
S
r
D
D
D
P
D
S
S
D
24
2B
1A
IB
1C
ID
IE
1A
IB
1C
10
IE
IA
IB
2A
28
1A
IB
2A
2B
3A
36
1A
IB
1C
ID
1A
IB
1C
1A
IB
1C
1A
IB
2A
2B
1A
IB
1C
ID
1A
IB
IA
IB
1C
2A
2B
3A
UTM
XT600410
XT680409
XT6S0412
XT600412
XT632178
XT692164
XT701212
XT66.8243
XT604224
XT632178
XT692164
XT701212
XT668243
XT604224
XT770483
XT685450
XT770480
XT692450
XT737508
XT687477
XT688475
XT739506
XT740505
XT689474
XT965589
XT863528
XT881555
XT927580
XT729514
-XT655470
XT655400
XT691533
XT661453
XT660400
XT600405
XT680405
XT680407
XT600408
XT692164
XT701212
XT668243
XT604224
XT650250
XT660250
XT770460
XT738448
XT680405
XT668438
XT600412
XT600403
�MISSIONS STARTING IN
0£Tc
700406
700406
700409
700409
700409
700409
700409
700409
700409
AGN
0
G/SLS
0
0
3000
0
0
0
0
0.
0
BINH DUONG
TYP
D
.
LEG
3B
3C
1A
18
1C
ID
IE
IF
1G
UTM
XT646402
XT680405
XT670530
XT706533
XT752497
XT745489
XT697524
XT670518
XT670530
UNCLASSIFIED
PROV NO. = 23
�NREC = 17381
NREC= 17381
NPROV=
NPROV=
246
246
NZREC=
NZREC=
513
513
UNCLASSIFIED
�MISSIONS STARTING IN
TAY NINH
£<•**#* i|-*.-£:t#4:
DATE
650924
650925
651003
651004
651008
651008
651010
65W10
651012
651017
651017
651019
651019
651019
660918
660918
660918
660918
660922
660922
660923
660923
660924
660924
660925
660925
660926
660926
660927
660927
660927
660927
660929
660929
660929
660929
660930
66093 J
661002
661002
661002
661002
661002
661002
661002
661003
661003
661003
661003
661003
TYP
r
C
C
C
C
0
GALS
3000
1800
2000
200
2700
0
3000
0
2000
1000
0
2000
2000
0
2700
0
0
0
2700
0
2000
0
1BOO
D
f GN
0
0
0
0
0
0
0
0
0
0
0
0
-o
c
r
c
c
c
D
n
D
0
0
1800
0
0
0
0
0
0
0
n
0
.
0
2700
0
2700
0
2700
0
2700
0
2700
0
4000
0
3600
0
0
0
3600
0
D
D
0
C
0
D
D
D
'°
/
1800
0
0
0
D
1600
0
LEG
1A
1A
14
It.
1A
13
1A
IB
1A
1A
IB
1A
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
13
2A
2B
1A
IB
1C
0
1A
C
IB
1C
1A
1C
UTM
XT400640
XT100755
XT185760
XT360660
XT1G2754
XT26S760
XT450630
XT380780
XT200740
XT055560
XT060670
XT050600
XT015550
XT040700
XT005569
XT040610
XT035650
XT020711
XT455555
XT370670
XT600847
XT442843
XT117690
XT120860
XT450550
XT500690
XT120705
XT130870
XT552705
XT383705
XT020710
XT020320
XT010570
XT030710
XT110700
XT110830
XT485760
XT260760
XT483820
XT446818
XT300918
XT285918
XT082822
XT180940
XT200935
XT450550
,\T500660
XT550700
XT450550
XT340690
�TAY NIMH
«**#**##****
TYP
LEG
GALS
1A
2700
D
IB
0
1A
1300
D
18
0
2A
0
2B
0
1A
D
3600
IB
0
1A
3600
D
IB
0
IA
D
3600
IB
0
1A
r
3600
IB
0
1A
D
3600
IB
0
1A
2700
D
IB
0
1A
D
2700
IB
0
1A
D
2700
IB
0
1A
D
2700
IB
0
1A
D
2700
IB
0
1A
2700
D
IB
0
1A
D
2700
IB
0
1A
D
2700
IB
0
D
1A
3600
IB
0
1A
D
2700
IB
•o
1A
1800 v . - ~ D
IB
0
1A
2700
D
IB
0
1A
2700
D
IB
0
1A
P
2700
IB
0
p
1A
3600
IB
0
1A
2700
r
18
0
1A
D
1800
IB
0
PROV NO. = 24
MISSIONS START ING IN
DATR
661006
661006
661006
661006
661006
661006
661007
661007
661007
661007
661009
661009
661009
661009
661010
661010
661013
661013
661013
661013
661014
661014
661014
661014
661015
661015
661015
661015
661016
661016
661017
661017
661018
661018
661020
661020
661021
661021
661022
661022
661023
661023
661023
661023
661023
661023
661024
661024
661026
661026
AGN
0
0
0
0
W
W
W
w
w
w
w
w
w
0
0
0
w
H
w
w
w
w
w
w
UTM
XT170630
XT305690
XT555700
XT565760
XT618770
XT622820
XT118710
XT1 3.6870
XT015570
XT027740
XT280690
XT280850
XT630810
XT420810
XT137702
XT139902
XT550710
XT370710
XT460560
XT360680
XT080820
XT200930
XT590738
XT414738
XT195682
XT195885
XT050620
XT000820
XT570760
XT420760
XT550700
XT400700
XT120709
XT140879
XT335695
XT335895
XT600350
XT384870
XT146713
XT145890
XT136705
XT136860
XT620772
XT430767
XT354667
XT354860
XT 104710
XT100855
XT286690
M283394
�UNCLASSIFIED
MISSIONS STARTING
P4TF
661026
661026
661026
661026
661027
661027
661028
661028
661029
661029
661030
661030
661030
661030
661030
661030
661031
661031
661101
661101
661102
661102
661103
661103
661103
661103
661103
661103
AGN
W
661106
661106
661106
661106
661106
661106
661107
661107
661107
661107
661107
661107
661108
661108
661108
661108
661109
661109
661100
661109
661109
66110.S
M
w
W
0
0
W
H
W
VI
0
W
0
D
n
0
yj
W
W
W
W
W
W
W
W
IN
GALS
1800
0
1800
0
4500
0
2700
0
4500
0
2700
0
2700
0
2700
0
3600
0
1800
0
2700
0
2700
0
2700
0
2700
0
3600
0
3600
0
4500
0
3600
0
2700
0
2700
0
2700
0
2700
0
3600
0
3600
0
3600
0
T A Y NINH
TYP
r
D
n
D
r
0
n
D
D
D
D
D
D
D.
D
D
D
D
D
D
n
D
C
P
r
PROV NO.
LF.G
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
16
1A
IB
li
IS
1A
IB
24
UTH
XT552714
XT297714
XT060554
XT000320
XT195685
XT195880
XT249689
XT249886
XT630790
XT430790
XT228687
XT226880
XT620815
XT400815
XT560740
XT290740
XT337682
XT334875
XT147690
XT147864
XT328690
XT328895
XT353667
XT353867
XT136703
XT136903
XT570757
XT370757
XT623820
XT420820
XT556735
XT370735
XT287690
XT285870
XT190680
XT190880
XT215635
XT215882
XT620825
XT415825
XT120710
XT132863
XT630790
XT410790
XT620770
XT430770
XT334680
XT335895
XT280690
XT280840
^ /
�DATE
661114
661114
661114
661114
661115
661115
661115
661115
661116
661116
661116
661116
661117
661117
661118
661118
661118
661118
661118
661118
661118
661118
661119
661119
661119
661119
661120
661120
661120
661120
661121
661121
661121
661121
661123
661123
661124
661124
66U24
661124
66112,5
661125
661125
661125
661126
661126
661126
661126
661129
661129
AGN
W
W
W
W
W
W
0
W
0
Q
0
'fl
4
tf
W
0
•ft
W
0
0
0
0
0
0
fi
GALS
1800
0
3600
0
3600
0
900
0
3600
0
2700
0
2700
0
2700
0
900
0
2700
0
3600
0
3600
0
2700
0
3600
0
3600
0
2700
0
2700
0
2500
0
2700
0
3600
0
3600
0
3600
0
2700
0
3600
0
3600
0
TYP
P
D
D
D
r
D
r
c
D
n
D
r
D
c
D
D
0
o
D
0
D
D
D
n
n
LEG
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
IA
IB
1A
18
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
UTM
XT550645
XT390630
XT131713
XT156920
XT153690
XT153872
XT107686
XT075820
XT620827
XT430827
XT160707
XT160870
XT620780
XT420780
XT150700
XT150850
XT150700
XT150850
XT110690
XT110860
XT630300
XT470800
XT127696
XT127855
XT623833
XT452833
XT605845
XT435845
XT170680
XT170865
XT625810
XT490810
XT125720
XT134855
XT549644
XT416631
XT620780
XT*50780
XT120740
XT120830
XT605340
XT520840
XT010574
XT035712
XT560745
XT310745
XT590785
XT520785
XT215685
XT215887
�aiTG
661201
661201
661203
661203
661203
661203
661204
661204
661204
661204
661205
661205
661205
661205
661205
661205
661206
661206
661206
661206
661206
661206
661206
661206
661207
561207
661208
661208
661208
661208
661208
661208
661208
661208
661239
661209
661209
661209
661209
661209
661209
661209
661210
661210
661210
661210
661210
661210
661210
661210
AGN
0
0
0
0
0
0
w
n
0
w
w
w
w
w
w
0
0
n
W
w
0
w
n
n
GALS
3600
0
2700
0
2700
0
3600
0
2700
0
2700
0
1800
0
1800
0
2700
0
3600
0
2700
0
2700
0 2700
0
2700
0
1800
0
1800
0
2700
0
1800
0
3600
0
3600
0
2700
0
1800
0
1800
0
0
TYP
D
D
0
0
D
D
0
C
c
D
D
D
D
D
D
D
D
C
D
D
D
C
D
0
3600
0
D
LEG
1A
IB
1A
IB
14
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
26
If
LH
UTM
XT170702
XT170880
XT210690
XT210855
XT245687
XT245905
XT150360
.
XT350860
XT390630
XT390830
XT270690
XT270S90
XT630800
XT520800
XT380660
XT380860
XT3 10690
XT310850
XT230690
XT230860
XT 560750
XT370750
,
XT200680
XT200890 •
XT563734
XT390734
XT253690
XT253860
XT200930
XT360370
XT330690
XT330890
XT504540
XT504730
XT540850
XT370860
XT160680
XT160860
XT350670
XT350880
XT148b87
XT362837
XT069670
XT065823
XT565760
XT485760
YT48576S
XT5B0769
XTU62-S50
"T003812
�UNCLASSIFIED
MISSIONS
D4TE
661210
661210
661211
661211
661211
661211
661211
661211
661211
661211
661211
661211
661211
661212
661212
661212
661212
661212
661212 .
661212 .
661212
661212
661212
661213
661213
661214
661214
661214
661214
661214
661214
661215
661215
661215
661215
661215
661215
661218
661218
661218
661218
661216
661218
661218
661218
661219
661219
661219
661219
661220
STARTING IN
AGN
W
0
0
GALS
2700
0
2700
0
2700
TYP
D
D
P
0
W
0
'••A
0
H
0
W
W
W
A
W
W
W
W
W
0
\-i
'{I
0
0
0
2700
0
270D
0
0
2700
0
2700
0
2700
0
2700
0
2700
0
2700
0
2700
0
3600
0
2700
0
2700
0
, 4500
0
4500
0
0
0
3600
0
2700
0
2700
0
3600
0
3600
0
3600
0
5400
PROV NO. = 24
TAY MNH
D
0
D
D
0
n
D
D
D
0
D
D
D
P
D
D
[
)
0
r'n
D
LEG
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
UTM
XT 18 0 7 5
6
XT180S50
XT113682
XT113872
XT290693
XT288895
XT188685
XT178880
X TO 6 0 9
60
XT060820
XT110850
XT445597
XT497625
XT360660
XT520660
XT550720
XT360720
XT140900
XT335900
XT480510
XT550645
XT455560
XT355695
XT293690
XT293370
XT450560
XT550700
XT140910
XT320910
XT010810
XT140920
XT170863
XT410337
XT470500
XT540633
XT533672
XT555708
XT150870
XT360870
XT165682
XT165850
XT065690
XT080830
XT203685
XT208855
XT1 10670
XT090330
XT269692
XT2/0390
XT070640
�ntTF
661220
661222
661222
661222
661222
661222
661222
661223
661223
661223
661223
661223
661226
661226
661227
661227
661227
661227
661227
661227
661227
661227
661227
661227
661227
661227
661227
661227
661228
661228
661228
661228
661228
661228
661228
661228
661228
661228
661228
661228
661223
661228
661228
661228
661228
661223
661229
661229
661229
661229
AGN
0
Q
0
0
0
0
0
0
0
0
0
GALS
0
3600
0
3600
0
3600
0
3600
0
0
3600
0
3600
0
3600
0
0
0
2700
0
3600
0
0
0
2700
0
3600
TYP
D
0
P
D
D
0
0
0
0
P
D
oW
W
w
3600
0
3600
0
0
0
3600
0
0
C
D
D
0
w
w
3600
0
0
0
3600
D
P
0
0
0
0
0
3600
0
2700
0
r
n
LEG
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
2A
26
1A
IB
1A
IB
2A
2B
U
IB
1A
IB
1A
IB
U
IB
2A
2B
1A
IB
2A
2B
1A
IB
2A
2B
1A
18
2/>
2B
1A
IB
1A
IP
UTM
XT070820
XT241690
XT241885
XT140900
XT340900
XT176683
XT176873
XT066670
XT066615
XT105845
XT148912
XT300912
XT200850
XT201684
XT570770
XT575770
XT575840
XT590840
XT523770
XT523840
XT576770
XT576840
XT562770
XT562825
XT530770
XT530840
XT561770
XT553840
XT09Q768
XT160778
XT160750
XT090750
XT160760
XT090760
XT090820
XT160820
XT090302
XT160304
XT160760
VT090760
XT090768
XT160768
XT160790
XT090790
XT160603
XT090803
rT552770
XT542810
XT150908
XT322"r08
'
j
�UNCLASSIFIED
MISSION?
DATE.
66122S
661229
661229
661229
661229
661229
661229
661229
661230
661230
670102
670102
670105
670105
670105
670105
670106
670106
670107
670107
670108
670108
670108
670108
670109
670109
670110
670110
670110
670110
670111
670111
670112
670112
670112
670112
670113
670113
670114
670114
670114
670114
670115
670115
670115
670115
670115
670115
670117
670117
S T A R T I N G IN
AGN
0
n
0
W
Q
W
W
W
0
w
w
0
0
n
0
0
w
n
o
0
n
Q
ii
GALS
3600
0
3600
0
3600
0
0
0
3600
0
3600
0
3600
0
3600
0
3600
0
3600
0
2700
0
2700
0
2700
0
2700
0
1800
0
2700
0
1800
Q
1800
0
1800
0
2700
0
900
0
2700
0
2 7 CO
.0
0
0
2700
0
PRCV NO. = 24
T f t Y NIMH
TYP
D
n
D
D
D
0
D
D
D
0
C
n
f)
D
C
n
n
n
D
D
D
D
f:
LEG
1A
IB
IA
18
1A
13
2A
26
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
18
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1ft
IB
1A
IP
I A.
IB
1A
IB
1A
IB
2A
2B
1A
1Q
UTM
XT560750
XT390750
XT550700
XT360700
XT534770
XT534840
XT543770
XT543840
XT160780
XT090780
XT140900
X.T330900
XT150880
XT330880
XT515800
XT345300
XT510800
XT3«40800
XT440810
XT270810
XT160937
XT330900
XT490780
XT330780
XT550840
XT350840
XT150890
XT330390
XT540845
XT360840
XT520830
XT320830
XT150870
XT350870
XT450810
XT293810
XT330900
XT155924
XT450790
YT280790
XT292823
XT460828
XT510790
XT335790
XT165935
.XT265912
>T310910
XT382355
XT550770
XT550840
�^'CLASSIFIED
MISSIONS STARTING
DAT =
670117
670117
670117
670117
670117
670117
670117
670117
670117
670117
670117
6 70 1 1 7
67011C
6 70 1 1 B
670118
670118
670118
670118
670118
6 70 1 1 8
670118
670116
670118
670118
67011S
670118
670118
673118
670118
670118
670119
670119
670119
670119
670119
670119
670119
670119
670119
670119
670119
670119
670120
670120
670120
670120
670121
670121
6701?!
670121
AGN
3
9
t
n,
B
B
3
B
B
3
B
B
3
B
3
B
B
B
B
B
IN
GALS
2700
0
2700
0
0
2700
0
2700,
0
2700
0
0
2700
0
0
2700
0
2700
0
0
0
1400
0
0
2700
0
2700
0
0
0
2700
0
2700
0
2700
0
1800
0
2700
0
2700
0
2700
0
1800
,o
B
2100
0
0
F)
2700
TAY NIMH
TYP
C
D
D
D
D
D
D
0
D
D
D
D
C
D
C
r
D
n
r
p
r
PRGV NO.
LFG
1A
18
1A
IB
1C
1A
IB
1A
IB
1A
IB
1C
1A
IB
1C
1A
IB
1A
IB
2A
2B
1A
IB
1C
1A
IB
IA
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
IA
IB
1C
It
UTM
XT544770
XT550340
XT546770
XT557840
XT557770
XT520765
XT520845
XT526770
XT532840
XT535777
XT538840
XT538767
XT090758
XT160760
XT160765
XT160767
XT090768
XT160771
XT090766
XT160773
XT198773
XT090750
XT160750
XT160752
XT160755
XT090755
XT140760
XT075760
XT160773
XT198773
XT420760
XT270760
XT490810
XT315810
XT160779
XT090777
XT430770
XT270770
XT430765
VT230765
XT160773
XT090773
XT326863
XT140868
XT329868
XT143868
XTQ90775
XT160780
/>T0907S1
XT3G5771
24
�• D1TE
670121
670122
670122
670122
670122
670122
670122
670123
670123
670123
670123
670124
670124
670124
670124
670124
670124
670216
670216
670219
670219
670220
670220
670220
670220
670220
670314
670314
670314
670314
670314
670314
670314
670314
670422
670422
670423
670423
670423
670423
670423
670423
670424
670424
670424
67U424
670426
670426
670428
670428
AGN
W
R
3
3
B
B
9
0
o
0
0
0
w
R
0
B
W
W
W
w
w
w
i-l
GALS
0
2700
0
2245
0
2700
0
2700
0
1800
0
1800
0
2700
0
2700
0
2700
0
2700
0
2700
0
0
2400
0
2700
0
2700
0
2700
0
2700
TYF
1800
0
1850
0
0
0
2500
0
2790
0
1860
0
5580
0
2793
D
a
0
D
D
D
D
D
n
P
p
P
0
C
n
D
D
D
r
D
r.
D
r.
D
p.
LEG
IB
1A
IB
It,
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB'
1A
IB
1A
18
1A
IB
1A
IB
UTM
XT182771
XT180820
XT380820
XT180760
XT320760
XT180830
XT342827
XT328890
XT142890
XT330877
XT148881
XT520835
XT364835
XT494839
XT340884
XT150680
XT330870
XT350780
XT180780
XT510780
XT350780
XT150915
XT260915
XT150913
XT318858
XT154858
XT558723
XT390723
XT558723
XT390723
XT562730
XT400730
XT562730
XT400730
XT460650
XT350710
XT510SOO
XT390800
XT510810
XT3903101
XT520830
XT350830
XT510785
XT358785
XT450772
XT360772
XT320750
XT320860
VT540350
XT360390
'•
|
�DAT;"
670428
670428
670504
670504
670506
670506
670511
670511
670511
670511
670512
670512
670512
670512
670514
670514
670517
670517
670519
670519
670524
670524
670527
670527
670527
670527
670528
670528
670614
670614
670614
670614
670615
670615
670621
670621
670621
670621
670623
670623
670625
670625
670625
670625
670625
670923
670923
671028
671028
680426
A3N
tf
W
W
GALS
1860
0
2790
0
TYP
1860
D
n
C
0
W
1860
0
D
W
1860
0
3720
0
0
0
1860
0
2790
0
2790
0
2790
0
2715
0
2790
0
5150
0
2790
0
0
0
2790
0
2760
0
0
0
2790
0
2790
0
3720
0
0
5900
0
4400
0
5000
C
W
W
W
W
0
H
0
0
0
W
W
W
0
H
0
0
0
C
D
C
D
D
D
C
D
D
D
P
D
D
C'
C
D
D
LEG
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
26
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
If
IB
1A
IB
1A
IB
1C
ID
1A
IB
1A
IB
2A
2B
1A
IB '
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
UTM
XT465638
XT355700
XT463645
XT366694
XT451777
XT358777
XT463643
XT373680
XT440820
XT356820
XT260750
XT260860
XT270860
XT270780
XT221750
XT221857
XT345750
XT345900
XT530850
XT460850
XT520840
XT340860
XT295750
XT235857
XT293857
XT293750
XT304750
XT304868
XT220750
XT220860
XT210860
XT210790
XT520840
XT360840
XT310860
XT310750
XT300750
XT300820
XT056740
XT056320
XT185750
XT185857
XT042750
XT040775
XT018812
XT630810
XT600810
XT337698
XT284810
>T253750
"
1
UNCLASSIFIED
UNCLASSIFIED
�KISS IONS START ING IN
DATF
630426
680429
680429
630507
680507
630507
680507
630508
680508
680515
680515
680519
630519
680521
680521
680522
680522
680523
630523
680524
680524
680528
630528
680604
630604
630605
680605
680606
680606
680607
680607
630607
680609
680609
680609
680610
680610
680610
680felO
680611
680611
630614
680614
680617
680617
630621
680621
630622
630622
680622
AGN
0
0
w
rl
W
W
w
ri
w
0
0
w
0
w
0
•4
w
w
o
w
w
rl
W
W
TAY NINH
************
TYP
GALS
LEG
0
IB
9000
D
IA
0
IB
1A
4800
D
0
IB
1000
1A
D
0
IB
1A
6000
0
0
18
n
1A
5000
0
IB
5050
1A
D
0
IB
D
6000
1A
0
13
3000
D
1A
0
IB
6000
D
1A
0
IB
4000
0
1A
0
IB
D
3000
1A
0
IB
D
6000
1A
0
IB
6000
D
1A
0
18
D
6000
1A
0
18
0
6000
1A
'o
0
6000
0
0
3600
0
3000
. 0
6000
0
6000
0
6000
0
600
•V-0
3000
0
6000
IB
D
1C
1A
IB
1C
D
0
0
0
D
P
n
n
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
UTM
XT349910
XT590824
XT415825
XT437615
XT300920
XT437815
XT300920
XT070818
XT168952
X.T590813
XT405819
XT465800
XT382820
XT075315
XT168743
>'T601830
XT407832
XT331910
XT160947
XT434798
XT300904
XT590818
XT421320
XT272774
XT100761
XT170760
XT248900
XT590856
XT420337
XT327905
XT199925
XT168934
XT267750
XT274801
XT329896
XT438810
XT310928
. XT618765
XT628840
XT270770
XT102757
XT590816
XT420816
XT260780
XT096757
XT063817
XT064805
*T269750
XT351905
XT180760
'*
^
�DATE
680622
680623
680623
630623
6S0624
680624
680626
680626
680702
680702
630702
680702
680706
68J706
680707
680707
680708
680708
680709
680709
680709
680709
680711
680711
630711
680714
680714
680714
680714
680716
680716
680721
680721
680724
680724
680728
680728
680729
68072V
680729
630729
630730
680730
680809
680809
630625
660825
680329
680829
680910
AGN
TYP
GALS
0
W
W
0
a
0
w
W
•ft
W
W
W
n
w
w
0
3000
W
VI
V4
0
0
Q
n
n
D
P
0
D
D
D
D
D
D
D
D
1000
0
6000
0
3000
o
w
D
0
0
5000
0
5700
0
3300
0
3000
0
6000
0
6000
0
4700
0
5000
0
5000
0
3000
0
0
5000
0
3000
0
3000
0
2600
0
0
0
3000
0
3000
0
2000
' 0
3000
0
3000
D
•
D
D
D
C
n
D
C
p
D
L8G
IB
1A
IB
1C
1A
13
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
14
IB
1A
IB
1A
IB
1A
IB
1C
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
28
1A
IB
1A
13
1A
IB
1A
IB
1A
UTM
XT26C910
XT553710
XT600765
XT58785Q
XT250756
XT325890
XT122767
XT207921
XT518750
XT415827
XT263785
XT099770
XT600736
XT430787
XT077809
XT176944
XT100752
XT240752
XT570755
XT400758
XT083816
XT015773
XT273763
XT210767
XT102755
XT578884
XT405850
XT578884
XT405850
XT120773
XT200820
XT102750
XT080830
XT182758
XT262907
XT243760
XT329410
XT451637
XT393632
XT393631
XT465436
XT440797
XT316893
XT341899
XT175932
XT133733
XT213917
XT079805
XT172930
XT136770
|
�UNCLASSIFIED
M I S S I O N S STARTING IN
DATF
680910
680914
680914
681103
681103
681103
681103
681215
681215
681215
631215
681215
631215
690205
690206
690209
690219
690219
690326
690329
690329
690329
690330
690330
690330
690330
690330
690331
690331
690331
690331
690401
690401
690401
690414
690414
690414
690414
690414
690414
690414
690414.
690414
690414
690416
690416
690416
690419
690419
690419
*GN
W
8
GALS
0
4000
0
1500
PRCV NO. = 24
TYP
D
P
0
H
ti
W
W
W
w
X
w
w
w
0
0
Q
0
0
0
600
0
0
0
0
0
550
550
440
1210
0
750
7000
0
0
7000
0
5000
0
, 0
2475
0
0
0
7000
0
0
1250
0
0
0
0
0
0
0
0
0
3000
0
'0
7000
0
0
P
P
P
P
w
P
0
D
D
W
D
W
L5G
IB
1A
IB
1A
IB
1C
ID
1A
IB
1C
ID
IE
IF
1A
1A
1A
1A
IB
1A
1A
IB
1C
1A
IB
1A
IB
1C
1A
IB
2A
2B
1A
IB
1C
1A
IB
1C
ID
IE
IF
D
D
2A
2B
34
3B
1A
IB
1C
1A
IB
1C
UTM
XT220920
XT166671
XT250910
XT263702
XT287702
XT287687
XT263687
XT277586
XT280586
XT277580
• XT280578
XT285530
XT286585
XT085818
XT623810
XT332900
XT590335
XT669240
XT282582
XT356895
XT326894
XT200914
XT070805
XT200933
XT354896
XT310895
XT185912
XT100500
XT013551
XT105463
XT215430
YT066810
XTU3832
XT206930
XT250370
XT346330
XT350297
XT373263
XT390231
XT394210
XT425090
XT400190
XT450050
XT463020
XT465803
XT380S68
XT343911
XT359891
XT309890
XT136907
1
�DATF
690421
690421
690421
690421
690421
690421
690421'
690423
690423
690423
690423
690423
690423
690424
690424
690424
690425
690425
690429
690429
690429
690430
690430
690502
690502
690502
6?0502
690504
690504
690504
690504
690504
690504
690504
690504
690504
690506
690506
690509
690509
690509
690513
690513
690513
69D514
690514
6C0514
690514
690514
690516
AGN
0
GALS
5000
0
0
0
0
0
0
0
. a
5000
0
750
0
0
0
0
0
5000
TYP
D
r
w
p
0
0
6000
0
0
0
a
7000
D
0
0
6000
D
0
0
3000
D
0
0
0
0
n
2800
V*
0
0
0
0
0
6000
D
0
0
0
4000
D
0
0
4000
D
0
0
0
7000
ri
0
0
200
0
0
46OO
D
V.
0
0
0
0
9000
C
LEG
1A
IB
1C
2A
26
1A
IB
1A
IB
2A
26
3A
3B
1A
IB
1C
1A
IB
1A
IB
1C
1A
IB
1A
IB
2A
2B
1A
IB
2A
23
3A
3B
1A
13
1C
1A
IB
1A
IB
1C
1A
IB
1C
1A
IB
1A
IB
1C
1A
UTM
XT600843
XT552848
XT502874
XT468855
XT440853
XT072784
XT203918
XT250340
'*
XT390230
XT400190
XT425090
XT450050
XT463020
XT355901
XT200919
XT178929
XTC69804
XT194951
XT351885
XT310885
XT181903
XT070774
XT190900 |
XT605844
XT550844
XT503870
XT441836
XT253373
XT253340
XT253340
XT347330
XT350296
XT373263
XT475852
XT410845
XT337908
XT075815
XT193936
XT348903
XT203924
XT190930
XT351873
XT310878
XT160897
XT488390
XT463400
XT474846
*T 40 5 844
XT331895
XT617804
�UNCLASSIFIED
MISSIONS STARTING IN
DATE
690516
690516
690516
690516
690518
690518
690520
690520
690520
690520
690520
690520
690520
690520
690520
690520
690521
690521
690522
6V0522
690522
690523
690523
690523
690524
690524
690527
690527
690527
690527
690528
690528
690526
690528
690601
690601
690604
690604
690604
690604
690609
690609
690609
690610
690610
690610
690610
690610
690618
690618
ASN
0
0
0
0
0
0
0
GALS
0
0
0
0
9000
0
0
0
0
0
0
0
0
0
0
0
4000
0
7000
0
0
6000
0
0
200
0
9000
0
PROV NO,
•
TYP
D
S
D
D
D
S
D
0
0
0
0
0
0
0
Q
0
500
0
0
0
5000
0
250
0
0
0
4600
0
0
100
900
0
'' 0
0
500
0
Vi
P
S
D
s
F
F
LEG
IB
1C
2A
23
1A
IB
1A
IB
1C
ID
IE
If
1G
1H
1J
IK
1A
IB
1A
IB
1C
1A
IB
1C
1A
IB
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
1A
IB
1C
ID
1A
IB
1C
1A
1A
IB
1C
ID
1A
IB
UTM
XT541804.
XT503823
XT481812
XT457812
XT072318
XT189938
XT42.0390
XT458390
XT464400
XT482410
XT464418
XT498385
XT538344
XT520345
XT510327
XT492317
XT077774
XT2 05904
XT350873
XT310872
XT181891
XT621309
XT541807
XT459854
XT058656
XT054563
XT475818
XT393812
XT353840
XT330870
XT020550
;;Tioo5oo
XT105462
XT215432
XT550847
XT378838
XT455525
XT460523
XT460510
XT455510
XT60583d
XT552839
YT500864
XT063584
XT055595
XT085598
XT086595
XT055592
XT055595
VT085598
24
�UNCLASSIFIED
04TE
690618
69061 8
690621
690621
690623
6*30623
690623
690623
690630
690630
690705
690705
690714
690714
690719
690719
690811
690818
690904
690921
690921
690921
690921
690921
690924
690924
690924
690924
690924
691003
691003
691003
691003
691212
691212
700302
700921
700921
700921
700921
701021
701026
701116
701230
710228
AGN
0
0
0
0 .
0
D
0
0
0,
Q
0
0
0
0
3
3
6
3
B
8
TAY NINH
****** ******
LEG
GALS
TYP
1C
0
ID
0
1A
300
F
IB
0
1A
300
S
IB
0
1C
0
10
0
1A
350
F
IS
0
1A
1 1 5.J
F
IB
0
1A
- 500
. «=
13
0
1A
5000
r
IB
0
1A
100
P
1A
50
P
IA
150
P
1A
5900
D
IB
0
1C
0
10
0
IE
0
1A
7000
D
18
0
1C
0
ID
0 /
IE
0 1A
6000
D
IB
0
1C
0
ID
0
1A
330
E
IB
0
1A
220
P
1A
220
P
IB
0
1C
0
ID
0
1A
770
P
1A
770
P
1ft
330
P
1A
330
P
1A
330
P
PROV NO. = 24
MISSIONS START ING IN
UTM
XT086595
XT055592
XT118684
XT093780
XT430512
XT444520
XT44.5498
XT434495
XT118684
XT093780
XT118684
XT093730
XT1 18684
XT093780
XT618823
XT430823
XT273682
XT273682
XT273682
XT084735
XT058676
XT064638
XT052610
XT052553
XT073739
XT047682
XT051640
XT038606
XT038553
XT078737
XT053679
XT057638
XT045609
XT452540
XT480590
XT283582
XT084819
XT087819
XT087814
XT084814
XT330900
XT481715
XT330898
XT067816
XT085816
�i^LAaa iricu
NREC= 17295
NPEC= 17295
NPPOV=
.MPFCV=
367
367
NZRFC=
NZREC=
478
478
UNCLASSIFIED
UMCLASSIFIEO
�MISSIONS STARTING IN
DATC
651125
651125
681013
681013
681013
681013
681027
681027
601110
631110
631204
681204
681204
631204
681212
681212
681215
681215
681228
68122S
690114
690114
690114
690114
690121
690121
690121
690121
690121
690121
690121
690121
690129
690129
690222
690222
690222
690222
690222
693222
690227
690227
690227
690227
690227
690316
690316
690316
690316
690316
AGN
0
8
W
W
W
ti
W
B
B
3
B
W
W
0
W
HAU HGHIA
************
TYP
GALS
LEG
D
2900
1A
0
IB
P
1A
275
0
13
0
1C
0
ID
6000
D
1A
0
IB
n
6000
1A
0
16
6000
D
1ft
0
IB
2A
0
0
2B
6000
D
1A
0
IB
1A
2200
D
IB
0
V,
1A
1100
0
IB
W
1A
530
18
0
0
2A
0
2B
P
725
1A
0
IB
0
1C
0
ID
0
IE
0
IF
0
1G
1H
0
V.'
700
1A
0
IB
D
1A
5600
0
IB
0
2A
0
2B
2000
0
1A
0
IB
1A
1430
F
0
IB
0
, 1C
0
10
0
IF
F
2333
1A
0
IB
0
1C
0
10
0
IrE
UTM
X.S485985
XS550930
YT597098
YT610097
YT61-0106
YT600105
XS 57,892 9
XT477020
XS573927
XT470020
XS529928
XS450998
XS450993
XS52992S
XS551926
XS452011
XS538928
XT450010
XT400133
XT400170
XS667960
XT681013
XT682021
XT710069
XT634156
XT643165
XT660164
XT667152
XT664152
XT660160
XT650163
XT637154
XT400170
XT400133
XS550940
XT470010
XS550938
XT455016
XS468971
YS336878
XS550940
XS569940
XS557950
XS550950
XS550940
XS587927
XS587910
XS640910
XS640927
XS605925
'"
1
�UNCLASSIFIED
MISSIONS STARTING IN
PRQV NO. = 25
HAU HGHIA
* * * • * * *
: * * * * # *
OATF
690316
650316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690322
690426
690426
690426
690428
690423
690503
690503.
690503
690503
690503
690503
690503
690510
690510
690510
690510
690513
690513
690513
690515
AGN
W
n
GALS
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1900
5000
TYP
P
D
0
0
0
550
P
0
3
300
P
0
0
0
0
B
6000
D
0
Q
350
F
0
0
0
0
8000
D
0
0
0
9000
0
LEG
IF
2A
2B
2C
2D
2E
2F
2G
2H
2J
2K
3A
36
3C
30
3F.
3F
3G
3H
3J
3K
3L
3M
3N
4A
48
4C
4D
4E
1A
1A
IB
1C
1A
IB
1A
IB
1C
ID
IF
1A
18
1A
IB
1C
ID
1A
IB
1C
1A
UTM
XS587927
XS587910
AS587838
XS594908
XS632909
XS635899
XS60.1879
XS602870
XS640900
XS640910
XS587910
XS602870
XS603865
XS625883
XS653866
XS 65 3 862
XS625865
XS603850
XS655850
XS659867
XS632883
XS630886
XS627888
XS502870
XS603850
XS605810
XS640810
XS656S50
XS603850
XT650160
XS551926
XS528934
XS450003
XT650168
XT666156
XT634177
XT662175
XT685158
XT685153
XT637178
XS574928
XS471020
XT486126
XT5C0153
XT502152
XT488125
XS 564923
XS480987
XT453014
XS475977
�M I S S I O N S S T A R T I N G IM
DATE
690515
690526
690526
690526
690526
690526
690526
690526
690526
690528
690528
690528
690528 '
690528
690619
690619
690619
690619
690619
690619
690702
690702
690702
690702
690702
690702
690712
690712
690712
690712
690712
690723
690723'
690725
690725
690802
690802
690802
690802
690805
690805
690805
690805
690805
690805
690805
690901
690901
690904
690904
AGN
6
0
0
0
0
0
0
0
0
0
GALS
0
400
0
0
0
1 00
0
0
0
500
0
0
0
0
400
0
0
0
0
0
990
0
0
0
0
0
600
0
0
0
0
5000
0
5000
0
200
0
0
0
450
0
0
0
0
0
TYP
F
F
P
P
P
P
D
D
P
.P
0
0
0
PROV NO. = 25
HAU H G H I A
25
0
100
0
F
W
LEG
IB
1A
IB
1C
ID
1A
IB
1C
ID
1A
IB
1C
ID
IE
1A
IB
1C
ID
IE
IF
1A
IB
1C
ID
IE
IF
1A
IB
1C
ID
IE
1A
IB
1A
IB
1A
IB
1C
ID
1A
IB
1C
ID
IE
IF
1G
1A
IB
IA
IB
UTM
XS335880
XT500152
XT503150
XT490126
XT485127
XT500152
XT503150
XT490126
XT485127
XT640176
XT656175
XT684156
XT683153
XT640168
XT640174
XT660170
XT670163
XT668160
XT660168
XT640166
X.T640174
XT660170
XT670163
XT668160
XT660168
XT640166
XT640176
XT656175
XT684156
XT683153
XT640168
XS497997
XS374910
XT493000
XS373916
XT635155
XT637160
XT644160
XT638154
XT636160
XT650166
XT666164
XT666156
XT660146
XT650140
XT634150
XT633158
XT658168
XT508260
XT545245
�UNCLASSIFIED
MISSIONS START IMG IN
PROV NO. = 25
HAD HGHIA
* * * £ « * *
* * # £ : *
DATE
690904
690904
691016
691022
691027
691027
691027
691027
691115
691117
691117
691119
691121
691124
691124
691124
691126
691130
691130
691130
691208
700126
700126
700130
700130
700217
700303
700303
700314
700314
700413
700417
AGN
W
.•1
W
0
0
0
0
0
0
0
0
n
*
3
0
0
0
W
W
GALS
0
0
990
960
500
0
0
0
110
55
0
165
55
330
55
0
165
385
0
0
•440
55
0
660
0
550
220
0
550
0
220
220
TYP
P
P
P
F
P
F
F
F
P
S
F
F
P
P
S
W
W
S
S
LEG
1C
ID
1A
1A
1A
IB
1C
ID
1A
1A
18
1A
1A
1A
1A
IB
1A
1A
2A
3A
1A
1A
IB
1A
IB
1A
1A
IB
1A
IB
1A
1A
UTM
XT516224
XT511210
XT640160
XT655160
XT640153
XT640170
XT660170
XT658166
XT572240
XT632154
XT644166
XT565272
XT540240
XT600185
XT660167
XS666155
XS473982
XT572240
XT575275
XT540240
XT600180
XT661156
XT666150
XT661156
XT650156
XT665162
XT463018
XS565928
XS525967
XT463020
XT663164
XT663164
UNCLASSIFIED
�N"EC= 17958
NREC= 17958
TJPROV=
NPPQV=
54
54
NZPEC=
NZR5C=
128
128
UMCLASSIFI^O
UNCLASSIFIED
�OAT?
650721
650724
650725
650726
650727
650728
650729
650807
650807
650311
650812
651115
651115
651115
651115
651121
651121
651123
651123
651123
651123
651127
651127
651217
651217
651217
651217
651220
651220
660220
660221
660222
650226
660226
660305
660305
660308
660311
660311
660314
660314
660325
660325
660325
660325
660331
660331
660331
660402
660402
AGN
0
0
0
0
0
0
0
0
0
0
0
0
0
0
G
0
0
0
0
Q
0
0
0
0
0
0
0
0
BIEN HOA
************
LEG
TYP
GALS
4000
D
D
6000
D
6000
6000
D
6000
D
5000
D
4000
0
D
1A
2000
IB
0
2000
C
D
2000
1A
3000
C
0
IB
2A
0
2B
0
It
2000
D
IB
0
1A
3000
D
0
IB
1A
D
3000
0
IB
2700
1A
0
0
18
1A
3000
C
0
IB
2A
0
0
28
1A
3850
D
IB
0
1A
2000
D
1A
5000
D
1000
D
1A
1000
1A
0
0
IB
2000
1A
D
IB
0
1A
2000
0
1A
2000
D
IB
0
1A
2000
D
IB
0
1A
3000
D
0
IB
0
1C
ID
0
1A
3000
D
IB
'' 0
1C
0
1A
3000
D
0
IB
PRCJV NO. =
MISSIONS STARTING IN
UTM
YT080110
YT110060
YT150190
YT240190
YT240270
YT130260
YT140280
YT235275
YT130248
YT235277
YT130248
YT235277
YT130280
YT240270
YT150275
YT240270
YT370390
YT360480
YT220270
YT120310
YT150290
YT150290
YT150290
YT180270
YT130295
YT180273
YT186328
YT150290
YT160260
YT168320
YT175275
YT180330
YT137254
YT112324
YT120324
YT143257
YT170285
YT170325
YT110325
YT170280
YT175325
26
�MISSIONS STARTING IN
DATS
660510
660510
660510
660510
660510
660510
660520
660520
660520
660520
660522
660522
660529
66052?
660707
660707
660712
660712
660712
660712
660716
660716
660721
660721
660723
663723
660726
660726
660727
660727
660728
660728
660804
660804
660806
660806
660810
660810
660811
660811
660811
660811
660811
660811
660811
660812
660812
660C12
660814
660814
AGN
0
0
G
0
0
0
0
0
0
n
0
0
0
0
n
0
0
w
0
0
BIEN HOA
************
TYP
GALS
LEG
2600
D
1A
0
IB
3000
0
1A
0
IB
2A
0
0
28
1A
2000
D
0
IB
0
1C
0
ID
2000
D
1A
0
IB
2000
1A
0
0
IB
3000
D
1A
0
18
1A
D
2000
0
IB
0
2A
0
2B
1000
0
1A
0
IB
2000
D
1A
0
IB
2000
D.
1A
0
IB
2000
D
1A
0
IB
D
1A
2000
0
IB
1750
D
1A
0
IB
2000
D
1A
0
IB
2000
0
1A
0
IB
2000
D
1A
0
IB
3000
D
1A
0
13
0
1C
2900
D
1A
0
IB
0
2A
0
2B
2000
C
1A
'• 0
IB
0
1C
r
3000
1A
0
IB
UTM
YT105315
YT188315
YT167263
YT172330
YT102328
YT189328
YT20.0229
YT235270
YT237265
YT206228
YT105316
YT188317
YT176267
YT187330
YT155285
YT182285
YT150290
YT140305
YT147283
YT145293
YT180350
YT180270
YS245820
YS281879
YS241829
YS274880
YS250824
YS272854
YT185273
YT195330
YT100330
YT193330
YS246808
YS293893
YT145332
YT116480
YT101320
YT101530
YT188330
YT188480
YT145480
YT130050
YT200050
YT134042
YT190040
YT140330
YT140430
YT120480
YT145330
YT155480
i
.vr^ I
I -* /
�IMTE
660814
660817
660817
660817
660820
660820
660820
660822
660822
660822
660824
660824
660826
660826
660826
660826
660826
660826
660826
660826
660826
660828
660828
660838
660829
660829
660907
660907
660907
660907
660908
660908
661012
661012
661012
661012
661018
661018
661026
661026
661027
661027
661031
661031
661105
661105
661106
661106
661110
661110
AGN
0
0
0
0
n
0
0
0
n
0
3
H
w
n
W
0
n
w
'A
w
GALS
0
3900
0
0
. 4000
0
0
3000
0
0
4000
0
3000
0
0
0
3000
0
0
0
4000
0
2000
0
2000
0
2650
0
0
0
2000
0
2700
0
2700
0
3600
0
1800
0
1100
0
3600
0
2700
0
1600
0
2700
0
TYP
D
D
D
D
n
D
D
LEG
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
D
D
p
n
n
D
0
D
D
D
D
n
c
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
UTM
YT100430
YT102363
YT102470
YT154470
YT190330
YT190490
YT14.0490
YT185360
YT185480
YT155360
YT148360
YT152480
YT125360
YT125475
YT120480
YT160480
YT125360
YT125475
YT120480
YT160480
YT105360
YT105480
YS240800
YS295894
YT180360
YT140485
YS20C990
YT200050
YT198050
YS198990
YS243822
YS282900
YT010270
YT012452
YT050270
YT054460
YT087268
YT087468
YT050270
YT050460
YT009270
YT011535
YT015270
YT015453
YT027290
YT027350
YT055270
YT060460
YT094270
YTJ93478
»
�UNCLASSIFIED
MISSIONS S T A R T I N G IN
DATF
661111
661111
661112
661112
661112
661112
651119
661119
661202
661202
661213
661213
661213
661213
661218
661218
661218
661218
661219
661219
661223
661223
661230
661230
661230
661230
670103
670103
670103
670103
670103
670103
670104
670104
670104
670104
670108
670108
670109
670109
670113
670113
670113
670113
670115
670115
670115
670115
670121
670121
AGN
0
W
W
n
w
w
w
W
'A
W
H
W
w
w
w
w .
w
w
0
o
w
w
GALS
2700
0
3600
0
3600
0
2700
0
2700
0
3600
0
1800
0
2700
0
0
0
3600
0
3600
0
3600
0
3600
0
3600
0
3600
0
0
0
27CO
0
2700
0
1800
0
2700
0
1800
0
0
0
2700
0
2 tOO
0
1800
0
B1EN HOA
TYP
D
D
D
C
D
D
D
n
D
D
D
D
D
D
D
0
D
D
D
D
D
0
PROV NO.
LEG
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
10
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
ID
1A
IB
1A
IB
1A
IB
UTM
YT030270
YT030518
YT027270
YT022484
YT048270
YT050450
YT07.1270
YT071430
YT020270
YT030475
YT068107
YT087080
YT089109
YT100058
YT160090
YT100090
YT160080
YT100080
YT100060
YT220060
YT10C067
YT220068
YT100080
YT220776
YT100060
YT200060
YT1 10040
YT220040
YT035178
YT0901T8
YT030160
YT090158
YT008270
YT008446
YT070080
YT 100080
YT100070
YT200070
YT100050
YT220050
YS249803
YS295894
YS296904
YS248816
YT070270
YT070430
YT100075
YT220075
YT200040
YT130040
26
�MISSIONS STARTING IN
DATP
670122
670122
670123
670123
670123
670123
670123
670123
670123
670123
670125
670125
670125
670125
670220
670220
670222
670222
670222
670222
670313
670313
670317
670317
670317 .
670317
670320
670320
670320
670320
670321
670321
670325
670325
670325
670325
670327
670327
670327
670327
670327
670328
670328
6T0329
670329
670401
670401
670401
670401
670407
,*GN
W
GALS
2700
W
2700
BIEN HOA
* * * * * *
* * * * * *
TYP
D
0
D
0
0
0
W
2050
0
0
0
0
W
2400
0
0
0
0
G
2 TOO
D
0
0
6300
0
0
0
8100
D
0
W
3
W
2700
0
900
0
0
0
2700
0
D
D
0
0
4000
0
0
W
1800
0
0
0
27CO
0
0
0
5400
0
0
0
2790
0
0
2790
P
c
0
0
2400
D
0
0
900
0
D
0
2790
W
0
0
0
W
2560
r
r
LEG
1A
IB
1A
18
2A
28
1A
IB
2A
2B
1A
IB
2A
2B
U
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
2A
2B
IA
UTM
YT200020
YT140020
YT200039
YT135039
YT160048
YT219048
YT160047
YT092042
YT100050
YT160050
YS209960
YT178020
YT200200
YT178004
YT057270
YT062448
YT060270
YT060450
YT030270
YT030445
YT050270
YT090240
YT070100
YT060030
YT090100
YT080070
YT138035
YT200035
YT100263
YT096450
YT037245
YT074234
YT007270
YT007430
YT130250
YT100410
YT080270
YT080430
XT763234
XT725350
XT59Q348
YT080240
YT040260
XT680271
XT475226
XT672277
XT748234
XT672295
XT740295
YT160074
1
�D&TF
670407
670407
670407
670415
67041?
670603
670603
670603
670603
670603
670603
670607
670607
670626
670626
670626
670626
670627
670627
67070&
670708
670709
670709
670709
670709
670727
670727
670727
670727
670727
670727
670727
670727
670818
67J81tt
670323
670823
670S23
670823
670823
670823
670823
670823
670824
670824
670824
670824
670823
670828
670828
AGN
W
W
W
'it
W
W
w
n
w
w
w
w
w
n
W
W
0
w
0
0
w
n
w
GALS
0
0
0
2790
0
2600
0
2790
0
2700
0
5580
0
5580
0
3720
0
2790
0
2000
0
4000
0
6000
0
6000
0
3000
0
6000
0
. 0
0
4000
0
3000
0
3000
0
3000
0
4000
0
2000
0
3000
0
4'JOO
0
1000
TYP
D
n
D
D
D
D
0
D
D
0
P
D
P
D
n
rD
D
n
D
C
C
D
LEG
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
It
UTM
YT219074
YT104047
YT140047
YT142027
YT200202
YT070090
YT100100
YT070090
YT100100
YT070090
YT100100
YT120360
YT120530
YT278720
YT280545
YT292716
YT292547
YT435386
YT435570
YT250270
YT250180
YT153170
YT154258
YT185170
YTl 85259
YT160261
YT160170
YT1301&5
YT233164
YT180267
YT180170
YT170252
YT170170
YT060280
YT060447
YT025280
YT025465
YTH7280
YT117463
YT117280
YTH7463
YT137280
YT137462
YT067280
YT067447
YT067280
YT067447
YT036230
YT037460
YT036280
"
1
�MISSIONS ST/RTING IN
niT?
670828
670903
670903
670904
670904
670904
670904
670909
670909
670909
670909
670917
670917
670917
670917
670919
670919
670922
670922
671122
671122
671125
671125
671125
.671125
'680326
680326
680401
680401
680402
680402
680403
680403
680405
680405
630412
680412
680412
680412
680413
630413
680414
680414
680414
680416
680416
680420
680420
680421
680421
ftGN
BIEN HQA
***** *******
TYP
GALS
0
0
D
2900
0
Q
o
P
7000
0
0
0
D
3000
0
G
D
5000
0
0
D
4000
0
1
W
D
3000
0
0
0
2000
0
0
4820
0
0
0
600
0
D
0
2700
D
0
0
W
0
3000
•
D
0
W
60CO
D
0
H
2900
D
0
W
3000
D
0
W
6000
D
0
W
2900
D
0
0
0
W
6000
D
0
W
5800
D
0
0
W
5500
D
0
W
2900
D
0
W
2900
0
LEG
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
26
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1C
1A
IB
1A
IB
D
1A
18
UTM
YT037460
YT029280
YT029465
YT015284
YT015455
YT071280
YT06.9445
YT064280
YT053457
YT073280
YT074460
YT033290
YT033472
YT021280
YT019460
YT142284
YT150495
YT095480
YT102320
YS127800
YS127718
YS128790
YS128718
YS162704
YS162800
YS170759
XS997759
YS180736
XS997736
YS180762
XS995760
YS180764
YS000764
YS180752
>S991752
YS190799
YS120779
YS090779
XS984279
YS180749
YS000749
YS190772
YS120772
YS090772
YS18075B
XS997?58
YS180766
XS938766
YS180766
^5988766
'
>
�UNCLASSIFIED
61 EN HOA
************
TYP
LEG
GALS
1A
D
3000
0
IB
1A
2500
D
IB
0
2A
0
2B
0
1A
6000
D
18
0
It
0
3000
IB
0
3000
D
1A
IB
0
1A
3000
D
IB
0
D
1A
3000
IB
0
2A
0
2B
0
p
1A
450
IB
' 0
1C
0
0
ID
1A
D
2800
0
IB
1C
0
1A
6000
D
IB
0
1A
0
5000
0
18
1A
6000
D
0
IB
D
1A
6000
IB
0
D
5500
U
0
IB
D
1A
3500
0
IB
1A
3000
D
0
IB
0
1A
3000
0
IB
2A
0
0
28
D
1A
2800
0
18
r
1A
2000
IB
'• o
1500
r
14
0
IB
n
1A
3000
PROV NO. = 26
MISSIONS STARTING !N
DATE
680422
630422
680426
680426
680426
630426
680508
630 50 8
680509
680509
680514
680514
680606
680606
680617
630617
630617
680617
680618
680618
630618
680618
680622
680622
680622
680701
680701
630703
680703
680703
680703
680704
680704
680707
630707
630717
680717
680716
6S0718
680720
680720
680720
630720
680720
630720
680726
680726
68072'?
680729
6 808 36
AGN
W
N
W
W
W
W
W
3
W
0
W
'ft
W
W
W
W
W
0
W
W
W
UTM
YS180769
YS9^5770
. YS187798
YS120793
YS120794
YS187794
YS188786
YS120786
YS188795
YS120795
YS188775
^5987776
YS273777
YS273870
YS190779
YS120779
YS090779
XSS 80779
YT104U6
YTU1112
YT094114
YT097105
YS090780
YS020780
YS090780
YT130272
XT970272
YT130317
XT970317
YS284780
YS289865
YT130281
XT970281
YT130345
YT051345
YS292790
YS292870
YT130286
XT970236
YT061355
YT127355
YT125351
YT058351
YT130288
VT970288
YT130269
VT970269
YT130321
YT020325
YT130170
�PATF680B08
680808
660803
630808
680806
680914
680914
680930
680930
680930
680930
680930
680930
630930
680930
680930
680930
680930
630930
630930
680930
680930
630930
680930
680930
680930
680930
680930
680930
680930
680930
680930
680930
630930
680930
680930
630930
680930
680<330
680930
680930
680930
680930
680930
680930
630930
680930
680930
680930
680930
AGN
W
W
B
GALS
0
0
0
3000
0
5000
0
1 1 00
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
' 0
0
0
0
TYP
P
0
P
Lf:G
IB
2A
2B
1A
IB
1A
IB
1A
IB
1C
ID
IE
IF
1G
1H
1J
IK
1L
1M
IN
10
IP
1Q
1R
IS
2A
26
2C
2D
2E
2F
2G
2H
2J
2K
2L
2M
2N
20
2P
2Q
2R
2S
2T
2U
2V
2U
3A
3B
3C
UTM
YT240170
YT242172
YT189172
YT130313
XT970313
XT985300
YT130300
YT029139
YT027156
YT022155
YT018159
YT010160
YT007154
YT000155
XT993153
XT993156
YT000158
YT006157
YT009163
YT019162
YT023158
YT029158
YT032137
YT029137
YT029139
YT014140
YT012144
YT007143
YT006145
YT003145
YT002143
XT993143
XT993154
XT985154
XT974148
XT973144
XT972144
XT972138
XT974137
XT977138
XT984145
XT987152
XT991153
XT991140
YT008139
YT01U35
YT014140
YT009133
YT006132
YT001116
�MISSIONS STARTING IN
DATF
630930
680930
680930
630930
680930
680930
680930
680930
680930
680930
630930
681002
631002
681024
68,1024
681028
631028
681028
681028
631028
681028
681023
681028
681028
681028
631028
681028
681028
6 8 1023
681028
681023
681028
631028
681028
631028
681028
681028
6S1028
681028
681028
681028
681028
68102R
681023
681028
681028
681028
631028
681028
681028
AGN
H
W
W
a
GALS
0
0
0
0
0
0
0
0
0
30CO
0
3000
0
5000
0
isoo
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
BIFN HOA
************
TYP
LEG
3D
38
3F
3G
3H
3J
3K
0
D
C
P
3L
3M
1A
IB
1A
IB
1A
IB
1A
IB
1C
10
IE
IF
1G
1H
U
IK
1L
IM
IN
10
IP
1Q
1R
IS
2A
26
2C
20
26
2F
2G
2H
2J
2K
2L
2M
2N
20
2P
2Q
2R
UTM
XT991115
XT975130
XT972130
XT984117
XT991114
YT003115
YT004122
YT011130
YT009133
YT130304
XT970304
YT130290
XT970290
YT130310
XT970310
YT029139
YT027156
YT022155
YT018159
YT010160
YT007154
YT000155
XT993153
XT993156
YT000153
YT006157
YT009163
YT019162
YT023153
YT029158
YT032137
YT029137
YT029139
YT014140
YT012144
YT007143
YT006145
YT003145
YT002143
XT993143
XT993154
XT985154
XT974148
XT973144
XT972144
XT972138
XT974137
XT977138
VT984145
XT987152
'
�UNCLASSIFIED
IG
MISSIONS STARTING IN
DAT =
631028
681023
631028
681023
681023
681028
681026
681028
681028
6S1028
681028
631023
681028
681028
681028
681028
681028
681028
681028
681031
681031
681031
681105
681105
681106
631106
681106
681106
681110
681110
681115
681115
681115
681115
681116
681116
681125
681125
681125
681125
681125
681125
531126
681126
681126
681126
681129
681129
68112<;
631129
GALS
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
5000
0
825
TYP
0
,'
o -
.K
0
5100
W
P
W
W
W
PROV NO.
3! EN HQA
t yf
sf. j|r #. ^ §. sf i T^ jfr ^f. 3[
' *?
0
4000
0
0
0
6000
0
5000
0
0
0
2400
0
3000
0
9000
0
0
0
9000
0
0
0
3000
0
0
0
D
D
D
0
0
D
P
D
D
LEG
2S
2T
2U
2V
2W
3A
38
3C
30
3E
3f
3G
3H
3J
3K
3L
3M
1A
IB
It
16
1C
1A
IB
1A
18
2A
28
1A
IB
1A
IB
2A
2B
1A
16
1A
IB
1A
IB
2A
26
1A
IB
2A
2B
1A
IB
2A
28
UTM
XT991153
XT991140
YT003139
YTOU135
YT014140
YT009133
YT006132
YT001116
XT991U5
XT975130
XT972130
XT984U7
XT991114
YTU03115
YT004122
YT011130
YT009133
YT120360
XT950360
YS023950
YS058950
YS023950
YT130298
XT970298
YT151281
YT151195
YT170195
YT170265
XT950347
YT050347
YT227280
YT227200
YT252200
YT252275
YT262172
YT130172
YT130323
YT000324
YT219274
YT219195
YT207274
YT207195
YT245274
YT245190
YT235277
YT235190
YT165270
YT165190
YT198190
YT198264
26
�DATF.
681208
681,208
681208
631208
681208
681208
631208
681208
681208
681219
6S1219
661219
681219
681219
681219
681219
681219
681219
681219
681219
681219
681219
681219
631219
690202
690202
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
690207
AGN
W
W
GALS
1540
0
0
0
0
0
0
0
0
4840
1
0
0
0
0
0
0
0
0
0
0
0
TYP
P
P
0
W
M
0
0
6000
0
1100
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
D
P
LEG
1A
13
1C
ID
IE
IF
1G
1H
1J
1A
IB
1C
ID
IE
IF
1G
1H
2A
28
2C
20
2£
2F
2G
1A
IB
1A
IB
1C
ID
IE
IF
1G
1H
1J
2A
2B
2C
2D
2E
2F
2G
2H
2J
3A
36
3C
3D
3E
3F
UTM
XT133016
YT129023
YT162044
YS195996
YS187990
YS173990
YS183997
YT160031
YT133016
YT130050
YT130108
YT116105
YT103095
YT110080
YT093062
YT093050
YT130050
YT060110
YT090U2
YT090108
XS070107
YT066098
YT049099
YT060110
YT250070
YT100070
YT011165
YT051165
YT054140
YT040140
YT040159
YT036159
YT033157
YT028154
YT011159
XT981149
XT9B8154
YT008154
YT007152
YT002152
YT000153
XT997152
XT991149
XT989150
YT007151
YT009151
YT008147
YT009144
YT007140
YT005140
*
�UNCLASSIFIED
BIEN HCA
************
TYP
LEG
GALS
3G
0
3H
0
3J
0
r"
1A
6000
IB
0
7000
D
1A
0
IB
IA
2500
D
IB
0
D
1A
5000
0
IB
1A
r
8000
0
IB
F
3355
1A
D
8000
1A
0
IB
P
770
1A
IB
0
0
1C
0
ID
D
1A
7000
0
IB
0
2A
0
2B
8000
D
1A
0
IB
2A
0
0
2B
D
1A
3000
0
IB
2A
0
:
0
28
6000
D
1A
0
IB
0
2A
0
26
P
4675
1A
3000
D
1A
0
IB
0
1C
0
ID
6000
D
1A
0
IB
0
2A
0
2B
5100
r
1A
0
IB
0
1C
0
ID
p
1500
1A
PROV NO.
MISSIOMS STARTING IN
DATE
690207
690207
690207
690212
690212
690215
690215
690222
690222
690320
690320
690326
690326
690330
690331
690331
690410
690410
690410
690410
690510
690510
690510
'690510
690520
690520
690520
690520
590526
690528
690528
690528
690609
690609
690609
690609
690613
690617
690617
690617
690617
690626
690626
690626
690626
690627
690627
690627
690627
690709
AGN
H
n
W
W
G
W
W
o
f>
9
0
0
0
0
o
0
n
UTM
YT006142
YT006145
YT005148
XT257065
X TO 1006 5
YT130293
XT970293
YS318786
YS318883
YT130325
YT000325
YT130337
YT000337
YT080070
YT130329
XT000327
YT071050
YT090060
YT099070
YT097076
YS258777
YS258855
YS263777
YS263890
YT177264
YT177170
YT183264
YT183170
YT256194
YT130194
YT163232
YT163180
YT190167
YT195264
YT158220
YT161175
YT050080
YS307730
YS3C7880
YS338882
YS338810
YS310783
YS310831
YS315785
YS315882
YS298620
YS298890
YS294820
YS2S6990
YT11C040
26
�DATE
690709
690709
690709
690713
690713
690713
690713
690812
690812
690812
690812
690813
690813
690813
690816
690816
690816
690821
690821
690821
690821
690822
690R22
690822
690822
690822
690822
690822
690822
690822
690822
690822
690824
690824
690824
690827
690827
690827
690827
690830
690830
690831
690831
690831
690831
690831
690831
690901
690901
690920
&GN
Q
0
0
0
n
0
0
0
n
0
n
0
0
G
GALS
0
0
0
4000
0
0
0
6000
0
0
0
6000
0
0
6000
0
0
11700
0
0
0
12000
0
0
0
0
0
1-2000
0
0
0
0
7000
0
0
4000
0
0
0
1500
0
2000
0
1900
0
0
0
4000
0
6000
TYP
D
D
D
D
D
D
D
n
c
LEG
IB
1C
10
1A
IB
2A
26
1A
IB
2A
2B
1A
IB
1C
1A
18
1C
1A
IB
2A
2B
1A
IB
2A
2B
3A
3B
1A
IB
2A
28
2C
1A
IB
1C
1A
IB
D
2A
2B
1A
IB
1A
18
IA
IB
2A
2B
1A
r
IB
1A
D
C
n
UTM
YT130040
YT110050
YT130050
YT070256
XT984304
YT070258
XT985308
YT077250
XT983299
XT962292
YT070241
YT134268
YT073268
XT967318
YT142279
YT076279
YT988328
YS312783
YS312882
YS33480a
YS334882
YT132262
YT070262
XT985313
XT987323
YT142274
YT074274
YS253790
YS330835
YS330807
YS253777
YS277776
YT151284
YT077284
XT990335
YS341819
YS341881
YS333806
YS333882
YS249815
YS330862
YT070232
XT980282
YS246849
YS306883
YS301873
YS247845
YS265802
YS345&47
YS24P835
1
�UNCLASSIFIED
PROV NO.
MISSIONS
DATE
690920
690920
690920
691129
691129 '
691129
691129
691129
691129
691201
691201
691201
691201
691204
691204
691204
691207
691207
700123
700123
700123
700123
700123
700123
700215
700215
700215
700215
700220
700220
700220
700220
700220
700326
700403
700403
700403
700403
IG
STARTING IN
AGN
0
W
0
0
BIEN HOA
!:$
**********^ LEG
GALS
TYP
IB
0
2ft
0
2B
0
1A
3700
D
IB
0
2A
0
2B
0
3A
0
3B
0
1A
4000
P
IB
0
2A
0
2B
0
1A
3600 '
D
18
0
1C
0
1A
3600
D
IB
0
3000
0
1*
IB
0
2A
0
28
0
3A
0
38
0
1A
2800
D
IB
0
1C
0
ID
0
1A
2800
D
IB
0
1C
0
2A
0
26
0
1A
100
S
1A
2000
D
IB
0
2A
0
2B
0
UTM
YS315S74
YS330875
YS248829
YS030772
YS090772
YS090769
YS030775
YS043782
YS090782
YS088737
YS178742
XS993740
YS088737
YS193737
YS092739
YS093736
YS207768
YS066768
YS188729
YS110729
YS115726
YS180726
YS180723
YS123723
YS190747
YS090747
YS106732
YS196732
YS208765
YS125765
YS0657TO
YS072762
YS206763
YT004180
YS189759
YS079757
YS080755
YS186757
26
�UNCLASSIFIED
NREC= 17402
NREC= 17402
NPROV=
NPROV=
237
237
NZREC=
NZREC=
501
501
UNCLiSSIFIEO
UNCLASSIFI.10
�D£Tc
651110
651110
651110
651110
651218
651218
651218
651218
651223
651223
651223
651223
651227
651227
651227
651227
651230
651230
651230
651230
660101
660101
660101
660101
660102
660102
660103
660103
66O104
660104
660113
660118
660207
660207
660226
660226
660311
660311
660314
660314
660412
660412
660412
660412
660412
660412
600412
660412
660605
660605
AGN
o0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
n
0
0
n
GALS
1500
0
2650
0
2350
0
3500
0
2000
0
1000
0
3000
0
3000
0
2000
0
3000
0
2000
0
2000
0
2000
0
2900
0
2000
0
2250
0
2000
0
1000
0
2000
0
2000
0
2000
0
0
0
2000
0
0
0
4000
0
TYP
C
C
D
D
D
D
D
D
D
0
D
D
n
D
D
n
D
D
D
r
n
n
r
LEG
1A
IB
IA
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
1A
13
1A
IB
1A
2A
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
10
14
18
1C
ID
1A
13
UTM
YS350780
YS720760
YS350780
YS720760
YS590613
YS530598
YS590613
YS530598
YS235785
YS290628
YS230785
YS235755
YS590610
YS530600
YS460483
YS425566
YS240785
YS295628
YS430569
YS4-70483
YS240780
YS290630
YS430570
YS470480
YS257744
YS295630
YS600605
YS465485
YS240780
YS290630
YS590607
YS530595
YS308515
YS298496
YS308515
YS298495
YS470500
YS460560
YS470485
YS495515
YS353672
YS340620
YS324623
YS302632
YS450575
YS456557
YS481513
YS490531
YS480520
YS440560
�MISSIONS STARTING IN
D4TF
660605
660607
660607
660620
660620
660630
660630
660630
660630
660630
660802
660802
660802
660802
660908
660908
661124
661124
661129
661129
661129
661129
661202
661202
661202
661204
661204
670113
670113
670120
670120
670125
670125
670126
670126
670126
670126
670130
670130
670130
670130
670203
670203
670205
670205
670213 670213
670214
670214
670214
AGN
n
0
0
0
0
0
0
0
0
0
0
0
w
0
0
w
0
0
0
n
G
0
PHUOC TUY
************
TYP
GALS
LEG
0
1C
n
4000
1A
0
IB
1600
D
1A
0
IB
D
4000
1A
0
IB
0
2A
0
28
0
2C
1350
D .
1A
0
IB
D
2000
1A
0
IB
0
1000
1A
0
IB
1100
C
1A
0
IB
D
3600
1A
0
IB
0
2A
0
28
2700
D
1A
0
IB
0
1C
2700
C
1A
0
IB
n
1800
1A
0
IB
D
2700
IA
0
IB
1300
C
1A
0
IB
2700
C
1A
0
IB
1600
C
1A
0
IB
D
1300
1A
0
IB
1800
D
1A
0
IB
2700
D
1A
0
IB
1800
D
1A
0
IB
n
2700
1A
0
18
2100
D
l.S
0
IB
2700
D
IA
UTM
YS450520
YS450550
YS490520
YS432566
YS467484
YS465482
YS43-1568
YS456526
YS463539
YS475516
YS323525
YS345560
YS351522
YS320524
YS320530
YS352555
YS670590
YS610615
YS390720
YS315767
YS365730
YS365790
YS430790
YS380710
YS300790
YS3 90850
YSS90810
YS762658
YS649584
YS615851
YS695851
YS616880
YS738880
YS790660
YS650580
YS340730
YS340790
YS740900
YS610900
YS630790
YS790800
YS365730
YS365790
YS632820
YS770820
YS616853
YS616800
YS570532
YS523340
YS638740
�D4TF
670214
673214
670214
670215
670215
670215
670215
670215
670216
670216
673216
670218
670213
670218
670218
670220
670220
670310
670310
670310
670310
670310
670310
670323
670323
670323
670323
670323
670323
670323
670323
670323
670323
670323
670323.
670328
670328
670331
670331
670401
670401
670401
670401
670404
670404
670404
670404
670406
670403
670821
AGN
Q
0
0
a
0
0
3
B
0
H
GALS
0
0
0
2700
0
0
0
0
1800
0
0
2700
0
2400
0
2500
0
1800
0
900
0
1800
0
2700
0
0
0
2700
0
0
o -•
0
5100
0
0
0
2790
0
2790
0
2790
0
0
0
2790
0
0
'0
2790
0
2000
TYP
D
D
0
.
D
D
D
D
D
D
D
• ~D
0
•
0
0
0
a
0
D
D
D
D
D
D
LEG
IB
2A
23
1A
IB
2A
2B
2C
1A
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
1A
13
1A
IB
1A
IB
2A
2B
1A
IB
2A
28
1A
18
2A
2B
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
24
• 26
1A
IB
1A
UTM
YS798740
YS630850
YS790850
YS717617
YS766648
YS718613
YS753617
YS771639
YS677850
YS727820
YS357S20
YS794880
YS615880
YS780700
YS917765
YS633788
YS7917B8
YS737898
YS616398
YS737898
YS616398
YS820836
YS630847
YS380850
YS330810
YS350850
YS355810
YS380850
YS380810
YS350850
YS355810
YS330790
YS390790
YS346805
YS3 90805
YS820810
YS630810
YS751665
YS926747
YS520840
YS580840
YS520850
YS580350
YS520810
YS580810
YS520830
YS580830
YS580820
YS520620
YS800822
'
�DAT F
670821
670821
670821
670822
670822
670623
670823
670824
670824
670824
670824
670902
670902
670912
670912
670925
670925
670926
670926
670927
670927
670929
670929
671002
671002
671026
671026
671030
671030
680109
680109
680109
680109
680109
680109
680109
680110
680110
680112
680112
660112
630112
630128
68012S
680128
680123
680126
680128
630128
680129
0
GALS
0
5000
0
3000
0
3000
0
3000
0
1000
0
1850
0
3000
0
2950
0
5700
0
5700
0
2725
0
3000
0
4850
0
3400
0
4400
0
0
0
0
0
0
5950
0
6000
0
3000
0
4000
0
0
3000
W
4000
ASM
W
0
n
W
0
W
0
0
0
W
0
n
n
w
w
w
w
w
0
TYP
r
r
n
D
0
r
D
r
0
r
D
D
0
D
D
D
D
D
D
18
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
2A
26
3A
33
1A
18
1A
IB
1A
IB
1A
IB
0
D
IB
1A
0
4000
1A
1C
1A
IB
It
D
0
W
LEG
IB
UTM
YS633349
YS800822
YS633849
YS800834
YS640838
YS806752
YS633752
YS805800
YS670798
YS805800
YS670798
YS805779
YS633779
YS816748
YS633748
YS790759
YS615759
YS363660
YS363840
YS585870
YS585800
YS800823
YS863823
YS796747
YS634747
YS803308
YS632807
YS287710
YS287780
YS270732
YS285733
YS339813
YS294730
YS310730
YS325754
YS326794
YS575896
YS575800
YS595898
YS595800
YS475504
YS433571
YS813692
YS752616
YS678590
YS8007B5
YS632786
YS800785
YS632786
YS48050U
>
�MISSIONS STAR!
riNG IN
DATE
680 139
680317
680317
680320
680330
680320
680320
680322
630322
680322
680331
680331
680406
680406
680413
630413
680413
630413
680422
680422
680422
680422
680430
680430
680506
680506
680512
680512
680513
680513
630516
680516
680513
680518
630521
680521
680526
680526
680526
680526
680527
6B0527
680527
680527
680528
6S0526
680530
680530
680608
03060S
A UN
W
W
W
W
0
1-J
A
0
W
W
W
0
W
W
W
W
W
W
W
Q
'
PHUOC TUY
***.#**#*****
TYP
LEG
GALS
0
IB
1A
6000
D
0
IB
1A
6000
n
0
IB
0
1C
0
ID
3600
r
IA
0
IB
0
1C
6000
D
1A
0
IB
3000
D
1A
0
IB
3000
D
1A
0
IB
2300
D
1A
0
IB
5650
D
1A
0
IB
0
2A
0
2B
5000
P
1A
0
IB
6000
0
1A
0
IB
3000
D
1A
0
IB
5000
B
1A
0
13
2750
D
1A
0
18
2800
D
1A
0
IB
D
6000
1A
0
IB
6000
D
1A
0
IB
0
2A
0
2B
3000
D
1A
0
IB
0
2A
0
2B
6COO
r
if0
IB
2000
0
1A
0
IB
3000
D
1A
0
IB
UTM
YS440572
YS605886
YS605800
YS252778
YS252857
YS232838
YS304898
YS288780
YS236870
YS330904
YS800827
YS232323
YS272690
YS272775
YS744628
YS561595
YS614890
YS614800
YS756618
YS710616
YS677587
YS598583
YS810742
YS004505
YS790685
YS633620
YS180755
XS998755
YS780882
YS615882
YS752852
YS605852
YS610892
YS619898
YS755683
YS591598
YS626900
YS626300
YS637800
YS637S70
YS633800
YS638B73
YS623900
Y5623800
YS357664
YS357830
YS811698
YST50627
YS301706
YS301370
�UNCLASSIFIED
MISSIONS STARTING IN
C
D4T
680613
&80613
630618
680618
630620
630620
680620
680620
630620
630620
680623
680623
680624
680624
680625
680625
680625
680627
&80627
630630
680630
680630
680630
AGM
0
Q
W
,1
ft
W
0
M
i4
PHUOC TUY
************
TYP
GALS
LfG
3000
1A
D
0
IB
5000
r
1A
0
IB
6000
D
1A
0
IB
0
2A
0 .
2B
5000
C
1A
0
18
5000
P
1A
0
IB
2900
1A
D
0
IB
5675
D
1A
0
IB
0
1C
6000
1A
D
0
IB
n
4500
1A
0
IB
0
2A
0
2B
PRQV N O . = 2 7
UTM
YS780680
YS640628
YS611588
YS690619
YS282687
YS282774
YS278687
YS278774
YS333675
YS330855
YS352651
YS352802
YS 75663 5
YS601596
YS312628
YS274688
YS274744
YS349680
YS342836
YS750625
YS703623
YS678592
YS640591
UNCLASSIFIED
�NREC= 17867
NREC= 17867
NPRQV=
NPP.OV=
113
113
NZREC=
NZR3C=
160
160
UNCLASSIFIED
UNCLASSIFIED
�M I S S I O N S S T A R T I N G IH
LONG AN
AGN
0
TYP
D
GATE
651126
651126
651126
651126
651206
651206
651222
651222
660724
660724
660729
660729
660729
670714
670714
670714
670714
671010
671010
671114
671114
671116
671116
671118
671118
671121
67U21
671204
671204
671206
671206
680810
680810
680810
630912
630912
690918
680918
630918
690310
690310
690315
6S0321
690321
690321
690321
690323
690323
690323
690605
0
0
0
0
w
n
0
w
0
w
w
0
0
0
0
0
W
n
n
w
0
GALS
4100
0
0
0
4000
0
3000
0
2950
0
1600
0
0
750
0
2000
0
3000
0
3750
0
8000
0
3900
0
3900
0
2400
0
3000
0
6000
0
0
5000
0
5000
0
0
8000
0
400
•3000
0
0
0
8000
0
0
5000
n
D
C
C
D
0
0
D
P
D
D
P
0
D
D
n
*
r>
s
D
D
C
P R C V NO. = 28
L. , G
1A
IB
2ft
2B
1A
18
1A
IB
1A
16
1A
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
13
1C
1A
IB
11
18
1C
1A
IB
1A
14
13
2A
23
1A
IB
1C
1A
UTM
XS510970
XS525945
XS565933
XS557810
XS550300
XS560935
XS55.7800
XS460985
X S3 50820
XS400790
XS352830
XS350810
X S3 7878 8
XS399913
XS505776
XS399913
XS505776
XS467718
XS351815
XS549890
XT464014
XS346887
XS486985
XS589789
XS575928
XS559920
XT463012
XS468720
XS351317
XS349835
XS49898S
XS480782
XS399840
XS372902
XS480775
XS360390
XS480773
XS368884
XS358875
y
S493 T97
XS392917
XS560940
XS480748
XS428770
XS368317
^5352874
XS568777
XS550811
"S541927
•"S560773
�UNCLASSIFIED
M1SSKiN'S STARTING IN
OUT*
690605
690605
690608
690608
690608
690606
690613
090613
690613
690614
690614
690614
690615
690615
690615
690615
690622
690622
690622
690623
690623
690623
690626
690626
690629
690629
690629
690629
690629
690629
700213
700213
AGN
0
0
0
0
0
0
0
0
n
Q
LONG AN
************
TYP
LEG
G6LS
IB
0
0
1C
4400
C
1A
0
IB
0
24
0
2B
4000
D
1A
0
IB
0
1C
1A
4000
C
0
IB
0
1C
3000
D
1A
0
IB
0
1C
0
10
6000
D
1A
0
IB
0
1C
5800
r<
1A
0
18
0
1C
6000
D
1A
0
IB
6000
D
1A
0
18
0
1C
6000
D
1A
0
IB
0
1C
440
S
1A
0
IB
PROV
HTM
XS543810
XS533929
XS480742
XS429764
XS362811
XS349862
XS480767
XS379828
XS363893
XS556778
XS539807
XS528933
XS480772
XS440794
XS382830
XS364894
XS539780
XS525804
XS514928
XS553781
XS540806
XS528933
XS502781
XS389914
XS480775
XS384835
8S373902
XS 54 7780
XS535802
XS523935
XS565928
XT463018
UNCLASSIFIED
NO.
28
�NPEC= 18053
NREC= 18058
NPROV=
32
32
NZRcC=
NZREC=
50
50
UNCLASSIFIED
UNCLASSIFIED
�MISSIONS
DATE
660105
660105
660105
660105
660106
660106
660107
660107
660107
660107
660108
660108.
660108
660106
660110
660110
660111
660111
660111
660111
660114
660114
660114
660114
660116
660116
660116
660116
660117
660117
660118
660116
660127
660127
660127
660128
660128
660129
660129
660125
660205
660205
660207
560207
660222
660308
660308
660709
660709
660709
STARTING
AGN
IN
n
GALS
2000
0
2000
0
1000
TYP
LEG
D
1A
0
r
0
D
0
0
2000
D
0
0
2000
0
0
2000
p
r-
0
0
3000
0
0
0
2000
D
0
0
3000
D
0
•J
3000
0
0
1800
D
r
0
0
n
1800
0
0
2000
D
0
0
1000
0
0
0
2000
D
0
0
1900
D
0
0
1800
2000
D
0
0
4000
D
0
0
rj
2000
D
0
0
1700
D
0
0
0
1000
1QOO
n
4000
D
n
0
0
0
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1ft
IB
UTM
-
YS130585
YS040650
YS040650
YS030750
YS150580
YS150630
YS150640
YS035675
YS035675
YS000740
YS115580
YS025640
YS025640
YS000760
YS120580
YS020660
YS025665
YS000750
YS120580
YS020655
YS135580
YSO 00760
YS000760
YS135580
YS023658
YSO00748
YS137580
YS020697
YS115530
YS020655
YS015657
YS000741
D
0
0
n
j
PROV NO. = 29
GIS OINH
C
10
11
1A
IB
1A
IB
2A
1A
IB
1A
18
1A
1A
IB
1A
IB
2A
YS150580
YS120660
YS090650
YS150580
YS152600
YS060800
YS147570
YS155570
YS120660
XS925695
XS930600
VS 92 069 5
YS155570
YS120660
YS100510
YS078482
YS115490
�UNCLASSIFIED
MISSIONS
OATF
56J70S
660726
660726
661121
661121
661130
661130
661130
661130
661202
661202
661202
661202
661204
661204
661217
661217
661219
661219
661219
661219
661220
661220
661220
661220
661223
661223
661223
661223
661223
661223
670102
670102
670103
670103
670104
670104
670106
670106
670106
670106
670106
670106
670107
670107
670107
670107
670115
670115
670120
STARTING
AGN
0
n
W
W
W
n
w
0
0
p,
B
n
0
0
3
PROV NO. = 29
IN
GALS
0
2000
0
2700
0
3600
0
2225
0
2700
0
0
0
3600
0
5400
0
2700
0
0
0
3600
0
0
0
2700
0
2700
0
0
0
3600
0
3600
0
3600
0
3600
TYP
r
C
D
D
D
D
p
D
r
D
D
p
D
D
IB
D
0
3
B
0
W
0
*
0
3600
0
3600
0
2700
0
3600
0
2700
0
1800
LEG
2B
1A
13
1A
IB
1A
IB
1A
IB
1A
IB
2A
28
1£
•. 16
1A
IB
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
D
D
1A
IB
1A
IB
14
IB
D
IA
IB
D
1A
IB
1A
IB
1A
n
0
UTM
YS092478
YS106497
YS0854?5
YS175673
XS995679
YS050510
YS050680
YS148527
YS000510
YS168600
XS982600
YS005572
YS102574
YS175668
YS000676
YS170600
YS050600
YS132542
YS050547
YS050527
YS150527
YS157570
YS062570
YS047543
YS101543
YS200640
XS986640
YS160590
YS160570
YS050590
YS050510
YS010680
YS010510
YS130530
YS060510
YS1 75665
YS032665
XS970680
YS025500
XS995680
XS995510
YS020670
YS022510
YS035648
YS035540
YS170610
YS050610
XS989517
XS9 84643
XS933692
�UNCLASSIFIED
MISSIONS STARTING IN
OATH
670120
670121
670121
670121
670122
670122
670122
670122
670123
670123
670123
670123
670124
670124
670124
670124
670125
670125
670126
670126
670126
670126
670127
670127
670127
670127
670128
670128
670128
670128
670129
670129
670131
670131
670201
670201
670203
670203
670203
670204
670204
670204
670204
670205
670205
670205
670205
670219
670219
670219
AGN
0
W
•j
0
0
p
3
W
0
o
0
0
0
0
0
n
0
0
G
0
GALS
0
2700
0
0
2700
0
2700
0
2700
0
2700
0
2700
0
2700
0
2700
0
2700
0
0
0
2700
0
2700
0
2700
0
2210
0
2700
0
2700
0
2700
0
1800
0
0
2700
0
0
0
2700
0
0
0
2700
0
0
PROV NO.
TYP
LFG
13
r
1A
IB
1C
D
1A
IB
1A
1R
p
D
0
D
D
C
D
D
D
D
r
D
n
p
0
n
D
0
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
28
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
lA
IB
1A
IB
1A
IB
1C
1A
IB
2A
23
1A
IB
2A
2B
1A
IB
2A
UTM
XS938603
YS000760
XS970680
XS980526
YS180640
YS110640
YS04.0750
YS020510
YS110640
YS030650
YS180620
YS040620
YS1 70660
YS130660
YS200633
YS040633
XS960690
XS960540
YS070750
YS035677
YS045645
YS045560
YS050753
YS026510
XS970680
XS970530
YS027756
XS990600
XS990620
XS980530
YS020760
YS080520
XS945688
XS945590
YS050753
YS017680
YS002760
XS977687
YS014753
YS028757
XS995679
YS042754
YS006679
YS120575
YS065575
YS050520
YS065524
YS023756
>'S987540
XS986660
29
�UNCLASSIFIED
MISSIONS STARTING If!
PROV NO.
GIA DINH
**•**•* 4 ib"****
DATE
670219
670220
&70220
670301
670301
t,70311
670311
670312
670312
670312
670313
670313
6 7031 S
670318
670320
670320
670320
670320
670320
670330
670330
670410
670410
670410
670612
670612
670612
670614
670614
670617
670617
670623
670623
670623
670623
670624
670624
670624
670624
670627
670627
670628
670628
670628
670626
670630
670630
670630
670630
670708
AGN
0
0
0
C
0
0
0
0
W
0
0
W
0
0
0
0
0
0
'vi
TYP
GALS
0
D
27CO
0
C
2700
0
2700
0.
0
2700
0
0
0
0
P
2700
0
.r
2100
0
0
0
0
. D
2790
0
c
2790
0
0
r
1700
' 0
0
D
1860
0
D
I860
0
D
1785
0 .
900
•„ , .. „ D
0
D
I860
0
D
5580
0
C
4650
0
D
2790
0
0
0
0
6055
0
0
0
r
2000
LEG
2B
1A
IB
IA
IB
1A
IB
1A
IB
1C
2A
2B
IA
IB
1A
IB
1C
ID
IE
1A
IB
1A
IB
1C
1A
IB
1C
1A
• 18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
it
IB
1A
18
26
2B
1A
IB
2A
23
1A
UTM
XS9C9547
XS960680
>S960540
XS920690
XS950590
YS070750
YS020660
XS920690
XS960550
XS960690
5S640432
NS6 4520
YS020750
YS000520
YS060500
YSO&0560
YS120560
YS050570
Y5 040600
YS062565
YS123565
YS014758
XS980670
XS983600
XS950660
XS980550
YS050560
YS070580
YS110660
YS050707
YS054677
YS049502
YS134602
YSC49502
YS134602
YS132626
YS053626
YS140535
YS050535
YS145527
XS977529
YS060&40
YS060570
XS960600
XS990680
YS133623
YS050623
YS133613
YS054613
YS046583
/
/
'
>
25
�Git DINH
^ ** a********
TYP
LEG
GALS
IB
0
1A
0
3000
IB
0
P;
1A
3000
IB
0
r
1A
2950
IB
0
D
4850
1A
IB
0
1A
800
D
IB
0
0
1C
1A
20CO
C
IB
0
D
1A
3950
0
IB
2A
0
2B
0
D
1A
5200
IB
0
1A
1000
D
0
IB
1A
2000
D
0
IB
1A
2900
D'
0
IB
5930
0
1A
IB
0
4600
D
1A
0
IB
D
1A
3000
IB
0
1A
3000
D
IB
0.
D
4650
IA
0
18
D
1A
1500
IB
0
1A
6950
D
0
IB
D
1A
7800
0
IB
4900
D
1A
0
IB
7500
C
1A
0
IB
7550
D
1A
0
IB
6700
D
1A
0
18
MISSIONS START ING IN
DATF
670708
670710
670710
670802
670802
670802
670802
67080T
670809
670809
670809
670809
670821
670821
670829 .
670829
670829
670829
670831
670831
670904
670904
670904
670904
670910
670910
670912
670912
670914
670914
670915
670915
670916
670916
670925
670925
671010
671010
671016
671016
671025
671025
671025
671025
671026
671026
671108
671108
671111
671111
AGN
0
W
0
0
W
W
0
0
w
0
0
0
0
0
G
w
0
w
0
0
n
0
0
•
UTM
YS120532
YS123553
YS058553
YS133622
YS950612
YS133622
YS950612
YS136598
XS950597
XS994762
YS038748
YS040705
YS175626
XS988628
YS050770
YS050660
YS000660
XS990760
YS178637
YS010637
YS115659
XS945659
YS115659
XS945659
YS150648
XS960648
YS164594
YS970602
YS158578
XS967578
YS134608
XS952609
YS178642
XS925642
YS082672
XS918675
YS125548
YS980548
YS176633
YS966578
YS164645
XS955645
YS162589
YS979593
YS009663
XS923660
YS145654
YS967650
YS123656
XS923656
1
�UNCLASSIFIED
GIA DINH
************
LEG
TYP
G4LS
1A
r
4000
IB
0
1A
r
2450
IB
0
IA
0
3300
IB
0
1A
D
4000
0
IB
1A
D
8000
IB
0
1A
C
4000
IB
0
1A
D
2800
IB
0
1A
D
1550
IB
0
1A
C
2930
IB
0
1A
D
6800
IB
0
D
1A
2500
0
IB
1A
D
5650
IB
0
1A
6000
C
IB
0
1A
2725
D
IB
0
IA
0
1000
IB
0
IA
1000
D
0
IB
3000
D
1A
0
IB
2A
0
2B
0
IA
3000
D
0
18
1A
6000
D
0
IB
n
6000
IA
0
IB
n
3000
1A
0
IB
8550
D
1A
0
IB
n
6275
1A
J
IB
D
6000
IA
0
13
PROV NO. = 29
MISSIONS START ING IN
DATE
671111
671111
671111
671111
671112
671112
671114
671114
671115
671115
671117
671117
671126
671126
671205
671205
671209
671209
671211
671211
671215
671215
671215
671215
671217
671217
671219
671219
671220
671220
671220
671220
671220
671220
671220
671220
671221
671221
671221
671221
671222
671222
671223
671223
671224
671224
671226
671226
671228
671226
4GN
0
Q
0
w
Q
n
0
W
0
0
0
Q
W
0
W
0
0
0
0
0
0
0
0
0
UTM
YS018690
YS018525
YS085669
XS923664
YS137522
XS990518
YS16.0588
XS950543
XS987690
XS987520
YS011690
YS011530
VS991690
XS991516
YSU1588
XS960589
XS7U691
XS971533
YS000680
YS000504
YS177712
YS020712
YS173723
XS998723
YS167679
XS965633
YS175703
YS0147G3
YS180734
XS998734
YS180734
XS998734
YS168689
YS070689
YS058689
XS957689
YS180729
YS000729
YS175673
YS970676
YS167634
XS972685
YS022668
YS022498
YS025690
YS025502
XS976687
XS976530
XS9fcl690
XS980525
�UNCLASSIFIED
MISSIONS STARTING IN
04Tt
671229
671229
6B0103
680103
680103
680 103
680103
680103
660106
680106
680113
6801 13
680115
6SO 115
630116
630116
630117
630117
680118
680118
630120
680120
630120
680120
680124
630124
680124
630124
680124
680124
630124
6S0124
680125
680125
680125
660125
68012&
680126
680324
680324
680325
680325
680326
630326
680327
680327
630327
6803Z7
680327
630327
AGN
0
«
W
0
0
W
0
0
0
0
0
0
rf
GALS
3000
0
6000
0
1000
0
2000
0
2000
0
5600
0
3000
0
3000
0
5900
0
3000
0
4900
0
12000
0
7400
0
0
TYP
D
D
0
0
P
D
0
P
0
D
D
:
D
D
0
0
0
0
W
W
W
W
W
PROV NO.
GIA DINH
2800
C
0
0
0
4000
0
0
0
0
8000
D
0
5500
D
0
2950
D
0 '
V
5500 '"" P
0
5775
D
0
3ck>o
0
0
0
r
LEG
1A
IB
1A
IB
14
18
1A
IB
1A
IB
1A
13
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
IA
IB
2A
2B
1A
IB
2A
2B
1A
13
1A
18
U
18
1A
IB
1A
13
14
18
2A
2B
(JTM
YS170692
YS000692
YS180743
XS990743
YS180726
YS000726
YS 18.0 726
YS000726
YS004690
YS004510
YS175701
YS000701
YS009&72
YS009500
YS170694
YS000692
XS996690
XS9S6513
YS015650
YS016492
YS130544
YS050544
YS175665
XS973666
YS158573
XS980575
YS177715
XS998715
YS158573
XS980575
YS177715
XS998715
YS1 74660
YS118660
YS115654
YS173650
YS180732
XS998732
YS180708
YS003709
YS171696
YS000694
YS180747
XS995747
YS175717
XS990717
XS940600
XS937670
XS960670
XS961600
/
f?
f
29
�DiTF
680327
630327
680327
680327
680328
680328
680328
680328
630329
630329
680329
630329
680329
630329
680401
680401
680403
680403
680*06
680406
680406
680406
680406
680406 '
680406
680406
680415
680415
680425
680425
680425
680427
680427
680504
680504
680608
680608
680620
680620
680623
680623
680630
680630
680630
680630
680701
680701
680701
680701
680701
AGN
W
W
W
w
w
w
w
0
w
n
w
w
w
0
0
B
3
W
0
GALS
3000
0
0
0
3000
0
0
0
3000
0
0
0
4000
0
3000
0
6000
0
1000
0
0
0
5000
0
0
0
5000
0
6000
0
0
3000
0
5950
0
3000
0
2000
0
3000
0
2000
0
2350
0
6000
'• 0
3000
0
0
TYP
n
p
D
D
D
D
D
D
0
D
D
n'
D
. D
D
D
D
D
r>
LEG
IA
IB
2A
2B
1A
18
2A
2B
1A
IB
2A
2B
1A
IB
1A
IB
1A
18
1A
IB
2A
2B
IA
IB
2A
2B
1A
IB
1A
IB
1C
1A
IB
1A
18
1A
IB
1A
IB
1A
18
1A
IB
IA
IB
1A
IB
1A
IB
24
UTM
XS969690
XS969604
XS928600
XS914690
XS948689
XS949603
XS 9 . 6 3
480
XS946688
XS946687
XS946600
XS937600
XS934689
XS955690
XS954600
XS945688
XS945600
YS173703
YS000703
XS963690
XS957600
XS933604
XS933690
XS963690
XS957600
XS933604
XS933690
YS180708
XS998708
YS137524
XS990524
XS970555
YS159582
XS970591
YS004670
YS004505
YS100512
YS000509
YS158576
XS970576
YS149519
YS064485
YS120717
YS130590
YS110697
YS142622
YS168688
YS000692
YS120515
YS010511
YS010514
t
�DATE
680701
680705
680705
680706
680706
680706
680706
680711
680711
680711
680712
680712
680713
630713
680715
680715
680715
680715
680719
680719
680720
680720
680720
680720
630720
680720
630721
680721
630726
680726
680730
680730
680S03
680803
680803
630803
680804
680804
680804
630804
680807
680807
680807
680807
680807
630807
630809
68080?
680809
680809
AGN
n
0
0
W
w
W
0
w
w
3
'fi
w
w
w
w
a
0
B
3
0
w
w
GALS
0
5000
0
6000
0
0
0
3000
0
0
6000
0
5000
0
5850
0
4000
0
2000
0
2000
0
3000
0
0
0
3000
0
2000
0
3000
0
3000
0
3000
0
5000
0
5000
0
2000
0
300.0
0
5000
0
30'OO
0
3000
0
TYP
D
r
c
D
p
D
D
D
D
0
D
D
C
D
D
D
D
. D
r
r
D
r
LEG
2B
1A
IB
1A
IB
2A
2B
1A
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
23
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IP
1A
IB
UTM
YS120517
YS167682
YS000682
YS151526
YS061490
YS121518
YS061494
YS103640
YS010700
YZ040735
YS166602
XS985636
YS166602
YS985636
YS157681
XS9C7739
YS165606
XS989642
YS005670
YS026503
YS166613
YS000651
YS027505
YS043601
XS997608
YS015646
YS145695
YSOU5770
YS160614
XS946668
YS121618
XS956652
YS160626
VS944667
YS160615
VS980662
YS157624
XS960675
YS163609
XS975651
YS055482
YS055632
YS090634
YS002754
YS090630
XS972781
YS160620
VS943673
YS157639
XS9 70681
�UNCLASSIFIED
PROV NO.
MISS ICNS START ING IN
DATE
680809
680809
680810
680810
680810
680810
680813
680813
680813
630813
630813
680813
680814
680814
680814
680814
680815
680815
680815
680815
680817
680817
680820
680820
630823
680823
680824
680824
680827
680827
680828
630828
680828
680901
68Q901
630903
680903
680913
630913
6SOS13
630913
630913
1^80915
680915
690117
690117
690124
690124
690131
690131
AGN
W
n
0
B
B
0
0
T
0
0
0
w
w
B
3
0
W
W
W
0
0
w
H
GI* DINH
*:M**i! ******
GALS
L5G
TYP
n
1A
2000
IB
0
1A
4700
D
IB
0
2A
0
2B
0
1A
1525
D
IB
0
1A
3000
D
IB
0
1A
D
2150
IB
0
r;
1A
5025
IB
0
1A
5000
D
IB
0
1A
2000
D
IB
0
1A
2000
D
IB
0
0
1A
4500
IB
0
1A
3000
C
IB
0
3000
1A
D
IB
0
D
1A
3000
IB
0
1A
4000
D
0
IB
D
1A
3000
IB
0
1C
0
n
1A
3000
IB
0
1A
3000
C
IB
0
1A
3000
0
IB
0
1A
D
2800
IB
0
1C
0
1A
D
3000
IB
0
0
1A
3000
0
18
n
1A
9000
IB
0
1A
6400
D
0
1R
UTM
YS158635
*S980685
XS938620
XS986558
XS984558
XS967538
YS155643
XS981685
YS155570
YS156667
YS150567
XS953647
XS160636
XS984681
YS154647
XS9C5687
YS009735
YS033541
YS011735
YS035545
YS037735
YS066494
YS039734
YS063530
YS 004 69 5
YS025525
YS169692
YS028743
YS036551
XS947651
YS103640
YS010705
YS020742
YS008700
YS031520
YS011690
YS033520
YS010740
YS040500
YS018734
YS038560
YS025533
YS032736
YS601503
YS031526
XS92662 7
YS032503
XS927610
YS122555
YS049525
29
�UNCLASSIFIED
PROV NO. = 29
GIA DINH
MISSIONS STARTING IN
* * * * Ji-Jf * •
* * *
**
DATE
690131
690131
690205
690205
690206
690206
690216
690216
690414
690414
690507
690507
690507
690507
690516
690516
6^0516
690516
690525
690525
690525
690525
690721
690721
690730
690730
690730'
690730
690730
690730
690730
690E21
690822
691121
691121
691121
691121
691125
691125
691125
691125
&GN
W
0
0
n
GALS
0
0
4400
0
3000
0
8000
0
6000
TYP
n
D
r>
D
0
0
6000
D
0
0
0
0
9000
D
0
0
0
Q
7000
D
0
0
0
06000
C
0
0
:
2000
D
0
0
0
0
0
0
0
0
0
100
100
4000
F
P
P
0
0
0
0
4000
0
0
0
D
LEG
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1C
ID
1A
IB
1C
ID
1A
IB
2A
2B
1A
IB
IA
IB
1C
ID
2A
28
2C
1A
1A
1A
IB
2A
26
1A
IB
2A
2B
UTM
YS013494
XS946565
YS030540
XS940630
YS034544
XS933638
YS030535
XS926630
YS034518
XS927620
YS020760
YS020680
YS025762
YS033680
YS155527
YS061493
YS125542
YS055572
YS126543
YS051520
YS060499
YS140532
XS970718
YS147718
YS000731
YS030731
YS090740
YS090735
YS000729
YS000728
YS094728
XT056593
XT056593
XS985746
YS088738
XS984740
YS038738
XS953630
YS034552
YS030550
XS95062S
�NREC= 17599
NREC= 17599
NPPOV=
?^PROV=
229
229
NZREC=
NZR5C=
312
312
UNCLASSIPIliD
<-
*, %
"*'-*
�MISSIONS STARTING IN
VUNG TAU
PROV NO. = 95
* gk**.****-****
DAT?
AGN
GALS
TYP
LEG
UTM
UNCLASSIFIED
UNCLASSIFIED
�NREC= 18140
NREC= 181-tO
NPRQV=
NPROV=
0
0
-NZREC =
NZREC=
0
0
UNCLASSIFIED
�MISSIONS STARTING IN
DATT
«GN
' GALS
PROM NO.
SAIGON
TYP
LEG
UTM
UNCLASSIFIED
UNOLASSIFI-D
�NREC=
NREC=
18UO
18140
NPPOV=
NPROV=
0
0
NZREO
NZREC=
0
0
UNCL6SSI-1-0
�MISSIONS
DATE
680731
630731
68J731
680731
690418
690423
690505
STARTING IN
ASM
0
GALS
6000
0
0
0
875
840
1380
PROV NO. = 30
GO CONG'
TYP
C
LHG
1A
IB
2A
2B
1A
1A
IA
UTM
XS965309
XS979292
XS982296
XS930281
XS705405
XS720415
XS715405
UNCLASSIFI:0
UNCLASSIFIs'O
�NREC= 18133
NREC= 18133
NPROV=
f^PROV=
4 NZREC=
4 NEREC=
3
3
UNCLASSIFIED
UNCLASSIFIED
�DATE
670307
670307
670307
670307
670313
670313
670313
670313
670319
670319
670319
67031<=
670324
670324
670324
670324
670324
670329
670329
670329
670329
670329
670330
670330
670406
670406
670406
670406
670423
670423
670426
670426
670426
670426
670428
670428
670428
670428
670428
670428
680625
630625
680629
680629
680629
680629
680629
680629
680629
68062S
AGN
8
0
B
3
Q
0
0
W
w
w
GALS
2700
0
0
0
3600
0
900
0
2700
0
0
0
1800
0
0
0
0
3720
0
0
0
0
0
0
2600
0
0
0
2190
0
2630
0
0
0
2790
0
0
0
0
TYP
D
r
0
D
D
D
D
r
0
c
N
\
\
0
w
0
w
4850
0
1000
0
0
0
5000
0
0
0
r
D
r
LEG
1A
IB
2A
28
1A
IB
1A
IB
1A
IB
1C
ID
1A
IB
2A
2B
2C
1A
13
1C
ID
IE
2A
2B
1A
IB
1C
ID
1A
IB
1A
IB
2A
2B
1A
IB
2A
28
3A
3B
1A
18
1A
IB
1C
ID
1ft
IB
1C
10
UTM
XS170890
X.S160860
XS200840
XS110860
WT820010
WS370830
WT820010
• WS370830
XS160890
XS200830
XS200840
XS110860
WS77C990
WT820010
WS870940
WS910970
WS320970
WT790020
WS810970
WS870920
WS900950
WS860940
AT942864
AT947920
WS830990
WS880930
WS840970
WS900940
XS119686
XS001693
XS120680
XS100640
XS060640
XS080690
XS156653
XS100661
XS035645
XS036695
XS098678
XS080645
XS322691
XS201714
XS391692
XS330722
XS368779
XS408718
XS3S1692
XS330722
XS368779
XS408718
*
�MISSIONS START ING IN
DiTS
680708
680708
680706
630708
680712
680712
680714
680714
680714
680714
680722
680722
680722
680722
631021
681021
681021
681021
690115
690115
690125
690125
690125
690125
690203
690203
690203
690203
690205
690205
690207
690207
690207
690310
690310
690322
690322
690322
690324
690324
690324
690324
690405
690405
690409
690409
690409
AGN
H
0
W
0
8
0
W
0
H
A
W
0
0
0
0
KJEN TUONG
************
GALS
TYP
LEG
1A
5000
D
IB
0
EA
0
26
0
1A
4300
D
0
IB
1A
5800
0
0
IB
2A
0
2B
0
1A
4000
D
0
IB
2A
0
2B
0
5000
1A
0
0
18
0
2A
0
2B
1A
8000
c
0
IB
1A
6000
D
IB
0
2A
0
0
2B
6000
1A
P
0
IB
0
2A
0
2B
6000
D
1A
0
IB
6000
1A
D
0
IB
0
1C
8000
1A
C
0
IB
6000
D
1A
0
IB
0
1C
3000
1A
D
0
IB
0
2A
0
28
n
4000
1A
0
IB
6000
D
1A
0
IB
0
1C
UTH
XS362780
XS405714
XS342775
XS394696
XS323696
XS202718
XS351780
XS400705
XS337767
XS384693
X S3 5 8670
XS403710
XS336772
XS391693
XS348775
XS397700
XS375699
XS333762
HS900930
WT780000
XS198834
XS120860
XS220862
XS150888
XS200840
XS120870
XS220870
XS150890
WS890923
WT775005
WS920947
WS876947
WT78S009
KS883918
WT766001
WS867837
WS867918
WT807010
XS220853
XS150880
XS196826
XS164898
XS219839
XS150865
WS870860
WS870918
WT798010
�UNCLASSIFIED
NREC= 18043
NPRQV=
28
28
NZREC=
NZR£C=
69
69
UNCLASSIFIsL)
UNCL*SSIFIEO
�DATE
670606
670606
670606
670606
670611
670611
670909
670909
670912
670912
681122
681122
681122
681122
681201
681201
681201
681201
690414
690414
690414
690422
690422
690422
690422
690422
690422
690513
690513
690513
690513
690513
690513
690513
690513
690518
690518
690518
690518
690516
690518
690518
690518
690603
690603
691126
691126
691127
691127
691128
4GN
0
0
0
9
W
W
0
0
W
0
0
GALS
TYP
2590
T
0
0
0
2500
D
0
3000
P
0
1450
C
0
990
F
0
0
0
120
F
0
0
0
1595
S
0
0
645
S
0
0 .
405 v , _ S
0
0
990
W
0
0
0
0
0
0
0
715
S
0
0
0
0
0
W
0
B
?
PROV NO.
K1EN PHONG
MISSIONS STARTING
0
0
300
0
280
0
380
0
160
S
W
W
h
LEG
1A
IB
2A
2B
1A
16
1A
IB
1A
IB
1A
IB
1C
ID
1A
IB
1C
ID
1A
2A
3A
1A
2A
3A
1A
2A
3A
1A
IB
1C
ID
2A
2B
2C
20
1A
IB
1C
ID
2A
26
2C
2D
1A
IB
1A
IB
14
IB
1A
UTM
XS034617
WR978623
XS000650
WR990558
XS000630
WS912722
WS904710
XS000600
WS995622
WS909717
WS645643
WS700643
WS643638
WS700636
WS740642
WS836637
WS740635
WS836631
WS880740
WS855670
WS785555
WS720610
WS700670
WT620030
WS720610
WS700670
WT620030
WS740642
WS836637
WS740635
WS836631
WT585023
WT605040
WS628972
WS650986
WS545705
WS568745
WS575744
WS566704
WS480945
WS500945
WS480920
WS500920
*S633642
WS905630
WS776550.
WS783557
WS778550
WS790553
VJS974536
32
�0>».TE
691128
69112°
691129
691129
691129
691129
691129
700130
700130
700130
700130
700130
700130
7U0130
700130
700130
700130
700130
700130
700203
700203
700203
700203
700203
700203
700203
700203
700203
700203
700203
700203
700203
700203
700204
700204
700204
700204
700204
700204
700 20 -V
700204
700204
700204
AGN
3
W
GALS
0
450
0
0
0
0
0
1045
0
0
0
0
0
0
0
0
0
0
0
W
1155
0
0
0
0
0
0
0
0
W
0
0
0
0
0
880
0
0
0
. 0
0
0
0
0
0
LEG
IP
1A
IB
1C
ID
IE
IF
1ft
IB
2A
26
3A
38
4A
4B
5A
5B
6A
68
1A
IB
2A
2B
3A
3B
4A
4B
5A
53
6A
6B
7A
78
1A
IB
2A
2B
3A
38
4A
4B
5A
5B
UTM
WS906599
WS945563
WS973535
WS822485
WS831572
HS790552
WS800561
WS801568
WS826590
WS795560
WS826532
WS783558
WS810590
WS825500
WS831568
WS826500
WS832572
WS860547
WS892548
HS860543
WS890544
WS860542
WS890543
WS766573
WS765610
WS747595
WS765613
WS750662
HS757707
WS744670
WS749708
WS7 10680
WS723715
WS900544
WS937507
WS905546
WS935512
WS855546
WS900550
WS915591
WS950558
WS962546
WS935575
�cu
NKEC= 18047
N P E C = 18047
NPPOV=
NPROV=
19
19
NZREC=
NZR£C=
7<^
74
UNCLASSIFIED
UNCLASSIFIsO
�MISSIONS
D4T~
6S0816
630816
660816
680816
680816
680816
630816
680816
680816
680816
680816
680816
681007
661007
681009
690129
690129
690214
690214
690214
690214
690310
690310
690311
690311
690407
690408
690408
690406
690408
690408
690408
690408
690409
690409
690409
690409
690409
690409
690409
690415
690415
690418
690418
690516
690516
690516
690521
690619
690619
STARTING
AGN
W
W
W
W
W
W
tt
W
B
IN
TYP
GALS
P
990
0
0
0 •
0 "- ----0
0
0
0
0
0
0
c
540
0
P
275
130
S
0
950
s
0
0
0
250
s
0
130
s
0
650
s
365
s
0
0
0
B
W
M
W
0
0
0
600
0
0
0
0
0
0
975
0
385
0
1216
0
'•' o
H
0
825
440
0
PROV NO,
OIMH TUCNG
s
s
s
s
s
s
LEG
IA
18
2A
26
3A
3B
4A
48
5A
58
6A
68
1A
IB
1A
1A
IB
1A
IB
2A
2B
IA
IB
1A
IB
1A
1A
IB
1C
ID
IE
IF
1G
1A
IB
1C
ID
IE
IF
IG
1A
2A
1A
IB
1A
IB
1C
1A
1A
IB
UTM
XS425425
XS422455
XS429456
XS431425
XS410422
XS402455
XS40.9456
XS415422
XS409451
XS408456
XS422456
XS422451
XS480490
XS465455
XS415440
XS453445
XS468468
XS522460
XS522463
XS542463
XS540470
XS544458
XS557476
XS544458
XS557476
XS555472
XS571496
XS567482
XS580473
XS588475
XS588478
XS570482
XS575495
XS571496
XS567482
XS580473
XS588475
XS588478
XS570432
XS575495
XS450460
XS490490
XS470470
XS455450
XS472468
XS455448
XS445468
XS495-+95
XS472468
XS460452
I Mf. I
33
�UNCLASSIFIED
MISSIONS START IMG IN
DINH TUGNG
PROV NO.
* $ $ : * * *
* * * £ # *
DAT?
690619
690628
690628
690628
690628
690628
690628
69062S
690707
690/07
690707'
690707
690707
690707
690707
690707
690707
690707
690714
690714
690717
690717
690730
690730
690731
690731
690731
690731
690731
690731
691101
691101
691101
691105
691105
691105
691111
691111
691111
691111
AGN
n
0
0
0
0
0
0
0
0
69 1 1 1 1
691114
691114
691114
691114
691114
691114
691117
TYP
S
to
0
691111
691114
GALS
0
880
0
0
0
0
0
0
720
0
0
0
0
0
0
Q
0
0
0
700
0
1150
0
500
0
600
0
0
0
0
0
150
0
0
•350
0
0
600
0
0
0
0
0
550
0
0
0
0
0
0
300
fc
w
S
s
H
H
w
LEG
1C
1A
IB
1C
2A
2B
2C
20
1A
18
1C
10
IE
IF
1G
1H
11
U
1A
IB
1A
IB
1A
IB
1A
IB
1C
10
2A
28
1A
IB
1C
1A
IB
1C
1A
IB
1C
ID
ie
s
\
IF
1A
IB
1C
2A
2B
3A
s
3D
14
UTM
XS448466
XS472468
XS460452
XS448466
XS501503
XS492504
XS49Q492
XS476502
XS252443
XS303455
XS304437
XS261429
X S3 0445 8
XS337457
XS350446
XS350440
XS316426
XS3Q4430
XS193460
XS174405
XS260440
XS300448
XS200473
XS202490
XS211536
XS214523
XS180530
XS181550
XS158550
X.S168532
XS070530
XS090510
XS105520
XS060487
XS133506
XS130525
XS130500
XS080487
XS059465
XS045496
XS016440
WS996454
XS600425
XS640A14
XS680418
VS671430
XS651418
XS620434
VS625417
XS650430
33
�UNCLASSIFIED
MISSIONS
0*15
691117
691118
69111S
691118
691124
691124
691124
691124
691210
691210
591210
691210
691210
591212
700413
700413
700413
700413
STARTING
AGN
0
0
n
0
0
IN
GALS
0
280
0
0
450
0
0
0
400
0
0
0
0
250
400
0
0
0
OINH TUONG
TYP
fc
H
S
PRQV NO. = 33
LEG
IB
1A
IB
1C
1A
IB
2A
2B
1A
IB
2A
2B
2C
N
1A
W
1A
IB
2A
2B
UTM
XS671430
XS100641
XS100615
XS160612
XS100615
XS160612
XS252561
XS289577
XS600425
XS682418
XS672430
XS640414
XS605426
XS126503
XS199445
XS1?5459
XS308553
XS315528
11 Mr i .* c." T = i -11
�NREC=
NREC=
18022
18022
NPROV=
NPROV=
31
31
NZREC=
ftlRK=
87
87
UNCLASSIFI'D
�M I S S I O N S S T A R T I N G IN
D4TE
651207
651208
651208
651208
651208
651208
651208
6m f~ \J O
*J J L ?OR
651209
651209
651209
651209
651209
651210
651210
651211
651211
651211
651211
651212
4GN
0
0
0
0
0
0
0
0
0
0
A C 1 pi p
O U X £. J. £,
65121Z
0
A.R1 717
*J J J. £. I C*
651213
AC L C. L 3
vj J i 71 ^
0
651213
651213
651214
651214
651215
651215
651219
651219
651219
651219
651220
651220
651221
651221
651221
65122 1
651228
651228
651228
0
0
0
0
0
0
0
o
0
0
0
AS1 77H
O J L C. £- fi
A JL^ 1
OC 1 5 ^J i
651231
651231
65123 1
651231
0
TYP
GALS
D
2700
D
3000
0
0
0
D
3000
0
0
D
2000
0
D
2000
0
0
D
2700
D
2700
C
300
0
D
3000
0
D
3000
0
D
3000
0
D
3000
0
C
2000
0
D
2000
0
D
750
D
3000
C
3600
0
D
3700 .
0 ">r
2500
0
D
3000
0
D
2800
0
0
3000
0
D
2000
0
r
3000
0
0
PROV NO. = 34
K I F N HQA
3000
0
0
n
LEG
1A
1A
IB
2A
2B
1A
IB
1C
1A
IB
1A
16
1C
1A
1A
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
• 1A
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
UTM
XS870150
XS650295
XS730250
XS470280
XS470260
XS840130
XS83O210
XS730270
XR780980
XR740970
XS840130
XS820080
XS810040
XS880190
XS380190
X.S470280
XS450240
XS637310
XS760240
XS830095
XS780230
XS870120
XS880235
XR800980
XR720970
XS790030
XS830120
XS680290
XS870140
XS845140
XR750980
XS850130
XS765250
XS770000
XR740955
XS885232
XS870140
XS730255
XS832174
XS797052
XS800207
XP790980
XR760999
XS790025
XS810053
XS800020
XS885230
XS460290
XS460230
XS730250
I:
J
�MISSIONS STARTING IN
DATt
651231
660425
660425
660518
660518
663513
660521
660521
660522
660522
660522
660522
660523
660523
660523
660523 .
660524
660524
660524
660524
660525
660525
660525
660525
660525
660525
660525
660525
660525
660527
660527
660527
660527
66052?
660529
660530
660530
660530
660530
660530
660530
660531
660531
660531
660531
660531
660531
660531
660531
660601
AGN
0
0
0
0
0
n
0
0
0
0
0
0
0
0
n
3
KIEN HOA
************
LEG
GALS
TYP
28
0
1A
3000
D
IB
0
1A
3600
D
IB
0
0
1C
1A
3750
0
IB
0
1A
3000
D
0
18
2A
0
2B
0
1A
3700
D
0
IB
2A
0
0
2B
2000
1A
D
0
IB
0
1C
0
ID
4000
1A
D
0
IB
0
2A
0
2B
3000
D
1A
0
IB
0
1C
0
2A
0
2B
3000
1A
D
0
IB
4900
D
1A
0
IB
5000
D
1A
0
IB
2500
D
IA
0
IB
0
2A
0
2B
3000
D
1A
0
18
2500
1A
r
0
IB
0
2A
0
26
D
4000
1A
0
IB
0
2A
0
28
4000
1A
C
UTM
XS810190
XS635315
XS780230
XS936242
XS895207
XS865104
VS975212
XS870104
XS458293
XS474276
XS963236
XS883121
XR729876
XR763961
XR865917
XR829886
XS824087
XS823068
XS836063
XS842085
XR846950
XR754851
XR834894
XR867931
XS940239
XS900206
XS878105
XS940154
XS953162
XS960238
XS887129
XR830970
XP749358
XS950240
XS880130
XR800980
.<R736873
XS457292
XS473276
XS906208
XS887143
XS456294
XS458223
XR825972
XR748861
XS963235
XS895141
. XS906166
XS943222
XS966232
�MISSIONS START ING
DiTE
660601
660601
660601
660601
660601
660602
660602
660602
6606J2
660602
660603
660603
660606
660606
660606
660606
660624
660624
660627
660627
660627
660627
660629
660629
660629
660629
660702
660702
670612
670612
670612
670616
670616
670620
670620
670620
670620
670622
670622
670622
670622
670625
670625
670702
670702
670702
670702
670704
670704
670704
AGN
0
T
0
0
n
0
0
0
0
0
w
0
0
Q
0
w
0
in
GALS
0
0
4000
0
0
3600
0
4000
0
0
4000
0
4000
0
2000
0
2000
0
2000
0
0
0
2000
0
0
0
2600
0
2400
0
0
6250
0
2600
0
0
0
27SO
0
0
0
2790
0
3720
0
0
0
2300
0
0
KIEN HOA
* * * * * *
* * * * * *
TVP
D
D
D
D
D
D
0
0
D
D
D
D
P
D
0
D
n
LEG
IB
1C
1A
IB
1C
1A
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
2A
28
1A
IB
1A
IB
1C
1A
IB
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
1A
IB
2A
2B
1A
IB
2A
UTM
XS900UO
XS971228
XR805978
XR768936
XR820980
XS943240
XS899157
XR823973
XR742865
XR770953
XS868104
XS975216
XS953240
XS900158
XR845951
XR753851
XR845951
XR820920
XR738370
VR770990
XS815040
XS850150
XS940240
XS903133
XR862937
XR630S80
XR850950
XR830920
XS810190
XS830140
XS790050
XS635307
XS785213
XS692287
XS755256
XS782320
XS8371&0
XR744967
XR713895
XR728880
XR759962
XS687226
XS973207
XS865178
XS952159
AS952173
XS890121
V
S879199
XS964177
XS922140
�KIEN HOA
************
TYP
GALS
LEG
0
28
5900
D
1A
0
18
2A
0
0
2B
6000
D
1A
0
IB
2A
0
0
2B
D
2950
1A
0
IB
0
2A
0
28
2800
D
1A
0
IB
0
2A
0
28
D
2700
1A
0
IB
0
2A
0
2B
D
2725
1A
0
IB
0
2A
0
26
D
1850
1A
0
IB
0
2A
28
0
1A
2400
D
0
IB
2A
0
0
26
4000
D
U
0
IB
0
2A
0
2B
3000
r
1A
0
IB
0
2A
0
ZB
6500
1A
D
0
IB
4700
D
1A
0
IB
0
2A
0
2B
2000
D
1A
0
IB
4000
P
1A
MISSIONS STARTING IN
D4T<E
670704
670712
670712
670712
670712
670715
670715
670715
670715
670721
670721
670721
670721
670724
670724
670724
670724
670726
670726
670726
670726
670814
670814
670614
670314
670817
670817
670817
670817
670916
670916
670916
670916
671016
671016
671016
671016
671025
671025
671025
671025
671109
671109
671112
671112
671112
671112
671113
671113
671118
AGN
W
W
0
W
0
o
0
0
W
T
W
0
W
G
UTM
XS850160
XS882218
XS972197
XS951163
XS869181
XS873184
XS951167
XS972202
XS882223
XS880210
XS970180
XS840160
XS860180
XS875187
XS950172
XS970193
XS885214
XS853156
XS917136
XS953177
XS881197
XS855152
XS912132
XS964181
XS881203
XS882210
XS970190
XS951154
XS860173
XS882209
XS969189
XS911133
XS857148
XS880195
XS960174
XS950162
XS867173
XS861208
XS968187
XS962144
XS848164
XS855143
XS793028
XS8S0205
XS964188
XS960175
XS880194
XS635305
XS686270
XR754055
*
�UNCLASSIFIED
KIEN HOA
************
TYP
LEG
GALS
IB
0
2A
0
2B
0
C
1A
4600
IB
0
2A
0
2B
0
C
1A
5750
IB
0
D
1A
6000
IB
0
2A
0
2B
0
D
1A
6000
IB
0
D
IA
3000
IB
0
D
IA
8000
IB
0
2A
0
2B
0
D
1A
8000
IB
0
2A
0
2B
0
D
1A
6000
IB
0
4000
D
1A
IB
0
E
1A
385
IB
0
2A
0
2B
0
h
1A
605
IB
0
U
1A
320
IB
0
0
2A
26
0
PRDV NO. = 34
MISSIONS STARTING IN
DATE
671118
671118
671118
671119
671119
671119
671119
680331
630331
680401
680401
680401
680401
680410
680410
681221
681221
690213
690213 •
690213
690213
690219
690219
690219
6S021?
690407
690407
650501
690501
700213
700213
700213
700213
700216
700216
700216
700218
700218
700213
A3N
G
W
0
a
w
w
w
0
0
0
0
0
UTM
XR854944
XR865935
XP835901
XS853167
XS927165
XS951159
XS865178
XS568137
XS491246
XS460409
XS370401
XS370389
XS453398
XS470382
XS370382
XS595237
XS531273
XS613257
XS556296
XR420850
XR400930
XS600240
XS536277
XR334780
XR304769
XS604247
XS542282
XS610254
XS550293
XS719230
XS752232
XS730234
XS753235
XS822205
XS796225
XS725935
XS732935
XS735955
XS742961
it,:'.'{ r <-, <; : f T 'it
�NREC= 17901
NREC= 17901
NiPROV=
,NPf!OV=
34
84
NZREC=
NZR=C=
155
155
UNCLASSIPI =0
�DATE
660102
660102
660103
&60103
660103
660103
660103
660103
660112
660112
660112
660112
660112
660112
660117
660117
660117
660117
660117
660117
661122
661122
661202
&612J2
661219
661219
661221
661221
661221
661221
661226
661226
661226
661226
661230
661230
670102
670102
670102
670102
670120
670120
670125
670125
670129
670129
670203
670203
670207
670207
AGN
0
0
0
0
'3 '
0
0
0
0
w
0
0
n
0
0
Q
GALS
4000
0
4000
0
0
0
0
0
3000
0
0
0
0
0
2000
0
0
0
0
0
3600
0
1300
0
3600
0
3600
0
0
0
3600
0
0
0
3600
0
3600
0
0
0
2700
0
2700
0
2700
0
3000
0
2700
0
TYP
D
D
D
D
D
c'
D
D
D
C
D
D
D
n
C
n
LEG
1A
IB
1A
IB
1C
ID
2A
23
1A
13
2A
2B
3A
3B
1A
IB
1C
ID
2A
2B
1A
18
1A
18
1A
IB
1A
18
1C
10
1A
IB
1C
ID
1A
IB
1A
IB
1C
ID
1A
IB
1A
IB
1A
IB
1A
16
1A
IB
OTM
XR690710
XR690780
XR570550
XR585600
XR540550
XR560605
XR510560
XR530600
XR680780
XR675705
XR505562
XR525595
XR580595
XR570560
XP685780
XR685700
XR655700
XR635690
XR550600
XR540550
XR492610
XR650662
XR540537
XR728720
XP708773
XR603533
XR698776
XP693700
XP671626
XP534579
X&700774
XR674624
XR585561
XR511558
XR730750
XR512558
XR508561
VR576563
XR651640
XR669691
XR725758
XR590560
XP700730
XP.490580
XR530600
XR710630
XP6855e&
XR489577
XP610690
XR.670790
�DATE670213
670213
670213
670213
670213
670213
670215
670215
670215
670215
670215
670215
670219
670219
670219
670219
670219
670219
670303
670303
670303
670303
670303
670303
670308
670308
670308
670308
670308
570308
670310
670310
670310
670310
670315
670315
670315
670315
670316
670316
670317
670317
670317
670317
670328
670328
670323
670328
670331
670331
AGN
0
GALS
2400
TYP
[>
0
0
0
0
0
0
1500
D
0
0
0
0
0
0
2700
D
0
0
0
0
0
0
2700
D
0
0
0
0
0
0
1600
D
0
0
0
0
0
n
3600
D
0
8
1500
D
0
0
1600
D
0
3
B
0
2600
0
0
0
900
0
2700
D
D
D
0
0
2790
D
0
n
0
0
4650
0
P
LEG
1A
IB
2A
28
3A
3B
1A
IB
2A
2B
3A
3B
1A
IB
2A
2B
3A
3B
1A
IB
2A
2B
3A
38
1A
IB
2A
2B
3A
3B
1A
IB
1A
IB
1A
IB
1A
18
2A
2B
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
UTM
XS385068
XS370115
XS380025
XS40C064
XR417853
XR408890
XS359115
XS352083
XS372052
XS350030
XS426001
XS439070
XR 11 692 7
XR116900
XR128883
XR158856
XR176832
XR2 10802
XS373033
XS393048
XS383068
XS374124
XS344120
XS346086
XS348117
XS355032
XS391046
XS376023
X S3 5002 8
XS370056
XR680580
XR500560
XR680580
XP500560
YS690595
YS518548
YS690595
YS518548
VD763653
XD705653
XP475590
XR670620
XR475590
XR670620
XP600680
XR730720
YR640870
XR650850
V
R690590
>-P490570
�// I
04T6
670521
670521
671230
671230
671230
671230
671230
671230
680102
680102
680102
680102
680102
680102
630104
AGN
0
0
0
0
680104
630104
680104
680104
680104
680110
630110
680110
630110
680110
680110
681217
681217
681216
681218
631227
681227
690109
690109
690109
690109
W
690111
690111
690111
690111
0
690129
690129
690129
69012S
690221
690221
690221
690221
690411.
690411
W
W
W
0
0
G
0
GALS
4650
0
2800
0
0
0
0
0
3000
0
0
0
0
0
2800
0
0
0
0
0
2800
0
0
0
0
0
425
0
830
0
6000
0
9000
0
0
0
9000
0
0
0
8000
0
0
0
8000
, 0
' 0
0
6000
0
\TYP
x
r
D
D
D
r
p
p
p
0
D
D
D
D
LEG
1A
IB
1A
IB
2A
28
3A
3B
1A
IB
2A
2B
2D
3A
1A
IB
2A
2B
3A
38
iA
IB
2A
2B
3A
3B
1A
IB
1A
13
1A
IB
1A
IB
2A
2B
IA
IB
2A
2B
1A
IB
2A
2S
14
IB
2A
2B
1A
1R
UTM
XR717712
XR620570
XR516000
XR559956
XR656896
XR681870
XR701838
XR685899
- XR512995
XR557933
XR657896
XR688872
XR664907
XR698880
XR515999
XR559959
XR655895
XR684870
XR693875
XR660901
XR514997
XR558953
XR663885
XR683869
XR702887
XR670913
XS388040
XS389062
XS343023
XS367052
XR732716
XR660572
XR677780
XR695703
XR682648
XP653608
XR676786
XR682735
XR668705
XR662663
XR686594
XR620558
XP570558
XR525558
XR720770
XR720690
XR710640
XP680600
XR206302
XR164845
'
�UNCLASSIFIED
MISSIONS
DATE
690411
690413
670413
690413
690413
690423
690423
690427
690427
690427
690427
690427
690427
690427
690427
690428
690428
690504
690504
690525
690525
690525
690525
690525
690525
690627
690627
690705
690705
690705
690705
690709
690709
690713
690713
690713
690825
690825
690325
700310
700310
700310
700310
700310
700310
700310
700310
700313
700313
700313
STARTING
AGN
0
0
0
W
n
w
W
n
n
0
0
0
r)
0
0
IN
GALS
0
6000
0
0
0
6000
0
440
0
0
0
210
0
0
0
385
0
365
0
630
0
0
330
0 '
0
6000
0
6000
0
0
0
6000
0
4000
TYP
D
D
s
s
s
s
s
s
n
D
D
D
'd
0
11000
0
0
800
0
0
0
0
0
0
0
800
0
0
PROV NO. = 35
VINH B!NH
D
k
V»
LEG
1C
1A
IB
2A
28
1A
IB
1A
18
2A
2B
1A
IB
2A
26
1A
IB
1A
IB
1A
IB
1C
1A
IB
1C
1A
IB
1A
IB
1C
ID
1A
18
1A
IB
1C
1A
IB
1C
1A
IB
2A
26
3A
36
4A
4B
1A
IB
2A
UTM
XR112906
XR719770
XR7 17696
XR702650
XR669590
XR503563
XR&47563
XSS70123
XS392060
XS395080
XS370015
XS370123
XS392060
XS395080
XS370015
XS430060
XS378010
XR417990
XS445050
XR417990
XS438035
XS387075
XR417990
XS438035
XS387075
XR497568
XR657568
XR703776
XR701703
XR686643
XR657604
XR655584
XR485579
XR690780
XR689704
XR648611
XR730760
XR720650
XR700610
XS352118
XS343070
XS372120
XS388070
XS354033
XS370054
VS411044
*S381013
XS37U025
XS390G50
X RIO 591 5
�UNCLASSIFIED
MISSIONS STARTING IN
IG IN
AGN
700313
700313
700313
700313
700313
700318
700318
700318
700318
700318
700318
700318
700318
700319
700319
700319
700319
700319
700319
700325
700325
700325
700325
700325
700325
700325
700325
700331
700331
700331
700331
700331
700331
GftLS
0
0
0
0
0
750
0
0
*0
0
0
0
0
600
0
0
0
VINH BINH
TYP
W
fe
0
0
800
0
0
0
0
0
0
0
600
0
0
0
0
0
k
W
PROV NO.
LEG
2B
3A
3B
4A
4B
1A
IB
2A
2B
3A
33
4A
48
1A
IB
24
2B
3A
3B
1A
IB
2A
25
3A
3B
4A
4B
1A
18
2A
2B
3A
36
UTM
XP098935
XS460050
XS438031
XS35011B
XS342068
XR610685
XR656704
XR000930
XR060913
XS390020
XS410040
XS344-024
XS375054
XS436026
XS389019
XR610632
XR656704
XP100950
X5004002
XR610670
XR672703
XS455018
XS390050
XR405625
XR444604
XS352090
XS387060
XS365120
XS388075
XP610670
XR670703
XS380015
XS440043
UflCLA.SSIFIjn
35
�NP.EC= 17907
NREC= 17907
NPPOV=
NPfrL)V=
61
61
NZRRC=
NZR£C=
172
172
UNCLASSIPI30
�MISSIONS
DATP
681017
631206
631206
631230
681230
690122
690228
690226
690228
690228
690301
690301
690302
690302
690302
690302
690303
690303
69Q304
690304
690306
690318
690318
690325
690326
690403
690404
690405
690406
690406
690416
690416
690416
690416
690424
690424
690424
690426
690520
690520
690520
690520
690520
69G520
690613
690702
69070*
690702
690702
693702
STARTING
AGN
0
W
w
B
W
W
W
w
,•
w
w
8
W
W
W
ft
w
w
w
w
w
W
W
IN
GALS
445
670
0
830
0
470
480
0
245
0
1130
0
850
0
0
0
'250
TYP
P
K
S
P
S
s
s
s
s
0
90
0
420
P
1185
£
0
270
440
195
800
250
1075
0
820
0
0
0
4 70
0
0
385
1485
$
c
S
s
s
s
w
\s
\
s
P
?
0
0
0
0
0
<*,
W
PROV NO. = 36
VINH LONG
165
715
P
s
LEG
1A
1A
IB
1A
IB
1A
1A
IB
1A
IB
1A
IB
1A
IB
2A
28
1A
IB
1A
IB
1A
1A
18
1A
1A
1A
1A
1A
1A
IB
1A
2A
3A
4A
1A
2A
3A
1A
1A
IB
2A
2B
3A
3B
1A
1A
' 0
IB
0
0
0
2A
2B
1C
UTM
XS040330
XS287224
XS307192
XS061179
XS066212
XS054312
XS192243
XS210246
XS098168
XS106184
XS107194
XS099168
WS976260
WS985240
WS978238
WS979194
WS910217
WS913158
WS910217
WS913158
XS054312
WS910217
WS913158
XS 130010
XS150010
XS105005
XS105005
XS105005
XS025164
XS099168
WS960090
XS020070
XS150040
XS170110
XS230270
XS195265
XS265226
XS110310
WS910216
WS910169
XS018166
XSOB8176
XS062208
XS061180
XS110310
XS046070
XS034J46
XS027071
XS030042
X SO 1406 8
�MISSIONS STARTING IN
DAT?
690702
690702
690704
690704
690704
690704
690712
690725
690725
690726
690726
690726
690726
690726
690726
690726
690726
690726
690726
690726
690726
690726
690726
690726
690804
690804
690804
690804
690804
690804
690304
690804
690804
690804
69O304
690804
690804
690805
690805
690805
690805
690805
690805
690805
690805
690827
690827
690827
690827
690827
AGN
0
«
0
0
0
0
0
VINH LONG
************
GALS
TYP
LEG
3A
0
0
38
S
1A
840
IB
0
0
1C
0
ID
P
1A
220
W
1A
275
0
IB
715
S
1A
IB
0
0
1C
0
ID
0
IE
IF
0
0
1G
1H
0
0
U
IK
0
0
1L
0
1M
0
IN
0
10
0
IP
800
S
1A
0
IB
0
1C
2A
0
0
2B
0
2C
0
2D
0
2E
0
2F
0
2G
b
2H
0
2J
0
2K
850
S
1A
0
IB
0
1C
0
ID
0
IE
IF
0
0
24
0
28
S
1A
435
0
IB
0
2A
0
5A
0
4A
UTM
WS990108
XS002067
WS998067
XS003036
XS002067
XS027071
XS110310
XS032041
XS013068
XS046070
XS034046
XS027071
XS046070
XS002068
XS095200
XS091171
XS043210
XS058192
WS967198
WS976200
WS974220
WS934218
WS977300
WS975260
XR939979
XS130057
XS170063
XS142049
XS170063
XS143102
XS192068
XS150097
XS180180
XS043209
XS057193
XS090174
XS096199
HS070200
WS973219
XS033043
XS045070
XS013067
X 503 3041
XS034046
XS023070
SS174296
•<Sl?3287
XS230225
VS250205
VS236198
'
f.
I
�UNCLASSIFIED
MISSIONS START ING IN
!G IN
DATE
690827
690827
690827
690827
690827
690827
690827
690828
690828
690828
690828
690828
690828
69D828
690828
690828
690828
690828
6?0828
690912
691202
691202
691202
691202
691204
691204
691204
691204
691204
691204
691204
691204
691204
691205
691205
691205
691205
691205
691205
691205
691205
691205
691205
691205
691205
691205
GALS
0
0
0
0
0
0
0
470
0
0
0
VINH LONG
TYP
S
0
0
0
0
0
0
0
0
125
300
0
0
0
600
0
0
0
0
0
0
0
0
600
b
0
0
0
0
0
0
0
0
0
0
, 0
P
V,
Vt
h
PROV NO. = 36
LEG
5A
56
6A
66
7A
76
8A
1A
18
2A
3A
3B
3C
3D
3E
3F
3G
3H
3J
1A
1A
IB
2A
2B
1A
IB
2A
28
3A
38
3C
4A
4B
1A
IB
2A
2B
3A
38
44
4B
4C
5A
5B
6ft
68
UTM
XS013067
XS045069
XS143052
XS170063
XS060178
XS090173
XS33O105
XS174296
XS193287
XS230225
XS250205
XS236198
XS013067
XS04506S
*S143052
XS170063
XS060178
XS090173
XS330105
XS040329
XS171081
XS199101
XS248079
XS306070
XS270070
XS315070
XS125100
XS145103
XS045225
XS188055
XS069223
XS209002
rS230980
WS780254
WS805284
WS812242
WS833282
WS931218
WS972218
XS045159
XS055189
XS110160
XS332108
XS368123
XS350119
•^5340135
�UNCLASSIFIED
/
NPEC= 17994
NREC= 17994
i\PP.OV=
NPROV=
36
36
N2REC=
NZREC=
110
110
r-
UfJCLASSIFino
�D*TE
AGN
AN GIANG
************
GALS
TYP
LEG
PR
MISSIONS STARTING IN
UTM
UNCLASSIFIED
UNCLASSIFIED
OV NO- = 3 7
�NRBC= 18140
NREC= 18140
NPROV=
NPROV=
0
0
NZREC=
NZREC=
0
0
UNCL^SSI
�MISSIONS STARTING IV
H4T-
AGN
660804
660804
660804
660804
660817
660817
660S17
660817
66082"?
660829
680930
680930
681003
681003
631224
681224
601224
690121
690121
690121
690121
690526
690526
690526
690526
690526
690526
690601
690601
690601
690601
690601
690601
690602
690602
690602
690602
690602
690602
690602
690602
690602
690602
690602
69060P
690610
690610
690616
690616
690618
n
0
0
0
0
0
til
0
w
w
0
w
0
T
KIEN GIANG
************
TYP
LEG
GALS
n
1A
3000
0
IB
0
2A
0
28
0
1A
3900
0
IB
2A
0
26
0
n
1A
2000
IB
0 .
1A
3000
D
0
IB
4000
1A
D
0
IB
4000
D
1A
0
IB
0
1C
615
s
1A
0
IB
0
2A
2B
0
4500
D
1A
0
IB
0
1C
2A
0
'0
2B
0
2C
5
1540
1A
0
IB
0
2A
0
2B
3A
0
0
3B
880
S
1A
0
IB
2A
0
0
28
1A
4000
D
IB
0
2A
0
0
2B
3A
0
3B
0
4A
0
4B
0
5
1A
3,30
0
IB
S
825
1A
0
IB
P
14
3500
UTM
VS553342
VS553397
VS575254
VS560316
VS560392
VS562350
VS566310
VS586262
VS575330
VS600270
US929087
US929246
US928037
US925243
VS930090
VS910210
VS940246
WS137112
WS118150
WS134105
WS165165
US941137
US895137
US894133
US947133
US955127
US897127
WS115155
'nlS140103
WS108073
WS125090
WS 11 8080
WS125063
WS410040
WS492052
WS392008
WS424034
US955123
US897123
USS97119
US940119
US948116
US898116
US898107
US947107
WS39200b
WS424084
VS950165
WS030123
US947103
�UNCLASSIFIED
MISSIONS ST&RTING IN
DATP
690618 •
690618
690618
690618
690618
690623
690623
691206
700124
700126
700126
700126
700126
700126
700126
700126
700126
700126
700126
700127
700127
700127
700127
700211
700211
700323
700323
700323
700323
700323
700324
700324
700324
700324
700324
700324
700324
700324
700324
700324
700327
700327
700327
700327
700327
700327
700429
700429
710112
710112
AGN
.
W
0
0
W
W
W
0
0
0
GALS
0
0
0
0
0
220
770
400
440
770
0
0
0
0
0
0
0
0
0
330
0
0
0
4000
0
800
0
0
0
0
700
0
0
0
TYP
S
S
S
S
S
S
D
£
E
6
W
W
W
W
PRQV NO.
KIEN GIANG
300
0
0
0
0
5000
0
0
0
0
0
3000 '
0 *
800
0
C
0
r,
"' ™~
P
L6G
IB
1C
2A
2B
2C
1A
1A
1A
1A
1A
IB
2A
2Q
3A
3B
4A
48
5A
53
1A
IB
2A
23
1A
18
1A
IB
1C
2A
2B
1A
IB
1C
ID
IE
1A
IB
1C
ID
IE
1A
IB
1C
10
It
IF
1A
ie
1A
18
UTM
US89S107
US910093
US950097
US942093
US912093
WS950165
WS950165
VS899225
VS896225
VS980162
VS937162
VS980164
VS937164
VS982165
VS936166
VS983166
VS935170
VS983169
VS934172
VS910154
VS937164
VS911159
VS935169
VS882150
VS761292
VS910170
VS960180
VS980170
VS980160
VS910150
VS910170
VS960180
VS980170
VS980160
VS910150
VS910170
VS960130
VS980170
VS980160
VS910150
VS913154
VS890185
VS865181
VS837227
VS816251
VSdG3265
VRS25532
VR843713
WP020510
WR024515
38
�UNCLASSIFIED
MISSIONS
DiTF
710112
710112
710112
710112
710113
710113
710113
710113
710113
710113
710113
710113
710115
710115
710115
710115
710121
710121
710121
710121
710121
710209
71020?
710212
710212
710213
710213
710214
71Q214
710215
710215
710215
710215
710216
710216
710216
710216
S T A R T I N G IN
AGN
W
W
W
W
W
W
W
W
W
GALS
0
0
0
0
450
0
0
0
0
0
0
0
750
0
0
0
1550
0
0
0
0
605
0
1100
0
660
0
880
0
1100
0
0
0
1100
0
0
0
KIFN GIANG
TYP
P
P
P
P
P
P
P
P
P
PROV
LEG
1C
ID
IE
IF
1A
IB
1C
ID
IE
IF
1G
1H
1A
IB
1C
ID
1A
IB
1C
ID
IE
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
26
1A
IB
2A
2B
UTM
WR038478
WR043487
WF020510
HR060440
WR045470
WR059441
WR066448
WR050475
WR035440
WR042440
WR012502
WR007499
WR035440
WR042440
WP012502
WP007499
VR922622
VP.948630
VR9375SO
VR955568
VP964568
WR028485
WR054465
VR995541
WR020510
WR050460
WP063414
VR945620
VP900605
VR870610
VR850599
VR060615
VR870610
VR945415
VR975395
VR925426
VR965595
L'\CLASSIFI =f
NO.
38
�UNCLASSIFIED
NREC= 13003
NREC= 18003
NPC.OV=
NPROV=
36
36
NZREC=
NZREC=
101
101
UNCLASSIFIED
UNCLASSIFIED
,_ /
�MISSIONS STARTING
DATf?
660807
660807
660814
AGN
0
GALS
2900
0
2000
690227
690605
690605
690606
690606
690611
690611
690612
690612
690620
690620
690620
690620
690809
690809
690821
690821
690823
690823
690922
690922
690922
710219
710219
D
0
0
660820
660631
660831
681224
631224
TYP
D
0
660814
660820
I N CHUONG T H I E N
3000
D
0
0
.w
w
f]
0
0
0
Q
Q
0
0
3000
0
715
0
520
300
0
440
0
495
0
605
0
385
0
0
0
5100
0
330
0
165
0
D
P
P
S
W
W
k
S
D
k
V,
0
4500
D
w
0
0
990
0
P
LEG
1A
IB
1A
IB
1A
18
1A
IB
1A
18
1A
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
26
1A
IB
1A
IB
1A
16
1A
IB
1C
1A
IB
PROV NO.
UTM
WR360720
WP230745
WK403740
WP230740
WF405735
WR250730
WR37-2707
WR240739
WR645580
WR674596
WP660580
WR470609
WR519608
WR470609
WR519608
WR470609
WR519608
WR550598
WP604605
WR245767
WR240744
WR266750
WR228751
WR773781
WR672745
WR600728
HR592694
WR606695
WP562700
WR346663
WR283703
WR268743
WR 17 767 6
WR196602
UNCCASSIFItO
39
�NREC= 18106
NREC= 18106
NPROV=
NPROV=
16
16
NZREC=
NZREC=
18
18
UNCLASSIFIED
�MISSIONS STARTING IN
DATE
651214
670805
670805
671220
671220
671220
671220
680819
680819
680819
680819
680820
680820
680820
630820
681019
681019
681019
6S1019
681203
631203
681203
681203
681226
681226
681226
631226
690115
6S0124
690204
690204 •
690204
690204
690211
690211
SON
0
0
0
W
B
W
3
B
B
3
8
3
690211
690211
690313
690313
690313
690313
690327
690327
690327
690327
690401
690403
690403
690403
690403
0
0
8
0
PHONG OINH
$********•***
GALS
TYP
LEG
D
1A
2550
D
1A
4000
IB
0
6000
D
1*
0
IB
2A
0
0
28
F
1A
990
0
IB
2A
0
0
2B
P
IA
165
0
IB
0
2A
26
0
355
V<
1A
0
IB
0
1C
0
10
1980
P
1A
0
IB
0
1C
0
ID
1540
P
1A
0
IB
0
1C
0
10
1A
360
P
1A
315
P
1A
900
P
0
18
2A
0
0
2B
800
1A
f
6
IB
2A
0
0
2B
P
520
1A
0
IB
2A
0
0
26
7000
D
1A
0
IB
0
24
0
2B
115
P
1A
9000
D
14
0
IB
0
1C
0
2A
UTM
KS790140
VP795129
VR816321
VC841601
V0798479
V0750487
VQ770535
WR830950
WR822946
WP.845929
WP839917
WR760880
WP810810
WP300810
WP770880
WS753032
HS753028
WS726998
WS730994
WS797158
WS810147
WS777129
WS769141
HS797158
VJS810147
WS77712S
HS769141
WS840108
HS840108
WS797158
WS810147
WS777129
WS769141
WS797158
WS810147
WS777129
HS769141
WS797158
HS810147
WS777129
WS769141
WS676088
WS676002
WS696088
WS696002
WSb4010d
WS700074
WS664079
WS653029
WS678036
'
# /
�DATS
690403
690403
690403
690404
690411
690411
690411
690411
690411
690411
690417
690417
690417
690417
690*21
690421
690421
690421
690429
690526
690526
690526
690526
690526
690526
690526
690526
690526
690526
690526
690526
690526
690526
690527
690527
690527
690527
690614
690614
690614
690614
690621
690625
690625
690625
690625
690625
690625
690625
690625
AGN
3
W
W
8
3
W
GALS
0
0
0
220
1927
0
0
0
0
0
1110
0
0
0
550
0
0
0
235
1320
0
0
0
0
0
0
0
0
TYP
P
S
S
P
P
S
0
0
W
3
8
W
0
0
0
590
0
0
0
605
0
0
0
220
1265
0
0
, 0
0
0
0
0
S
P
P
S
LEG
26
2C
2D
1A
1A
2A
3A
4A
5A
6A
1A
2A
28
2C
IA
IB
2A
28
1A
1A
IB
2A
28
3A
3B
4A
46
5A
5B
6A
66
7A
7B
1A
18
2A
28
1A
18
2A
28
1A
1A
16
1C
ID
IE
2A
28
3A
UTM
WS722025
WS683068
WR683995
WS840108
WS660120
WS700120
WS700100
WS750060
WR760980
WR760950
WR920820
WR850930
WR930960
WR920900
WS797158
WS810147
WS777129
WS769141
WS840108
WS655142
WS674114
WS693135
WS707117
WS696100
HS706105
WS774065
WS750060
WS776012
WS773976
*IS752010
WS763970
WS737987
WS758968
WS667096
WS512063
WS937968
WS920898
WS797158
WS810147
WS777129
WS769141
WS840108
WR755065
WS774065
WR773052
WR937968
WR920900
WR776012
WR773976
WR752010
�UNCLASSIFIED
MISSIONS STARTING IN
D5T17
690625
690625
690625
690625
690625
690704
690813
690S13
690S13
690813
690816
690816
690816
690816
690918
691024
691024
691024
691024
691215
691215
691218
691218
691220
691220
691220
691220
691220
691220
691220
691220
691220
691220
691220
691220
691222
691222
691222
691222
691222
591222
691222
691222
691222
691222
691223
691223
691223
691224
691224
fiGN
B
S
B
W
B
0
W
0
W
0
GALS
0
0
0
0 .
0
110
770
0
0
0
495
0
0
0
300
650
0
0
0
400
400
300
0
325
0
0
0
0
0
325
0
0
0
0
b
W
irf
700
0
0
0
0
0
0
0
0
0
3,00
TYP
P
P
P
P
P
P
P
V.
W
W
to
w
0
W
0
750
0
PROV NO, = 40
PHONG DINH
w
LEG
3B
4A
46
5A
5B
1A
1A
16
2A
28
1A
IB
2A
26
1A
1A
IB
1C
ID
1A
1A
1A
IB
1A
IB
2A
2B
3A
3B
1*
IB
2A
28
3A
38
1A
IB
1C
2A
2B
3A
36
4A
46
4C
1A
IB
1C
1A
IB
UTM
WR763970
WP736987
HR758968
WS703104
WS696100
WS835104
WS79T156
HS810147
WS777129
WS769141
WS797158
WS810147
WS777129
WS769141
WS825105
WS797158
WS810147
WS777129
WS769141
WS790145
WS790145
WR575980
WR620942
WS565008
WS581044
WS602074
WS628093
WS645085
WS640062
WS565008
WS5U1044
WS602074
WS628093
NS645085
WS640062
WS645085
WS660030
WS656064
WS665083
WS649108
WS567095
WS539109
WS555088
WS541080
WS542058
WP, 63 596 4
WR679994
WR671007
WR621942
WS695005
t
�UNCLASSIFIED
MISSIONS STARTING IN
DATF
700321
700323
700626
700627
AGN
0
G
3
B
GALS
800
800
600
1350
PROV NO.
PHONG DINH
TYP
P
P
P
P
LEG
1A
1A
1A
1A
(JTM
WS84-0120
WS84911ti
WS790140
WS790140
UNCLASSIFIED
UNCLASSIFIED
40
�NREC= 17936
NREC= 17936
NPROV=
NPROV=
55
55
NZREC=
NZREC=
149
149
UWCL6SSIFI5D
UNCLASSIFIED
�M I S S I O N S STARTING IN
DATE
660617
660617
660617
660617
660619
660619
660622
660622
660629
660629
660629
660629
660630
660630
660630
660630
660716
660713
660718
660718
690207
690207
690207
690207
690218
690218
690218
690218
690314
690314
690329
690329
690329
690329
690514
690514
690514
690514
690514
690514
690514
690514
690514
690514
690519
690519
690519
690519
690519
690519
ASM
0
0
0
Q
0
0
B
8
B
3
W
0
GALS
2000
0
0
0
3000
0
2000
0
2800
0
0
0
4000
0'
0
0
1800
0
0
0
315
0
0
0
330
0
0
0
520
0
115
0
0
0
851
0
0
0
0
0
0
0
0
0
715
0
0
0
0
0
3A XUYEN
TYP
D
D
D
D
0
P
P
P
P
P
s
W
PROV NO.
LEG
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
2A
2B
1A
18
1C
10
1A
IB
2A
2B
1A
IB
2A
26
1A
IB
2A
26
1A
IB
1A
IB
2A
28
1A
IB
1C
ID
2A
2B
2C
20
3A
3B
1A
ie
1C
ID
2A
2B
41
UTM
XR380534
XR365570
XR346570
XR330550
WR860575
WR830570
XR186443
XR330480
XR322572
XR335540
XR352540
XR354570
WR860560
WR820560
WR800580
WR830570
XR210436
XR320470
XR375545
XR375560
XR060597
XP052587
XR0635<54
XR054584
XR060597
XR052587
XR063594
XR054584
XP060597
XR052587
XR060597
XR052587
XR063594
XR054584
XP131615
XR184587
XR162578
XP125588
WR972678
WR958670
WR948645
WR982628
WR941760
WR940705
XP.131615
XR184587
,\R 162578
XR125538
HR972678
WR958670
!•*»
�DiTE
690519
690519
690519
590519
690519
690519
690519
690519
690519
690519
690522
690522
690522
690522
690528
690528
690528
690528
690604
690604
690604
690604
690617
690617
690617
690617
690617
690617
690617
690617
690617
690617
690618
690618
690618
690618
690624
69J624
690624
690624
690624
690624
690624
690624
690624
690624
690626
690626
690626
690626
AGN
0
•
W
W
W
GALS
0
0
0
0
0
0
0
0
0
0
550
0
0
0
550
0
0
0
1155
0
0
0.
990
0
0
0
0
0
TYP
2C
20
3A
36
3C
3D
44
48
5A
5B
P
W
S
0
1320
0
0
0
0
0
0
0
0
0
385
0
0
0
1A
IB
1C
ID
W
1A
IB
2A
2B
2C
20
3A
38
3C
3D
0
0
1A
IB
1C
ID
o •
0
605
0
0
0
1A
IB
2A
28
0
0
LEG
S
1A
IB
2A
2B
W
1A
13
1C
ID
IE
IF
2A
2B
2C
2D
S
1A
IB
2*
28
UTM
WR948645
WR982628
WR940760
HP946760
WR954708
WR940706
XR170718
XR173693
XR285600
XR300580
XR060597
XR052587
XR063594
XR054584
XR131615
XR184587
XP182578
XR125588
WR880570
WR880560
WR860530
WR830590
XR169690
XR176713
XR131615
XR184587
XR182578
XR125588
WR810598
WR880565
WR930615
WR850630
XR 17471 8
XR178695
WR876725
WR934703
XR100758
XP118760
XRU8743
XR098741
WR941760
WR930970
WR930615
WR880566
WR810598
WR850630
WP934703
WR876725
WPS40760
WP939706
.
�UNCLASSIFIED
MISSIONS STARTING IN
DATE
690627
690627
690627
690627
690627
690627
690627
690627
690627
690627
690627
690627
690701
690701
690701
690701
690701
690701
690701
690703
690703
690703
690703
690703
690703
690703
690703
690711
690711
690711
690711
690711
690711
700220
700220
700220
700223
700223
700223
700223
700224
700224
700224
700224
700226
700226
700226
700226
700226
700226
AGN
0
0
GALS
1540
0
0
0
0
0
0
0
0
0
0
0
1100
0
0
BA XUYEN
TYP
k
S
0
0
0
Q
0
0
0
0
0
0
0
935
0
0
0
0
0
0
0
300
0
0
0
265
0
440
0
0
440
0
0
0
440
0
0
0
770
0
'/ 0
0
0
0
S
k
P
W
W
W
W
LEG
1A
IB
1C
ID
' IE
2A
2B
2C
2D
3A
3B
3C
1A
IB
1C
ID
IE
2A
28
1A
IB
1C
ID
IE
IF
2A
2B
1A
IB
1C
ID
1A
IB
1A
2A
2B
1A
IB
2A
26
1A
IB
2A
26
1A
IB
2A
2B
3A
3B
PROV NO.
UTM
XR131615
XR184587
yp.125538
WP876725
WR934703
WRS30615
WR880566
WR810598
WR850630
XR021776
XR018759
XR008761
WR972678
WP97262B
XR021776
XR018759
XP007761
XR147606
XR126590
XP284600
XR300580
HR877725
WR934703
WR972678
WR949644
WR939706
WR940760
NR880570
WR860560
WR860530
WF. 83 0590
WR660570
WR805546
WR940410
WR920430
WR820420
XR860740
XR940710
XR950720
XR950750
XR850580
XP880560
XR880580
XR860620
WR830590
WR880581
WR881580
WR865620
XR224441
XR262410
41
�MISSIONS STARTING IN
DATF
700226
700226
700303
700303
700303
700303
700303
700303
700305
700305
700305
700305
700305
700305
700305
700305
700305
700305
700309
700309
700309
700309
700309
700309
700309
700309
AGN
GALS
0
0
660
0
0
0
0
0
935
0
0
0
0
0
0
0
0
0
820
0
0
0
0
0
0
0
PROV NO. = 41
BA XUYEN
TYP
LEG
44
4B
1A
ie
2A
2B
2C
20
1A
IB
2A
2B
3A
36
4A
46
5A
58
1A
IB
2A
2B
3A
3B
4A
4B
UTM
XR280620
XR292581
WP910615
WR940620
KR90061Q
WR931620
WR880564
HP881610
XR020840
X.P020860
HR988882
XR020864
WR970862
WR990862
WR910440
WR918430
XR000880
XR002870
XR310450
XR271420
XR280412
XP300440
XR189460
XR200460
XR289430
XR300440
UNCLASSIFIED
�NREC= 17964NREC = 17964
NPi»CV =
MPKQV=
31
31
NZPEC=
NZREC=
145
145
t'
\
UNCLASSIFIHO
UNCLASSIFIED
�AN XUYEN
4>**« «.#*****
TYP
GftLS
LEG
1A
3000
0
0
18
2A
0
0
28
1A
3000
0
IB
0
0
2A
2B
0
2000
D
1A
0
IB
0
1C
2A
0
0
28
0
2C
1A
3000
D
0
IB
0
2A
0
28
0
3000
1A
0
IB
2A
0
0
2B
3600
0
1A
IB
0
0
2A
0
28
D
3600
1A
0
IB
0
1C
ID
0
C
1A
2700
0
IB
0
1A
2700
0
IB
D
1A
2700
0
IB
2700
D
1A
0
18
2400
0
1A
IB
0
2A
0
2B
0
1A
2700
D
18
0
0
1A
1200
0
IB
900
0
1A
0
IB
0
1C
900
D
1A
MISSIONS STARTING IN
DATE
660809
660809
660809
660809
660«15
660815
660815
660815
660819
660819
660819
660819
660819
660819
660823
660823
660823
660823
660902
660902
660902
660902
661019
661019
661019
661019
670107
670107
670107
670107
670110
670110
670114
670114
670124
670124
670127
670127
670204
670204
670204
670204
670214
670214
670227
670227
670311
670311
670311
670311
AGN
0
0
0
0
0
0
,
0
0
w
0
0
ri
0
0
0
B
UTM
WQ250960
WC220905
WQ090710
VQ980670
WQ095705
VC985662
WQ222960
WQ222912
VQ792930
VQ794977
VQ837992
VQ837994
V0793990
VQ793015
WQ230960
WQ230912
WR100240
WR072212
HF.170399
WR095326
UR797038
UR799010
W0235960
WQ235912
WR095237
WR077214
WR370010
WQ460950
WQ430980
WQ440920
HR370005
WQ455947
W0450942
WR382004
WR417010
WR443240
WR370000
WR450940
WQ220960
WQ220930
WR428016
WQ446934
VQ840990
VR793035
WR370000
WQ450930
WQ350971
WC401913
WQ426864
WQ350971
}
�UNCLASSIFIED
MISSIONS STARTING IN
PROV NO. = 42
AN XUYEN
: £ ^e^cjjcX1^^^^
:
^$
D4TS
670311
670311
670321
670321
670324
670324
670324
670325
670325
670330
670330
670331
670331
670402
670402
670404
670404
670409
67040S
670417
670417
670420
670420
670422
670422
670425
670425
67Q429
670429
670507
670507
670510
670510
670513
670513
670516
670516
670516
670516
670516
670516
670516
670604
670604
670610
670610
670614
670614
670617
670617
AGN
D
0
0
0
0
0
o
w
W
W
w
w
0
w
w
w
0
0
0
3
GALS
0
0
5400
0
2700
0
0
2700
0
3720
0
0
0
4650
0
4650
0
4650
0
5580
0
4000
0
4600
0
5580
0
3700
0
4650
0
3520
0
2790
0
2790
0
0
0
0
0
0
3690
0
5400
' 0
2800
0
5400
0
TYP
D
D
D
D
D
0
r>
0
D
D
D
D
D
D
D
r
c
0
D
0
LEG
IB
1C
1A
IB
1A
IE
1C
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
2A
2B
2C
3A
3B
1A
IB
1A
IB
1A
IB
1A
IB
UTM
WQ401918
WC426864
VR985140
VR985320
HQ450940
WR370007
WQ435995
VR990316
VR813316
VR990296
VR812296
AT960920
AT960886
VR990160
VR800160
VR990180
VR800172
VR988220
VF807220
VR983200
VR804200
VR970242
VF808242
VR965262
VR810263
VR970288
VR811289
VR984225
VR807225
VR970160
VP800160
VR984213
VR806213
VR983228
VP807228
XP025389
XP027323
XR272343
XP301370
VR300397
XR3143V7
XP300350
VR980210
VP810210
VPS70290
VR810290
VP970312
VR813312
VR940610
VR890470
�UNCLASSIFIED
M I S S I O N S S T A R T I N 'G
G
IN
PRCV NO. = 42
AN XUYEN
* # « : : * . *
* * . > ? * * *
DATE
670619
670619
670622
670622
670626
670626
670630
670630
670630
670630
670703
670703
670703
670703
670705
670705
670707
670707
670708
670708
670708
670708
670713
670713
670719
67071?
670719
670719
670720
670720
670720
670723
670723
670723
670723
670727
670727
670727
670727
670728
670728
670728
670728
670730
670730
670805
670805
670815
670815
670815
AGN
0
0
w
w
0
0
0
w
0
0
a
W
n
0
w
w
0
w
ri
'ft
W
0
GALS
5510
0
6060
0
6510
0
3570
0
2790
0
5580
0
0
0
4650
0
5580
0
40
00
0
0
0
40
00
0
5000
0
1000
0
6000
0
0
4640
0
725
0
3600
0
900 ..'
*0
5350
0
0
0
5550
0
2000
0
3000
0
1850
TYP
D
D
0
D
C
D
0
D
D
D
0
D
D
D
D
D
.. P
• .. —
D
C
D
D
n
LEG
1A
IB
1A
IB
It
IB
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
IB
1C
1A
IB
1A
16
1A
IB
1A
IB
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
1A
UTM
VQ900602
VQ850465
WQ113604
WQ006495
VR960195
VF.804195
VQ970631
VQ908473
VQ970631
VQ908473
VQ628604
V0784481
VQ697504
VQ713529
W0390840
WQ310680
WQ215685
HQ079565
V0865602
VQ817467
VQ733491
VQ743517
VR960213
VP.806213
VR965238
VR8 10240
VR965238
VR810240
W0404843
WQ375755
WQ320694
VQ943617
VQ885468
VQ943617
VQ885468
WQ029645
WQ002496
WQ029645
WQ002496
VQ832602
V0783481
VQ728493
VQ736511
VP.962234
VR807235
VR795129
VR816321
VQ863603
V0813468
VQ863603
/
f
J
/V/71"!
�DATE
670815
670316
670816
670818
67081S
670819
670819
670821
670821
670821
670821
670822
670322
670822
670822
670825
670825
670828
670828
670828
670828
670831
670831
670901
670901
670905
670905
670905
670905
670911
670911
670913
670913
570915
670915
670918
670918
670919
670919
670920
670920
670922
670922
670923
670923
670928
670928
670928
670928
671001
AGN
W
0
0
W
0
w
0
0
0
H
0
0
0
0
0
0
n
0
0
n
n
0
0
GALS
0
5600
0
4890
0
4300
0
3800
0
1900
0
3000
0
3000
0
5700
0
4000
0
2000
0
3900
0
4350
0
3850
0
0
0
5000
0
5680
0
5300
0
3965
0
3600
0
5620
TYP
D
C
D
C
C
D
C
D
D
D
D
D
D
D
D
• D
D
D
C
0
4525
0
5250
0
5000
0
0
0
4400
D
D
r
LEG
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
> IB
1A
IB
1A
IB
1A
IB
1C
ID
1ft
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
IA
IB
2A
2B
C
1A
UTM
V0813468
W0025644
V0996496
VC907602
V0857465
VQ94.8619
VQ892469
WQ053651
WQ007494
WQ053651
W0007494
VQ985634
VQ915474
VQ985634
VQ915474
WQ128670
WQ083522
. WQ230691
WQ384315
WQ230691
WQ384815
WQO 12642
VQ993505
VQ972629
W0129663
VQ859602
VQ810468
V0735490
VQ748523
VQ911603
VQ862465
WQ099658
WQ052509
WQ074652
W0031500
W0230688
WQ102579
W0172694
WQ128538
VQ894603
VQ845464
VQ932613
VG874467
W0230690
WQ360800
VC836602
VQ793480
VQ739490
VQ754530
WQ122664
�MISSIONS STARTING IN
2W1
671001
671002
671002
671007
671007
671010
671010
67101*
671014
671014
671014
671015
671015
671021
671021
671029
671029
671101
671101
671104
671104
671106
671106
671106
6-71106
671107
671107
671107
671107
671119
671119
671128
671123
671202
671202
671203
671203
671207
671207
671209
671209
671209
671209
671212
671212
671216
671216
671219
671219
671227
A-3N
GALS
AN XUYEN
$**##*******
TYP
0
0
5000
D
0
0
5500
0
0
0
2800
D
0
0
7550
C
0
0
0
0
6375
D
0
0
6775
0
0
0
7600
0
0
0
7800
D
0
0
w
7500
C
0
1000
D
0
0
6700
P
0
0
7000
0
0
0
0
7425
0
r
0
0
4700
D
0
0
5500
p
0
0
2700
D
0
0
4400
D
•0
n
4800
n
w
0
900
0
D
w
o
5325
0
5675
0
5300
r
p
0
0
0
4500
LEG
IB
1A
IB
1A
IB
IA
IB
IA
IB
2A
26
1A
IB
IA
18
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
2A
28
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
n
n
1A
IB
IA
UTM
H0078520
VR965177
VR800175
V0371603
VQ321467
VQ92.7610
VQ870465
VC800620
VQ761485
V0744489
VQ763535
WQ169690
WQ124534
WQ364786
WQ234685
VR977207
VP205207
WQ119663
HQ795210
VQ960625
V0902472
WQ073652
WQ033502
WQ073652
WQ033502
VQ890602
VQ840465
VQ724495
VG731512
WQ003635
VQ977490
VR967167
VR798167
WQ067650
WQ02549d
VQ988596
VQ972438
VQ854602
VQ808477
VQ922606
VQ866465
VG922606
VQ866465
VQ884601
V0833465
WQ083655
WG042506
VR960187
VRS03138
VQ877603
�UNCLASSIFIED
MISSIONS ST/^RT ING IN
AM XUYEN
PROV NO.
****>* **£***
nar =
671227
671229
671229
671231
671231
630429
680429
680502
680502
680502
680502
680513
680513
680517
630517
680519
680519
680524
680524
630527
680527
680530
680530
680603
630603
630605
630605
680607
680607
680611
680611
630614
630614
680618
680618
680622
680622
680702
680702
680705
630705
681031
681031
681031
681122
681122
681205
631205
681205
681205
4GN
0
0
0
w
0
G
W
3
0
0
H
H
a
w
0
w
0
w
0
w
0
a
vi
GALS
0
5000
0
5000
0
5375
0
1000
0
5000
0
6000
0
6000
0
6000
0
6000
0
6000
0
5000
0
6000
0
5900
0
5000
0
6000
0
6000
0
6000
0
6000
0
5900
0
6000
0
5000
0
0
5000
0
6000
0
0
0
TYP
D
0
D
0
D
D
C
D
D
D
D
D
D
D
C
D
C1
LEG
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
IA
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
C
D
C
D
D
D
1A
IB
1A
IB
1A
IB
1A
IB
40
1A
IB
1A
IB
2A
26
UTM
VQ828466
VR970273
VR810278
VQ914603
VQ862465
MQ09.8658
WQ053509
WQ010640
VQ984493
W0010640
VQ984493
WQ133670
WQ088552
VQ992636
VQ965485
VR960151
VR794151
WQ190659
WQ066515
WQ161678
WQ116531
WQ062651
WQ018496
WQ017635
VQ989495
VR960163
VR798163
WQ133670
WQ087523
VR970260
VR810260
VQ969630
VQ942478
WQ058650
WQ014496
WG156678
WQ111529
W0182700
WQ134540
VR970309
VR812312
WQ187702
WQ138540
WQ149676
W0106528
W0203716
VvC251658
W0208719
IV 02 5 866 6
42
�UNCLASSIFIED
DAT 6
681211
681211
681211
681211
681217
681217
631217
631217
631217
681219
681219
681219
690103
690103
690107
690107
690113
690113
690119
690119
690119
690121 .
690121
690123
690123
690123
690126
690126
690419
690419
690619
690619
690619
691228
691223
700104
700104
70010&
700108
700111
700111
700111
700111
700113
700113
700113
700113
700113
700119
700119
AGN
0
LEG
TYP
GALS ************
1A
D
6000
0
0
o
x
6000
0
C
o
0
o
0
4000
W
0
0
0
7000
0
D
0
8000
'A
D
0
9000
0
D
0
0
6000
D
0
0
0
5900
D
0
0
5400
D
0
0
VI
D
7000
0
0
n
4500
D
0
5000
D
0
0
3
7000
D
0
8
5}
5000
D
0
5000
D
0
3
4800
D
0
0
0
H
2000
C
0
' 0
0
o
w
PROV NO.
AN XUYEN
IG
MISSIONS STARTING IN
4700
0
D
IB
2A
26
1A
IB
1C
2A
28
1A
IB
1C
1A
18
1A
IB
1A
IB
1A
IB
1C
1A
IB
1A
IB
1C
1A
IB
1A
IB
14
IB
1C
1A
IB
1A
IB
1A
IB
1ft
IB
1C
10
14
IB
1C
ID
IE
1A
16
UTM
VQ969627
VQ911600
VQ833599
VC808619
VQ960630
VQ91.0610
VG850610
VQ820640
VQ830650
WQ200710
W0220690
WQ242660
VG986637
VQS58485
WQ194702
WC144545
W0143677
WQ995525
WQ088715
VQ967665
VQ964632
WQ203723
WQ088713
WQ087705
VQ975057
VQ974633
WQ203707
HQ083707
VP930180
VR820130
WQ01 1677
VC975658
VQ964554
VR830500
VR820320
WQ275710
H5135600
VR830135
VR820320
VR96839S
VP950365
VRM84367
VR813325
WR000302
VR950302
VR920298
VR870302
VR820302
VK917302
VR909205
42
�D*.TP
700119
700121
700121
700121
700125
700125
700125
700202
700202
700202
700202
700202
700202
700221
700221
700227
700227
700227
700311
700311
700311
700311
700311
700321
700321
700406
700406
700406
700406
700408
700408
700408
700408
700409
700409
700409
70040?
700410
700410
700410
700410
700421
700421
700421
700421
710123
710123
710123
710123
710124.
AGN
W
W
r»
^
0
0
W
W
0
W
n
0
W
W
GALS
0
6000
0
0
4000
0
0
3100
0
0
1900
0
0
4900
0
5000
0
0
4000
0
0
0
0
4000
0
450
0
0
0
4100
0
0
0
450
0
0
0
450
0
0
0
3000
0
0
0
900
0
0
u
W
950
TYP
D
r
D
D
C
D
C
0
K
r
V
1
W
r
p
L?G
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1C
1A
IB
1A
IB
1C
1A
IB
1C
2A
2B
1A
IB
1A
IB
2A
2B
1A
IB
2A
28
1A
IB
2A
2B
1A
IB
2A
28
1A
IB
1C
ID
14
IB
p
1C
ID
1A
UTH
VR909136
WR000295
VR921256
VP.8 79248
VR945415
VR93.0404
VR821480
VR950158
VR920155
VR890160
VR950158
VR920155
VR890160
VR945415
VR823532
VR988353
VR945291
VP850290
H001 871 7
VQ956717
VQ908705
VQ957714
WC018714
VR985147
VR990330
V0022758
VQ024782
VQ024772
VQ009778
WQO 18711
VQ911674
VQ907700
V0958716
V0022758
VQ024782
VQ024772
VQ009778
VQ022753
VQ024782
VQ024772
VQ009778
WC008715
VQ912S80
VC912685
VQ993713
VR950389
VR970398
VR973368
VR998381
VP990330
�UNCLASSIFIED
MISSIONS STARTING IN
AGN
710124
710124
710124
710124
710124
710124
710125
710125
710125
710125
710217
710217
710217
710217
710217
710217
GALS
0
0
0
0
0
0
450
0
• 0
0
990
0
0
0
0
0'
PRQV NO.
AH ?UYEN
TYP
LEG
IB
1C
l.D
IE
IF
IG
1A
IB
1C
ID
1A
18
2A
26
3A
3B
UTM
VP990370
WR005350
VR990333
WP000393
VR985405
VR976395
VR993379
VP.999381
WP010359
WR016364
VR939334
VP950403
VF939394
VR950399
VR9463S6
VR960596
UNCLASSIFIED
42
�NREC= 17724
NR6C= 17724
NP-OV=
NPRQV=
162
162
NZREC=
NZRaC=
254
254
UNCLASSIFIED
UNCLASSIFIED
�MISSIONS
DATH
660104
660104
660109
660109
660109
660109
660110
660110
660113
660113
660115
660115
660115
660115
660115
660115
660119
660119
660127
660127
660128
660123
660130
660130
660131
660131
660131
660201
660201
660205
660205
660414
660414
660414
660414
660414
660416
660416
660422
660422
66,0529
660529
660529
660529
660529
660529
670323
670328
670328
670328
STARTING
AGfJ
0
0
0
n
0
n
0
0
0
0
n
0
0
0
0
0
0
0
0
IN
GALS
3800
0
2000
0
2000
0
2000
0
2450
0
4000
0
4000
0
0
0
4000
0
900
0
4000
0
3900
0
3900
0
0
4000
0
4000
0
3000
0
0
0
0
3800
0
2500
0
2000
0
0
0
0
' 0
2790
0
0
0
BAC
PROV NO. =
LIEU
TYP
D
\ P
\
0
D
D
D
D
D
0
D
D
D
D
D
D
D
r>
C
n
LEG
1A
IB
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
2A
26
1A
IB
1A
IB
1A
IB
LA
IB
1A
IB
1C
1A
IB
1A
IB
1A
IB
1C
2A
28
1A
IB
1A
IB
LA
IB
1C
10
IE
IF
1A
IB
2A
26
UTM
WR 800 18 5
WR720145
WR805180
HR640113
WR 802 185
WR63.5117
.XR280345
XR2S0400
WR800200
WR650120
WR800225
WR675150
XR260420
XR310450
XR250340
XP.3 10330
WR453125
WQ465955
WR800200
WR640120
WR455120
WQ460955
WR450080
HQ460960
XR230420
XR320455
XR260340
WP780170
W0500000
WP450125
WQ460965
WR970340
WR970320
WR923302
WR805180
WR760175
WR453125
WQ470960
WR445125
WQ455960
WR975343
WR970324
WR952302
WR945314
V.R968328
WP975305
XROSOSSO
XP030320
VR250340
KR290400
43
�OATS
670328
670401
670401
670401
670405
670405
670405
670407
670407
670407
670407
670419
670419
670424
670424
670427
670427
670430
670430
670504
670504
670518
670518
680812
680312
680812
680812
680812
680312
630812
680812
680813
680813
630813
680313
680814
680814
630814
6S0814
680816
680816
680922
680922
630927
680927
680927
630927
680927
680927
631008
AG^4
GALS
TYP
0
0
2790
0
0
0
3
u
w
w
w
w
w
w
w
w
w
n
4000
1860
P
0
2790
C
0
4650
D
0
2660
D
0
4650
0
0
3345
D
0
5580
D
0
5580
0
826
0
0
0
0
0
0
0
889
0
0
0
665
0
0
0
4000
6000
0
0
n
0
0
0
0
P
6000
n
s
s
s
D
n
p
0
0
0
0
0
3
6000
L5G
2C
1A
IB
1C
1A
IB
1C
1A
IB
1A
18
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
1A
IB
2A
2B
3A
3B
4A
43
1A
IB
2A
2B
1A
IB
2A
2B
1A
IB
1A
IB
1A
IB
2A
2B
3A
n
33
14
UTM
XR310340
WR440120
WR420010
WR440001
WR460120
WR450020
WQ480970
WP540045
WR720140
XR072350
XR157377
WR460120
WQ480970
WP460120
WG470970
WR437118
WQ445932
WR472120
W0483975
WP456U9
WQ473964
WR485058
WQ375843
WS535212
WS550192
WS545214
WS539191
WS925339
WS926333
WR948350
WR950342
WR550230
WR555200
WP610215
WP600235
WR350205
WR365235
WR415240
WR420215
WR311172
WR&40109
WR740150
WR570080
XR057410
XR025387
VR023363
WR970345
WR9453515
WR937380
WR4090'53
�UNCLASSIFIED
MISSIONS STARTING IN
DAT?
681008
681008
681008
681005
681012
681012
681107
681107
681107
681107
681117
631117
631117
681117
631201
631201
681201
631201
690201
69Q201
690201
690201
690209
690209
690209
690209
690215
690215
690215
690215
iGN
0
0
0
0
0
0
0
GALS
0
0
0
0
3000
0
6000
0
0
0
6000
0
0
0
5000
0
0
0
6000
0
0
0
9000
. 0
0
0
6000
0
0
0
BAG LIEU
************
TYP
LEG
IB
1C
ID
IE
r>
0
r>
D
0
0
D
IA
IB
1A
IB
2A
2B
IA
IB
2A
26
1A
IB
2A
2B
1A
IB
2A
28
1A
IB
2A
2B
1A
IB
2A
28
PROV NO.
UTM
WR481053
WR533038
WR488107
WR430106
WP894355
WR928397
WR 40804 8
HR500048
WR487102
WR429102
WR404042
WP500042
WR482098
WR425093
WR403037
WR500037
WR480092
WP424092
HP402034
WR500034
WP.478087
WR424087
WP400027
WR500027
WR476081
WR423084
WR487102
WR430102
WR408043
WR500048
43
�NPFC= 18010
NREC= 18010
NPRQV=
NPPOV=
43
43
NZR9C=
NZRFC=
87
67
UNCLASSIFIeO
UNCLASSI FI5S1
�MISSIONS STARTING IN
DATE
690218
4GN
W
GALS
184
CHAU DOC
TYP
S
PROV NO. = 44
LEG
1A
UTN
VS967476
UNCLASSIFIED
UfJCLASSIF!':0
�NREC= 18139
NREC= 18139
MPROV=
NPROV=
1
1
NZREC=
NZREC=
0
0
UNCLASSIFIED
UNCLASSIFIED
�MISSIONS STARTING IN
DATE
630104
680104
680104
680104
680104
680104
680104
680104
680108
680108
680108
680108
680806
631228
690126
690126
690307
690307
690315
690315
690315
690315
690315
690315
690316
690316
690316
690316
690316
690316
690408
700209
700209
700209
700209
700209
70020<5
700209
700209
700212
700212
700212
700212
AGN
W
0
0
W
W
W
W
W
M
d
0
0
GALS
600
0
0
0
1400
0
0
0
2400
0
0
0
735
130
790
0
635
0
805
0
0
0
0
0
640
0
0
0 .
0
0
1245
880
0
0
0
0
0
0
. 0
550
0
0
0
SA DEC
' TYP
D
PROV NO.
LEG
1A
IB
r
0
s
s
s
s
s
s
s
F
E
2A
26
1A
IB
2A
26
1A
IB
2A
2B
1A
1A
1A
16
IA
IB
1A
2A
3A
38
•4A
4B
1A
IB
2A
28
3A
38
1A
1A
IB
2A
2B
3A
38
4A
4B
IA
IB
2A
28
UTM
WS932270
WS904220
WS910220
WS899268
WS932270
WS904220
WS910220
WS899268
WS929270
WS904222
HS909220
WS900270
WS780420
WS910270
WS908248
HS900218
WS977302
WS977260
WS897281
WS892268
WS940287
WS926260
WS894258
WS910218
WS977302
WS978192
WS883307
WS835284
WS866289
HS847263
V*S890300
WS952241
WS956270
WS850231
WS875262
HS836259
WS856277
WS837258
WS856278
WS880220
WS860250
WS856278
WS835258
46
�
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
013
Folder
The folder containing the original item.
0108
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Creator
An entity primarily responsible for making the resource
U.S. Air Force Communications Service
Description
An account of the resource
<strong>Corporate Author: </strong>Headquarters, U.S. Air Force, Air Force Data Services Center, Air Force Communications Service
Date
A point or period of time associated with an event in the lifecycle of the resource
1965
Title
A name given to the resource
HERBS Tape: Defoliation Missions in South Vietnam, 1965-1971. Data by Province.
Subject
The topic of the resource
HERBS database
herbicide application
Ranch Hand
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/d092d7c887119af77f383247b4043d2c.pdf
e01c1611f48ad0559a09d53973647cb5
PDF Text
Text
Item ID Number:
00109
Author
Corporate Author
U
-S- Army & Joint Services Environmental Suuport
Group
Report/Article Title Services Herbs Tape - A Record of Helicopter and Ground Spraying Missions,
Aborts, Leaks, and Incidents
Journal/Book Titlo
Year
1Q
Month/Day
September^
Color
85
n
Number ofhnauos
142
DflSCrlptOn Notes
Funded/Sponsored by HQDA; DAAG-ESG; covers years 1962-1971; Figures 1 and
2 (Maps) were found inserted in the front cover of the copy of this document that also
has margin notes.
Thursday, December 28, 2000
Page 109 of 157
�US ARMY AND JOINT SERVICES
ENVIRONMENTAL SUPPORT GROUP
Services Herbs Tape
12 September 1985
�loe
h Linh
•marcatton Line
South China
Sea
Kien Giang)
South Vietnam
«j
°
Gfa
—*-•-•—
®
O
Da _Lat
Gulf
Of
hailand
106 ARE
1
NOT
NECESSARILY
AUTHORITATIVE
International boundary
Province boundary
National capital
Province capital
Autonomous municipality
Railroad
Road
108
1
Base 500676 5-72
FIGURE 1. 1972 Map of South Vietnam Showing Provinces and Major Cities,
�SOUTH VIETNAM
DEFOLIATION MISSIONS
ALL MISSIONS
(
Red = Crop
Hue = Defoliant
Sreen = Unknown
F-IGURE...--2-.---1-9-74-National Academy of Sciences Computer Printout of All
Defoliation Missions in South Vietnam, 1965-1971.
�Unclassified
SECURITY CLASSIFICATION Of THIS PAGE
REPORT 06CUMENTATION PAGE
1*. REPORT SECURITY CLASSIFICATION
1b RESTRICTIVE MARKINGS
Unclassified
3 DISTRIBUTIONi / AVAILABILITY OF REPORT
2» SECURITY CLASSIFICATION AUTHORITY
26. OECLASSIFICATION/ DOWNGRADING SCHEDULE
y/Pl
4. PERFORMING ORGANIZATION REPORT NUM8ER(S)
6t NAME OF PERFORMING ORGANIZATION
U.S. Army & Joint Services
Environmental Support Group
fib
T.
._
S MONITORING ORGANIZATION REPORT NUMBER(S)
OFFICE SYMBOL
6c. ADDRESS (Crty, Stttt, »nd ZIP Codt)
7b ADDRESS (Ofy, Sf*«. tnd tIPCodr)
Room 210J Riddell Building"
1730 K Street, N.W.
Washington, B.C. 20006-3868
Sa. NAME OF FUNDING /SPONSORING
ORGANIZATION
7*. NAME OF MONITORING ORGANIZATION
tf
ippiictbit)
DAAG-ESG
8b. OFFICE SYMBOL
(tf tpplkibh)
9. PROCUREMENT INSTRUMENT IDENTIFICATION NUMBER
HQDA
10. SOURCE OF FUNDING NUMBERS
8c ADDRESS (City, State, tntl ZIP Cod*)
PROGRAM
ELEMENT NO
PROJECT
NO
TASK
NO.
WORK UNIT
ACCESSION NO
1 1 TITLE f/rv/vcte Security Cltttifkttion)
(U) Services Herbs Tape - A record of helicopter and ground spraying missions, aborts,
leaks, and incidents.
i
12 PERSONAL AUTHOR(S)
13» TYPE OF REPORT
13b TIME COVERED
F*OM 1962
Summary
1 4 DATE OF REPORT (Yw, Month. 0*y)
ro
.L97L
1985
IS PAGE COUNT
September 12
138
16 SUPPLEMENTARY NOTATION
17.
18. SUBJECT TERMS (Continue on r*v*n* If n«*0«ry tnd fcfcnofy by W<x* nvmbtr)
COSATI COOES
FIELD
GROUP
SUB-GROUP
Herbicides, MACV, Agent Orange, Herbs Tape, helicopter
spraying, UTM grid coordinates.
N.
_ _
_
_
_
.
.
.
.
.
_
_
.
19 ABSTRACT (Continue on nvers* If ntttotry tnd identify by Woe* numbtf)
On 21 May 1980, the Army Agent Orange Task Force was formed to provide military research
support to several government agencies concerned with possible adverse health effects of
Vietnam veterans to the herbicide known as Agent Orange. Earlier, the National Academy
of Sciences (NAS) conducted an investigation for the Defense Department to study the
effects of herbicides used in Vietnam. During the conduct of the MAS study an automated
data base of U.S. Air Force C123 Hanch Hand spray missions was developed. As various
protocols were being designed for epidemiologic and case control studies, the need for an
automated data base of Non-Ranch Hand spray missions was recognized to provide data for
jse in studies about possible exposure opportunities for U.S. ground troops. This report
documents helicopter, ground spraying missions and Incidents.
20 DISTRIBUTION /AVAILABILITY OF ABSTRACT
S3 UNCLASSIFIED/UNLIMITED D SAME AS RPT.
22a NAME OF RESPONSIBLE INDIVIDUAL
Richard S. Christian
00 FORM 1473, 84 MAX
21. ABSTRACT SECURITY CLASSIFICATION
O DTK USERS
Unclassified
(2b. TELEPHONE (Vtdwd* Art«Cod») 22c OFFICE SYMBOL
C202) 653-1828
DAAO-ESG.. 93 APR tdition m«y b* used until mhawMd.
SECURITY CLASSIFICATION Of THIS PAGE
�DEPARTMENT OF THE ARMY
US A R M Y & JOINT SERVICES ENVIRONMENTAL SUPPORT CROUP
1730 K STREET N.W. ROOM 21O
WASHINGTON. DC 2OOO8-3868
REPLY TO
ATTENTION OF
DAAG-ESG
12 September 1985
SUBJECT: SERVICES HERBS TAPE
A RECORD OF HELICOPTER AND GROUND SPRAYING MISSIONS. ABORTS, LEAKS, AND INCIDENTS.
I. BACKGROUND.
Between 1962 and 1971 herbicides were tactically disseminated in South Vietnam
to deny the enemy protective foliage cover and to destroy his crops. In response
to public concerns about possible adverse health effects and ecological considerations, The Department of Defense contracted with the National Academy of
Sciences (NAS) to study the potential effects of herbicide applications. During
the investigation the NAS examined the U.S. Military Assistance Command, Vietnam,
(MACV) J-3, Chemical Division herbicide records. These records contained primarily Air Force Ranch Hand fixed wing herbicide missions which were recorded
beginning in 1965. U.S. Army helicopter missions were first entered into the
records in 1968. During the conduct of the study NAS prepared an automated record
known as the "HERBS Tape". The Tape contains spray missions data in terms of
gallons, dates, type of herbicide, grid locations, and where spray runs started
and ended. Mission entries were verified from a variety of record collections and
aerial photographs. Over 6000 fixed wing spray missions are documented on the
Herbs Tape, but it lacks important information on most of the helicopter spray
missions prior to 1968. In addition, the tape has no information whatsoever on
defoliation accomplished by ground vehicles or backpack spraying by Army personnel. The ground spraying took place around the perimeters of base camps, fire
bases, air bases and other fixed military camps. Heavy cover areas along major
highways were also defoliated to prevent enemy ambushes of convoys.
U.S. Army Chemical Section records and other documentation contain the data
about helicopter, backpack, and other types of ground spraying. The data needed
to be retrieved, organized and automated for use in cohort and case control
studies of Agent Orange. The following report provides the methodology and
results of the review of the Vietnam War records collection, to document herbicide
spraying not included in the original NAS HERBS Tape.
II. INTRODUCTION.
Critical elements in the determination of Agent Orange exposure opportunities
are time, proximity and specific duties of U.S. ground troops, in relation to the
herbicide spraying. Researchers identified, retrieved and researched documents
for all types of herbicide spray operations.
�Data was then recorded in a concise manner and automated. Data about aborts,
leaks and spills of herbicides was carefully examined and documented. This new
data base was designated the "Services Herbs Tape" when originally conceived,
since it was thought that the records of other services would show instances of
ground spraying operations. Only one Navy mission could be documented from
available records. The Tape primarily contains data obtained from U.S. Army troop
records.
HI. DOCUMENTATION USED TO DEVELOP DATA BASE.
U.S. Army troop records were primarily used in the search for additional
herbicide spray missions. U.S. Military Assistance Command, Vietnam joint records
were used to document Ranch Hand fixed wing spray missions not listed on the WAS
HERBS Tape. This was due to NAS documenting only Q6% of the Ranch Hand missions.
During the course of the research to build the Services Herbs data base an additional 557 Ranch Hand fixed wing missions were identified/verified. *However,
some of these still cannot be absolutely verified through backup documentation and
are included in this report. It should be noted that when only limited data was
available it was felt that the mission should be documented with whatever information was found to ensure the fullest coverage of possible exposure to any of the
herbicides. The below listed categories of records were used when constructing
the data base of the "Services Herbs Tape".
a.
b.
c.
d.
e.
f.
g.
h.
Daily Air Activities Reports (DAARs).
MACV Project Files by province and by year.
Operational Reports of Lessons Learned (OR-LLs).
Division Chemical Officer Reports.
MACV messages.
Daily Journals.
Defense Advanced Research Projects Agency Records,
Trip Reports.
Documentation dates back to the original MAAG VN OPLAN 1-61 (U) applicable to
the Military Assistance Advisory Group, Vietnam, predecessor organization to MACV,
28 December 1961. Records created by the Vietnamese Air Force (VNAF) and Joint
Planning Committee (202) were also reviewed for early spray missions.
*Research continues in an attempt to locate backup documentation.
�IV. METHODOLOGY.
Basic records analysis was used to identify the documents needed for this
project. Records were ordered from the Federal Records Center, other DOD activities, records holding areas or current files areas.
The following paragraphs describe the stepwise research and documentation
effort:
Step One. Examine GSA Standard Forms 135, "Records Transmittal and Receipt"
for the Vietnam war collection and other organizational retirements for documents maintained on any type of herbicide spraying activities. Identify the
accession number and location in the repository and forward the request to
retrieve the documents. In addition, during the discovery process in connection
with the Class Action Litigation, records researched were identified which contained specific references to herbicides.
Step Two. Separate the document (s) which contain information about spray
operations and reproduce backup papers for each herbicide spray application by
date. Originals are immediately returned to the file folders in order to ensure
integrity of the files.
Step Three. Data abstraction. Precise information about the mission/spray
needed for- epidemiological and other research uses were recorded on standard
work sheets. Entries are described in the next section.
A verification file documenting each entry listed in the "Services Herbs
Tape" was established separate from the master source records in case further
research might be required as additional confirming data later becomes available.
V. REPORT FORMAT AND ORGANIZATION.
The Services Herbs Tape has a standard IBM 80-column format form.
Descriptions of the contents printed in the numbered columns and the respective
code sets are described below beginning at the first left column of the page:
A
- MISSIONVTDATE; The date the herbicide was sprayed is given in columns 1
through 6.Columns 1 and 2 - the year (ex. 69), columns 3 & 4 - the month (ex,
06 for June), columns 5 and 6 - the date in the month (ex. 05 for 5th day in the
month) column 7 is always blank.
�B. COMBAT TACTICAL ZONE; (CTZ) Column 8 contains numerals from 1 to 4
inclusive indicating the Combat Tactical Zone in which the herbicide was disseminated, ex. 3 = the third Combat Tactical Zone. The Combat Tactical Zone is a
geographical boundary used for military Corps area operations. Vietnam was
divided into four CTZ's defined as I CTZ in the extreme North, II CTZ in central
Vietnam, III CTZ South of CTZ II and included Saigon, and IV CTZ which included
the Delta area in the southern part of Vietnam.
Columns 9 through 16 inclusive are always blank.
c
- PROVINCE; Columns 17 & 18 designate the Province in Vietnam in which the
spraying of the herbicide tracks started. The numerical codes used for provinces were as follows;
Code Province
Code Province
01
02
03
04
05
06
07
08
09
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
QUANG TRI
THUA THIEN
QUANG NAM
QUANG TIN
QUANG NGAI
KONTUM
BINH DINH
PLEIKU
PHU BON
PHU YEN
DARLAC
KHANH HOA
NINH THUAN
TUYEN DUG
QUANG DUG
LAM DONG
BINH THUAN
BINH TOY
LONG KHANH
PHUOC THANH
PHUOC LONG
BINH LONG
BINH DUONG
TAY NINH
HAU HGHIA
BIEN HOA
PHUOC TUY
LONG AN
GIA DINH
GO CONG
KIEN TUONG
KIEN PHONG
DINH TUONG
KIEN HOA
Code Province
35
36
37
38
39
40
41
42
43
44
46
91
92
93
94
95
96
VINH BINH
VINH LONG
AN GIANG
KIEN GIANG
CHUONG THIEN
PHONG DINH
BA XUYEN
AN XUYEN
BAG LIEU
CHAU DUG
SA DEC
HUE
DA NANG
CAM RANH
DALAT
VUNG TAU
SAIGON
Columns 19 through 26 are blank.
D>
AGENT USED; Column 27 shows the type of herbicide dissiminated during the
mission. Alpha character codes used are as follows;
�Code
Agent
0
W
B
P
D
R
S
T
U or blank field
Orange
White
Blue
Purple
Dinoxol
Pink
Pink & Green combination
Trinoxol
Unknown
Column 28 is blank.
E. GALLONS; Number of gallons of herbicide dispensed during the mission cited,
ranging from 1 gallon to several thousands of gallons. Columns 29 through 33
indicate actual gallons used; example: 06000 indicates 6,000 gallons delivered
in this mission.
Columns 34 is blank.
F. TYPE OF MISSION; Shown in column 35 only. This column includes a brief
description of the purpose of the mission. The alpha codes used are as follows;
Code
'
C
D
E
F
P
S
W
Discriptipn '
Crop destruction mission
Defoliation mission
Enemy infiltration/supply route
Friendly line of communication
Perimeter spraying around an installation
Enemy Supply Cache
Waterway/Landing Zone
Columns 36 through 59 are blank.
G. START. TURN. STOP MISSION DESIGNATOR; Columns 60, 61 & 62 are used to
designate the spray track flown by a herbicide mission, where each track point
(eg. 1A) has a UTM grid location (eg. BQ530280) associated with it in columns 64
through 71. The digits in columns 60 & 61 identify the track number. Column 60
will be blank for nine or less tracks. Column 62, identified by an alpha
character in the field, are track start, turn and stop codes. The character "A"
in column 62 indicates the starting point. A subsequent character (eg. "B")
indicates the UTM grid coordinate at which the aircraft changed flight direction. Flight directions may change more than once in one spray mission. The
�final character in the string indicates the UTM grid coordinate at which the
spraying was stopped. A successive number in columns 60 & 61 indicate that on
the same mission after completing the previous spray track, the aircraft
accomplished an additional spray track from point "A" (column 62) UTM grid coordinate to the last character of the string.
See example following:
Example; (a two track mission is shown by fixed wing aircraft)
Cols
60-61 (Start Point, first track)
(Point of direction change, first track)
(Spray Stop Point, first track)
(Start Point, 2d Track)
(Stop Point,_2d Track)
1
1
1
2
2
Cols
62
Cols
64-71
A
B
C
A
B
BQ530280
BQ550240
BQ570230
BQ580280
BQ580240
Column 63 is blank.
H. UTM COORDINATE; Columns 64 through 71, inclusive are used to give the
geographic locations of where herbicide spraying took place based on the
Universal Transverse Mercator (UTM) grid designations of Vietnam. As in the
example above grid square BQ represents a specific grid square 100 kilometers
(km) on a side. The first three digits to the right of BQ, 530 represents a
vertical line 53 km east of the west boundary of square BQ. The next three
digits in the example above, 280 represents a horizontal line 28 km north of the
South boundary of grid square BQ. The intersection of these two lines 530 and
280 is the location of the start point for spraying of the first track. When
the track points 1A, 1B and 1C are connected by straight lines between these
points the mission spray track is plotted on the map within grid square BQ.
Column 72 is always blank.
I. SOURCE OF DATA.ENTERED.ON THIS LINE; Column 73 shows the information source
of the mission or incident data entered on this line.
The codes are as follows:
R = Ranch Hand data files
S = Services Herb Tape files
Column 74 is always blank
�J. INCIDENT CODE; Column 75 is used to denote entries concerning unusual incidents. The following alpha codes indicate why these entries are considered
"incidents":
Code
Incident definition
A
E
L
R
S
Z
Abort of mission or aircraft.
Crash with herbicide load aboard aircraft.
Leak of herbicide took place.
Spray was made on wrong target.
A herbicide spill took place at this location.
An emergency dump of herbicde took place.
Column 76 is always blank.
K<
TYPE OF SPRAY MISSION; Column 77 indicates through use of the following
listed alpha codes by what means the spraying mission was accomplished:
Code
Definition
F
G
Fixed wing aircraft did the spraying.
Ground equipment (truck, buffalo turbine or back-pack sprayer)
was used to do the spraying.
_A helicopter was used to do the spray mission.
H
Columns 78 through 80 are always blank.
List of Appendices
Appendix A. Consolidated Services Herbs Tape printout.
Appendix B. Mission per date of the records.
Appendix C. Summary report of missions by year and gallons of herbicide.
Appendix D. Unknown chemical missions.
�UNCLASSIFIED
XXXXX
XXXXX
xxxxxxx
xxxxxxx
XX
X
XX
XXXXXX
xxxxxxx
X
XX
XX
XX
XXXXX
XXXXXX
XX
X
XX
XXXXXX
XXXXXX
xxxxxxx
xxxxxxx
XX
xxxxxxx
xxxxxxx
XXXXX
XX
XX
XX
XX
XX
XXXXX
XX
XX
XX
XX
xxxxxxx
xxxxxxx
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX XX
XX XX
XX
XX
XX
XX
X
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX XX
XXXX
xxxxxxxx
XXXXX
XXXXX
XXXXX
XXXXXX
xxxxxxx
xxxxxxx
xxxxxxx
X
XX
X
XX
X
XX
XXXXXX
XXXXXX
XX
XX
X
XXXXXX
XXXXXX
XX
X
XX
xxxxxxx
xxxxxxx
xxxxxxx
'XX
xxxxxxxx
XXXXX
XXXXX
XXXXX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XXXXXX
XXXXXX
XXXXXX
XXXXXX
xxxxxxx
xxxxxxx
xxxxxxx
xxxxxxx
XX
X
XX
XXXXXX
XXXXXX
XX
XX
X
XX
XX
XX
XX
XX
XX
XXXXXX
XXXXXX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XXXXX
xxxxxxx
XXXXX
XX
XX
xxxxxxx
XXXXXX
XX XX
XX
XX
XX
XX
XX
XX
Appendix A Page 8
XX
XX
XX
XX
XX
XX
xxxxxxx
xxxxxxx
XXXXXX
XXXXXX
UNCLASSIFIED
XX
XXXX
XX XX
XX
XX
xxxxxxxx
xxxxxxxx
• xx
xx
XX
XX
XX
XX
XX
XX
xxxxxxxx
xxxxxxxx
XX
XX
XX
XX
XX
XX
XX
XX
X
XX
XX
XXXX
XX XX
XX
XX
xxxxxxxx
xxxxxxxx
XX
XX
XX
XX
XX
XX
XX
XX
�UNCLASSIFIED
YYMMOD CTZ PRO
H
GAL
T
LEG
COORD
S I M
Page 9
YYMMDD CTZ PRO
H
GAL
7
LEG
COORD
S I M
• m
SOS 198
610810
61 0824
610824
610907
6110
620110 3
620110
620201 3
620202 3
620203 3
620203 3
620204 3
620205 3
620206 3
620207 3
620208 3
620209 3
620210 3
620211 3
620212 3
620213 3
620214 3
620214 3
620214
620215 3
620215 3
620215
620216 4
620217 4
6203
620305 3
600
293
620903
620904
620904
620905
620905
600
296
620906
620907
620907
620920
620920
62092 1
62092 1
620924
620924
620927 4
620927
620930
620930
621001
621001
621003
621003
621004
621004
621008
621008
U
D
0
D
T
P
26
D
26
26
26
26
26
26
26
26
26
26
26
26
26
26
26
21
B
P
P
P
P
P
P
P
P
P
P
P
P
P
D
0
P
0
D
D
D
D
D
D
D
D
D
D
D
D
26
19
P
P
D
D
42
42
P
P
P
P
D
D
26
P
P
0
U
U
U
U
U
U
U
U
35
U
U
U
U
U
U
D
1A YC607815
1A AR769898
1A XT770580
1B XT790550
1A XT766616
1A XT995145
1A XT103017 S
1B XT1 14019
1A YT072063 S
1A YT082041 S
1A XT978147 S
1A YT 100024 S
1A YT103016 S
1A YS112995 S
1A YS217825 S
1A YS213813 S
1A YS240770 S
1A YS2S5710 S
1A YS278652 S
1A YS380585 S
1A YS378565 S
1A YS386558 S
1A YS245710 S
1A YT080757 S
1B YT 180835
1A YS365535 S
1A YT685028 S
1B YS765985 S
1A V08 10735 S
1A VR820050 S
1A XT995145
1A YS006835 S
1A V0808980
1B VR970028
1A V0808980
18 VR970028
1A V0808980
1B VR970028
1A V0808980
1B VR970O28
1A V0808980
1B VR970028
1A W0003690
1B W0034770
1A W0003690
1B W0034770
1A W0093715
1B W0064805
1A XR718693 S
1B XR665710
1A WQ220720
18 W03 10760
1A W0220720
1B W03 10760
1A W0220720
18 W03 10760
1A W0093715
1B WQ064805
1A VR844520
1B VR990386
F
F
F
G
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
* •
621009
621009
621010
621010
621011
621011
621121 3
621122 3
621123 3
621214 2
621214
621218 2
621218
621224 2
621224
630216 1
630218 1
630218
630218
630218
630219 1
630220 1
630224 1
600 4
366
630606
600 4
367
630607
600 4
368
630608
630609 4
630609
630715 3
630715
630716 3
630716
630717 3
630717
630718 3
630718
630719 3
630719
631026 1
631026
631027 1
631027
631029 1
631029
631031 1
631031
631113 3
631 113
631114 1
631114
631116 1
631116
631119 2
631119
631121 3
631122 3
631123 3
U
U
U
21
21
21
1O
U
U
U
P
C
C
C
D
07
P
01950 D
0?
P
01750 D
03
03
U
U
C
C
1A
16
1A
1B
1A
1B
1A
1A
1A
1A
1B
1A
1B
1A
1B
1A
1A
VR344520
VR990386
VR844520
VR990386
VR844520
VR990386
YT6 10880
YT520810
YT580810
C0254276
C0270233
CR030130
CR055090
CR030130
CR055090
YC569828
YC550980
S
S
S
S
H
H
H
F
S
F
S
F
5
S
H
H
H
H
H
H
H
H
F
1A YC620970 S
U
U
03
03
03
42
P
C
C
C
00985 W
42
P
W
42
P
W
42
P
W
26
P
F
26
P
F
26
P
F
26
P
F
26
P
F
05
P
D
05
P
0
05
P
D
05
P
D
19
P
F
U
P
P
05
P
0
05
P
D
12
P
F
21
21
21
B
B
B
C
C
C
UNCLASSIFIED
1A YC569830 S
1A YC570820 S
1A YC568852 S
1A YC556863 S
1A YC542864 S
1A V0824613 S
1B V0985665
1A V0824613 S
1B VQ985665
1A WO 134660 S
16 WO 134605
1A W0 134660 S
1B WO 134605
1A YT085087 S
18 YT135100
1A YT085087 S
18 YT135100
1A YT085087 S
1B YT135100
1A YT172122 S
1B YT194127
1A YT222129 S
1B YT257121
1A AS990025 S
16 BS040055
1A AS990025 S
1B BS040055
1A BS205215 S
1B BS250218
1A BS250218 S
1B BS270250
1A YT2 17554 S
1B1A
1B
1A
1B
1A
1B
1A
1A
1A
YT364485
83182182
BS204206
BS040055
BS070115
BP940194
BP950205
YT6 10880
YT520810
YT580810
F
F
F
H
H
H
H
H
F
F
F
F
F
S
F
S
F
S R F
S
S
S
H
H
H
�WIVVsL.JwlO
YYMMDD CT2 PRO
H
GAL
T
LEG
COORD
S I M
Pag;e 10
YYMMDD CTZ PRO
H
GAL
T
LEG
COORD
S 1 M
* •
631208 2
631208
631209 2
631209
631223
631223
640131 4
640131
640205 4
64020S
640302 1
600 2
434
600
434
600 2
434
640304
640304 2
640304
640304 2
640304
640304 2
640304
640419
640419
602
440
602
440
640421 "
640421
640422 4
640422
640422
640422
640422
640422
640423
640423
640424
640424
640425
640425
640430 4
603
440
640526 4
640526
640531 1
640531
640624 1
640624
640625 1
640625
602 1
466
640626
640708
600
478
640708
600
478
600
478
600
478
640708
600
478
600
478
13
P 01950 F
13
P 01950 F
U
42
P
F
42
P
W
01
07
P 01950 D
U
D
07
U
D
07
U
D
07
U
D
07
U
D
P
P
P
42
P
P
P
P
P
P
P
42
P 040
00
33
P 00100
02
P
F
02
P
F
02
P
F
03
P
F
P
P
P
1A BN636564 S
F
1B BN704635
1A 8N688564 S
F
1B BN70763S
1A WR07S218
16 VR989390
1A WRO78218 S
F
1B VR989390
1A VR970380 S
F
1B VR790310
1A XD823S36 S
F
1A 8R740664 S
F
1B SR727662
1A BR7226S2 S
F
1B BR73S658
1A BR744649 5
F
1B BR725649
1A BR732673 S
F
16 BR734677
1A BR744673 S
F
1B BR746676
1A XS313579
1B XS430637
1A XS3 13579
1B XS430637
1A XS313579
1B XS430637
1A W0123915 S R F
18 WO 11 7889
1A WR 1 0 4
900
1A V0780690
1A XS313579
18 XS430637
1A XS313579
1B XS430637
1A XS313579
1B XS430637
1A XS3 13579
18 XS430637
1A W0328774 S Z F
18 WQ370774
1A XS313579 S Z F
18 XS284596
1A YC375986 S
F
18 YC522815
1A Y0680090 S
F
18 Y0602060
1A ZC070860 S
F
18 YC923873
1A ZC120515 S
F
1B Z 0 7 0
C040
1A ZT220030
18 AN770990
1C ZS2305OO
10 AM030090
1A ZT 150290
18 ZT2202SO
1C ZT160190
10 ZT260180
1A AN780400
640708
600
478
640708
640722
602 1
480
640826
600
495
600
495
600
495
600
495
600
495
600
495
600
495
64O905
6409O5
600
495
600
495
600
495
640926 3
641003 2
641003
641003
641003
641003
64 1004
6410O4
641004
641004
641004
641005
641005
641005
641005
641005
641006
641006
641006
641006
641006
641011
641011
64101 1
641011
641011
641012 3
641013
641013
641022 1
641022
641119 3
641222 1
641223 1
641223
641223 1
641223
641223 1
641224 1
650101 1
650101
650111 3
03
P
P
U
P
P
P
P
26
21
P
P
P
C
U 000
40
P 000
20
P 000 .
20
P 000
20
24
03
P
U 000
20
U
P
F
23
03
03
P 00110 D
P
P
P
F
03
U
03
02
06
P
P
U
P
U 000 0
20
18
U 000D
30
UNCLASSIFIED
F
1B AN840480
1C AN740290
10 AN840290
1A W0 140960
1A YC650250 S
1A YC672254
1A ZT 150290
18 ZT220280
1C ZT160190
10 ZT260180
1A ZT220030
18 AM770990
1C Z 2 0 0
S350
10 AM030900
1A AN780400
1B AN840480
1C AN740290
1D AN840290
1A YS140980 S
1A YU470000 S
2A YU580000
3A YT670930
4A YT670760
5A YT470760
1A YU4700OO
28 YU580000
3C YT670933
4D YT670760
5E YT470760
1A YU470000
28 YU580000
3C YT670933
40 YT670760
5E YT470760
1A YU470000
28 YU5SOOOO
3C YT670933
40 YT670760
5E YT470760
1A YU470000
28 YU580000
3C YT670933
40 YT670760
5E YT470760
1A XT550900 S 2
1A YT630830
• 1A YT630830
1A ZC070870 S
18 ATS 10850
1A XTS73237 S
1A-YC672254 S
1A ZC070870 S
18 ATS 10850
1A YC923873 S
18 ZC 1205 15
1A YC650250 S
1A YC4 15450 S
1A YB7205OO S
18 YB700340
1A YS916757 S
F
F
F
F
F
H
F
F
F
F
F
F
F
�UNCLASSIFIED
YYMMDO CTZ PRO
650111
650112 3
650112
650113 3
650113
650113
650113
650113
630113
650118 3
650118
650118
650118
650119 3
650119
650121 3
650122 3
650122
650123 3
650123
650124 3
650124
650124
65012.4
650125 3
650125
650125
650125
650126 3
650126
650126
650126
650127 3
650127
650127
650127
650129 3
650129
650201 3
650201
650201
650201
650202 3
650202 '
650202
650202
650203 3
650203
650203
650203
650204 3
650204
650204
650204
650205 3
650205
650205
650205
650206 3
650206
H
GAL
T
27
U 03000 D
19
U 000 D
30
19
U 000 D
20
18
U 000D
20
26
23
P 01925 P
P 000D
40
23
U 000D
80
24
U 000D
70
24
24
24
U 000D
70
U 000D
70
U 000D
70
18
U 000 0
20
19
U 05500 D
19
U 03500 0
19
U 05500 D
19
U 05500 0
19
U 05300 D
19
U 050 D
50
LEG
COORD
S I M
16 YS980800
1A YS615830 S
1B YS630910
1A YT447332 S
1B YT475340
2A YT501344
2B YT555362
3A YT585390
3B YT6 18427
1A YS650076 S
1B YS800970
2A YS908754
2B YS980800
1A YS884995 S
16 YT920O50
1A YS 140980 S
1A XT480430 S
1B XT545327
1A XT480430 S
1B XT545327
1A XT480430 S
1B XT440410
2A XT545327
28 XT500314
1A XT480430 S
1B XT440410
2A XT54S327
2B XT500314
1A XT480430 S
1B XT440410
2A XT545327
2B XT500314
1A XT480430 S
16 XT440410
2A XT545327
2B XT500314
1A YS884995 S
1B YT920050
1A XT540311 S
1B XT490310
1C XT440420
1D XT480430
1A XTS40311 S
16 XT490310
1C XT440420
1D XT480430
1A XT540311 S
18 XT490310
1C XT 140420
1D XT480430
1A XT540311 S
18 XT490310
1C XT440420
1D XT480430
1A XT540311 S
18 XT490310
1C XT440420
1D XT480430
1A XT540311 S
18 XT490310
F
f
F
F
F
F
F
F
F
f
F
F
F
F
F
F
F
YYMMDD CTZ PRO
650206
650206
650207 3
23
650207
650215 3
19
650215
650215
650215
650216 3
19
650216
650216
650216
650217 3
19
650217
650217
650217
650218 3
19
650218
650218
650218
650301 3 26
650301
650302 3 26
650302
650303 3 26
650303
650304 3 26
650304
650305 3 26
630305
650306 3 26
600
536
650312 3
26
630312
650318 3
26
630318
650329 2 07
630329
650329
650329
6 0 3 2 07
530
630330
650330
650330
650401 2 07
650401
650401
650401
650401
650401
650401
650401 •
650402 2 07
650402
650402
650402
650402
650402
650402
650402
UNCLASSIFIED
Page H
H
GAL
T
P 000D
80
U 000D
50
U 000D
50
U 000D
50
U 000D
50
U 080D
20
U 02800 D
U 080D
20
U 02800 0
U 080D
20
U 080D
20
U 000D
20
U 000D
60
U 000C
30
U 000C
30
U 000C
30
U 0300O C
LEG
COORD
S I M
* •
1C XT440420
1D XT480430
1A XT465410 S
1B XT520310
1A XT465410 S
1B XT520310
1C XT4 90428
10 XT545320
1A XT465410 S
1B XT520310
1C XT490428
10 XT545320
1A XT465410 S
16 XTS20321
1C XT4 90428
10 XT545320
1A XT465410 S
16 XT320310
1C XT490428
10 XT545320
1A YS125538 S
1B YS000752
1A YS12S538 S
1B YS000752
1A YS125538 S
18 YS000752
1A YS125338 S
18 YS000752
1A YS125538 S
18 YS000752
1A YS125538 S
18 YS000752
1A YS 125588 S
18 YS000752
1A YS125588 S
18 YS000752
1A BS600230 S
16 BS600160
2A BS850230
28 BS850160
1A BR680960 S
1B BS730040
2A BS730100
28 BS660050
1A BS600230 S
18 BS600160
2 A 8 58 502 30
28 BS850160
3A BS650040
3B BS730100
4A BS740040
4B BR690960
1A BS600230 S
18 BS600160
2A BS850230
2B BS650160
3 A BS6 5 0 0
04
38 BS7301OO
4A BS740040
48 8R690960
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
�UNCLASSIFIED
YYMMOO CTZ PRO
650412 2
650412
650412
630412
650413 2
650413
650413
650413
650414 2
650414
650414
650414
650417 2
650417
650417
650417
650418 2
650418
650418
650418
602
540
650420
602
540
602
540
650430 4
650430
650430
650430
65O430
650430
603
540
650430
650430
650430
650430
630430
650430
650501 4
650501
650501
650501
650501
650501
650501
650501
650501
650507 4
600
557
600
587
650507
600
557
650507
650525 4
650525
650525
650525
650525
650525
650525
650525
07
07
H
GAL
T
U 000C
30
U 02500 D
07
U 02500 D
07
U 000C
60
07
U 000 C
50
U 000
20
41
U 000D
60
43
U 000D
30
35
U 000D
30
43
U 000D
40
LEG
COORD
S I M
1A BS600230 S
1B BS600160
2A BS850230
2B BS850160
1A BR6 1 9 0 S
00
1B BR730890
1C BR720280
1D 8R65080O
1A BR6 10900 S
1B BR730890
1C BR720280
1D BR650800
1A BR740780 S
1B BR650800
1C BR690710
1D BR750720
1A BR740780 S
1B BR650800
1C BR690710
10 BR750720
1A XB945213
1B YB015221
2A YB088276
2B YB05023S
1A XR272345 S
1B XR283340
1C XR 3 0 4
036
1D XR317367
1E XR310397
1F XR290377
1Q XR272357
2A XR228416
2B XR260393
2C XR3184SO
20 XR305455
2E XR260410
2F XR238424
1A W0458960 S
1B WR436026
1C WR 4 0 2
002
10 WR405O6O
1E WR480O57
1F WR660160
1G WR920250
1H WR920220
11 WR575090
1A XR543598 S
1B XR556600
1C XR550570
10 XR547553
1E XR535553
1F XR538577
1A WQ458960 S
1B WR436026
1C WR400220
1D WR406060
1E WR480057
1F WR660160
1G WR920250
1H WR920022
F
F
F
F
F
F
F
F
F
YYMMOD CTZ PRO
650525
650721 3
26
650721
650721
650721
650721
650722 2
07
650722
650724 3
26
650724
650724
650724
650725 3
26
650725
650726 3
26
650726
650726
650726
650727 3
26
650727
650728 3
26
650728
650729 3
26
6S0729
650901 4
36
651101 2
08
651203
651203
651203
651203
651203
651203
65 1203
651203
651204
651204
651204
651204
651204
651204
651204
651204
651204
651204
651204
651204
651205
651205
651205
651205
651205
651205
651205
651205
651205
651208 4
33
651208 3
26
651208
651208
651209
UNCLASSIFIED
Page 12
H
T
GAL
U 000D
40
U
D
U 000D
60
U 000D
60
U 000D
60
U 000D
60
U 000D
50
U 000D
40
U
P
U
P
0 02100 D
0 000 .
40 0
0 070D
40
U 000 D
30
U 000 0
30
0 01500 D
0 090D
20
LEG
COORD
S I M
11 WR575090
1A YT065110 S
1B YT100110
1C YT 130095
1D YT 120070
1E YT095050
1A BR389447 S
1B BR355453
1A YT060110 S
1B YT 100050
2A YT 1001 10
2B YT 120070
1A YT090110 S
1B YT 1 0 7
200
1A YT085110 S
16 YT1 11070
2 A YTO68110
2B YT 103057
1A YT075110 S
1B YT 105060
1A YT1001 10 S
1B YT 127088
1A YT075110 S
16 YT 105060
1A XS040330 S1A YA842500 S
1A YB818815 S
16 YB8 12809
1C YB848780
10 YB852790
2A YB800871
2B YB855894
3A YB810910
3B YB8 17890
1A Y0105015 S
1B YD122015
1C YC 120995
1D YC 105995
2A YC1 13975
26 YC 100958
2C YC 11 8 4
90
2D YC1 30963
3A YC090990
3B YC 150965
4 A YD090015
4B YD 130025
1A YC3 10772 S
1B YC350747
1C YC240872
1D YC282909
1E YD049109
1F YD025O65
1G YD005049
1H YD025049
11 YD045030
1A XS700270 S
1A YS800230 S
1A YC065945 S
1B YC068967
1A YD008160 S
F
F
F
F
F
F
F
F
G
H
F
F
F
F
F
F
F
�UNCLASSIFIED
YYMMDD CTZ PRO
651209
651209
651209
651209
65 1 209
651209
651209
651209
651209
651210
651210
651210
651210
651211
651211
631211
631211
651213
631213
651213
651213
651214
651214
651214
651214
631214
651214
631215
651215
651215
631215
651220
651220
651220
651220
651220
651220
651221
631221
631222
651222
631222
651222
651222
651222
651222
651222
651223
631223
651223
631223
651223
631224
651224
651224
651224
651224
651224
651224
631224
H
GAL
T
U 000 D
30
0 01100 D
0 01875 D
U 000 D
20
0 040 D
00
0 01900 D
0 01700 D
0 000 D
20
0 01500 D
0 090 D
20
LEG
COORD
S I M
18 XD975132
1C XD969070
1D XD969087
1E XD988070
1F XD988087
2A YC193975
28 YC201949
2C YC22093S
2D YC231920
1A YB6 10905 S
1B YB610890
1C YB630890
1D YB630900
1A YC193975 S
IB YC201949
1C YC220935
10 YC231920
1A YC095765 S
18 YC1 18788
1C YC147795
1D YC173818
U YC1 10833 S
18 YC139859
1C YC178885
2A YC202780
2B YC223800
2C YC249818
U YC262639 S
18 YC274634
1C YC2S060S
10 YC239604
1A YB585700 S
18 YB585650
2A YB635565
28 YB644533
3A YB67SS05
38 YB648472
1A YB630730 S
18 YB650675
1A YC560110 S
18 YC620080
2A YC749058
28 YC593047
3A YC707668
38 YC697705
4A YC685690
4B YC662645
1A YC430680 S
18 YC475675
2A YC490690
28 YC530690
2C YCS60620
1A YC290S30 S
18 YC330490
2A YC275380
28 YC280465
3A YC325555
38 YC295520
4A YC325595
48 YC345575
F
F
F
F
F
F
F
F
F
F
YYMMDD CTZ PRO
631224
651224
651227
651228
651228
651229
651229
651230
631230
651231
651231
660101
660101
660101
660101 1
660101
660101
660101
660102
660102
660102
660102
660102
660102
660103
660103
660103
660103
660103 4
660103
660104
660104
660105 3
660103
660105
660103
660105
660105
660105
660106
600
616
660106
660106
660106
660106
660106
660106
660106
660106
660106
660106
660106
660106
660106 3
660106
660107
660107
660107
66O107
660107
Page 13
H
GAL
T
U 02000 D
U 01000 D
0 000D
20
0 01450 D
0 000D
20
0 060D
30
06
U 01600 D
U 000 D
20
U 000D
20
•
43
0 000D
40
U 000D
20
26
U 000D
40
0 03600 D
0 000D
20
26
UNCLASSIFIED
0 000D
20
U 000 0
40
LEG
COORD
S 1 M
5A YC370200
SB YC375165
1A YB708727 S
1A YB699432 S
1B YB782451
1A YB790460 S
1B YB690390
1A YB692393 S
18 YB700340
1A YB720500 S
18 Y87 10405
1A YB692393 S
1B YB700340
1C YB720500
1A YB590700 S
1B YB58S610
2A YB725670
28 YB708730
1A YB708727 S
18 YB720696
1C YB726665
2A Y8584647
28 YBS86670
2C YB588698
1A YB732709 S
18 YB720756
2A YB643713
28 YB644663
1A WR800185 S
18 WR720145
1A Y8713798 S
18 YB735697
1A YS 130585 S
18 YS040650
1C YS030750
1A YB638713 S
18 YB655654
2A YB679711
28 YB651659
1A YC370806 S
1B YC348785
2A YC283840
28 YC320841
3A YC276820
38 YC255809
4A YC293785
48 YC294751
5A YC045968
SB , YC068967
6A YD 180026
68 YD090015
7 A YD 1 4 4
600
78 YD 140027
1A YS 150580 S
1B YS 150650
1A YC450822 S
1B YC472769
2A YC04S969
28 YC068967
3A YC12S957
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
F
�UMMOLMOOiriCU
YYMMOO CTZ PRO
660107
660107
660107
660107 3
660107
660107
660107
660107 3
660107
660107 3
660107
660107 3
660107
660108
660108
660108
660108
660108
660108
660108 3
660108
660108
660108
660109
660109
660109
660109
660109
600
619
660109 4
660109
660109
660109
660110
660110
660110
660110
6601 1 1
660111
6601 12
660112
660112
660112
660112
660112
660112 1
660112
660112
660112
660112
660112
660113
660113
660113
660113
660113
660113
660113
660113
660113
26
H
GAL T
0 0000
40
24
W 02700 D
26
0 02700 D
26
W 070D
20
U 000D
40
26
0 000D
50
0000D
.20
41
0 000D
40
.
0 000D
40
0 01800 D
0 0600
30
01
U 01600 D
U 0000
20
LEG
COORD
S I M
3B YD097038
4A XC873615
48 XC892540
1A YS1S0640 S
1B YS03S675
2A YS03367S
2B YS000740
1A XT500630 S
1B XT450SSO
1A YS03S648 S
1B YS03S540
1A YS170610 S
1B YS030610
1A XC871616 S
1B XC905522
2A Y8213913
2B YB22597S
3A YB2 10975
3B YB220960
1A YS113S80 S
18 YS025640
2A YS025640
28 YS000760
1A X0775020 S
1B XC793978
2A XC864618
2B XC88S540
3A YC 145690
3B YC 1 3 9
060
1A WR805180 S
1B WR640113
2 A WR80218S
2B WR635117
1A XD600135 S
18 XD590192
2A XD588205
2B X0550302
1A XC854618 S
1B XC901523
1A XD593184 S
1B X0556295
2A XD5 18370
2B X052839S
3A X0086210
3B X0090210
1A XD5 18370 S
16 XD528395
2A X0086210
28 XD690210
3A X0086215
3B X0090215
1A X077S020 S
1B XC793981
2A YC065954
2B YC069977
3A YC054956
3B YC658981
4A YC153943
4B YC 11 4920
4C YC067953
F
F
F
F
F
F
F
F
F
F
F
F
F
YYMMOD CTZ PRO
660113
660113
660114
660114
660115 1
660115
660115 1
660115
660115
660115
660115
660115
660116
660116
660117
660117
660118
660118
660119
660119
660119
660119
660119 1
660119
660120
660120
660120
660120
660124
660124
660124
660124
660125
660125
660125
660125
660125
660125
660125
660125
660125
660125
660125 1
660125
660125
660125
660125
660125
660125
660125
660125 1
660125
660125
660125
660126
660126
660126 1
660126
660126
660126
. Page 14
H
GAL
T
0 000D
40
03
U 000D
20
03
U 01850 D
U 01900
0 01900 D
0 01900 0
0 01800 D
01
U 01800 0
0 01000 D
U 000
20
U 000
20
0 02450 D
06
U 01600 0
06
U 00850 0
0 000D
20
03
UNCLASSIFIED
U 000D
20
LEG
COORD
S I M
5A YC048947
SB YC059989
1A XD518370 S
1B XD528395
1A YC067846
1B YD090016
1A YC786960 S
1B YC148966
2A YC 153494
2B YC 148966
3A YC056986
3B YC047156
1A XC868609
1B XC901524
1A XC868609 S
18 XC901524
1A YC435830 S
1B YC325885
1A XD591192 S
1B XD600136
2A X0548303
2B XD587210
1A XD600135 S
1B XD62287Q
1A YB441319 S
1B Y8441321
2A YB439319
2B YB439321
1A XD589239
1B XD548304
1A XD600135
1B XD585190
1A YB698706 S
18 YB704661
2A YB667644
28 YB687689
3A YB2 13973
38 YB225975
4A YB2 10975
48 YB220960
5A YB708920
SB Y8709970
1A YB220850 S
18 YB222850
1C YB220855
10 YB222855
2A YB7056S6
28 YB695728
3A YB686700
38 YB662640
1A- YB 189987 S
18 YB227960
2A YS200980
28 YB256976
1A YC065945 S
18 YC068967
1A YC154943 S
18 YC066950
1C YC060890
10 YC060926
F
F
F
F
F
F
F
F
F
F
F
F
�UNCLASSIFIED
YYMMDO CTZ PRO
660126
660127
660127
660127
660127
660127 1
660127
660127
660127
660128
660128
660128
660128
660128
660128
660128 1
660128
660128
660129
660129
660129
660129
660130
660130
660130
660130
660131
660131
660131
660201
660201
660202
660202
660202
660202
660202
660202
600
623
660203
660203
660203
600
623
660205
660205
660206
600
626
600
626
660206
660207
660207
660208
660208
660208
660208
600
628
660209
660209
660210
660210
660210
H
GAL
T
0 000D
40
U 000 D
20
0 02100 D
01
U 01000 D
0 090D
00
0 000D
20
U 000D
20
U 000D
20
0 000D
60
0 000D
40
U 02OOO D
0 000D
50
0 000D
20
0 02500 D
0 000D
20
0 03850 D
LEG
COORD
S I M
1E YC036927
1A XD548303 S
F
1B XD587210
2A XD527395
2B XD5 18370
1A XD60013S S
F
1B XD585190
2A XD589239
2B XD54S304
1A XD08S210 S
F
1B X0090210
2A YD050110
2B YD036065
3A Y00501 10
38 YD081035
1A YD050110 S
F
1B YD025046
1C YD081035
1A YB712777 S
F
1B YB731708
2A YB7O8727
2B Y8726665
1A YB636536 S
F
18 YB6S8429
2A YB604413
2B YB695335
1A YB854804 S
F
1B YB841774
1C YB807813
1A XD775020 S
F
18 XD712021
1A XD720025 S
F
18 XD675040
1C XD620175
10 XD590180
2A XC795990
2B XC8 14705
U XC965425 S F
1B XC9S9515
1C XC891509
2A XC965425
2B YC040244
1A YB22597S S
F
18 YB366966
1A XD775020 S
F
1B XC926964
2A XC90597S
2B YC020980
1A YB212972 S
F
1B YC040230
1A YC 115097 S
F
18 YC07413S
1C YC0821SO
1D YB23O97S
1E YB270960
1A YC128070 S
F
18 YC07213S
1A YB3S0965 S
F
18 YB230975
2A YB364964
YYMMDO CTZ PRO
660210
660211
660211
660211
6602 1 1
660212
660212
660213
660213
660214
. 660214
660215
660215
660216
660216
660218
660218
660219
660219
660220
660220
660224
660224
660225
602
625
660226
660226
660227
602
627
660228
660228
660228 1
660228
660228
660228
660228
660228
660301
660301
660301
660301
660301 1
660301
660301
660301
660302
660302
660302 1
660302
660304
600
634
6603O4
6603O4
660305
600
635
660305
660305
660305
600
635
600
636
UNCLASSIFIED
Page 15
H
GAL
T
Q 01000 D
0 01000 D
0 0000
20
0 000D
20
0 000D
20
0 000D
60
0 000D
30
0 02800 D
0 000D
30
0 02000 D
0 01650 0
0 04650 D
0 000D
30
0 000D
30
U 03000 D
U
0 0800
20
01
0 080D
20
0 000D
20
06
U 000D
30
0 02100 D
0 04500 D
0 000D
30
LEG
COORD
S I M
28 YB360973
F
1A YB345968 S
1B YB225975
2A YB2 12973
2B YC 180250
F
1A YC175032 S
1B YC125065
F
1A XD528395 S
1B XD295555
F
1A XD740020 S
1B YC070970
F
1A XD7 10020 S
1B XD770020
f
1A XD740020 S
1B YC070970
1A YC 125048 S . F
1B YC 120095
F
1A XC868612 S
1B XC886524
f
1A XC825830 S
1B XC830680
f
1A YB677325 S
1B YB587313
f
1A XC960480 S
1B YC030355
1A YC030355 S
f
16 YC095233
1A YC096234 5
f
18 YC161039
1A XD780025 S
f
1B XC792770
F
1A XC794980 S
18 XC814814
1A XG563813
18 XG528833
1C XG491899
1D XG478842
1A YD000005 S
F
1B YD078031
2A YC021983
2B YC055968
F
1A YC021983 S
18 YC055968
2A YD080085
2B Y0078031
1A Y8689325 S
F
1B YB500327
1A YB657327
16 YB533320
F
1A YB532321 S
18 YB498324
2A YB492263
28 YB467321
F
1A YB500250 S
1B YB485270
2A YBS 10267
2B YB300508
3A YB494254
3B YB508302
1A XC887524 S
F
�UNCLASSIFIED
YYMMDD CTZ PRO
H
GAL
T
Page 16
YYMMDD CTZ PRO
H
GAL
T
LEG
COORD
S I M
a
66O306
660306
660307
660307
660308
660308
660309
660309
660310
660310
660311 1
660311
6603 1 1
6603 1 1
6603 1 1
6603 1 1
660312 2
660312
660312
660313 1
630313
660313
660313
660313
660313
6603 13
660315
660315
660316
660316
660318
660318
660318
660318
660325
66032S
660325
660325
660329
660329
660330
660330
660330
660330
660331
660331
660401
600
641
660401
600 2
644
600
645
660405
600
646
600
646
600
646
600
646
600
646
600
646
600
646
600
646
U
0 000D
20
Q 000D
20
0 0000
20
0 000
20
03
U 01 150 D
10
0
0 000
30
0 01B"QO D
0 000D
20
0 0000
20
U 02OOO 0
0 0000
30
U 000 D
30
U 000D
20
0 000D
20
0 000D
20
U 000D
20
0 000D
20
10
U
D
0 0000
20
U 000D
20
1B XCS45668
1A YT 150290
1A YB364542 S
F
18 YB356467
1A YB365342 S
F
1B YB356467
1A XCS87S24 S
F
IB XC820697
1A X0674034
1B XD633156
1A YC013963 S
2A YC032966
26 YC041002
3A YC070981
38 YC080987
3C YC067947
1A CR040070 S 2 F
1A XS675054
1B X0632158
1A YC030235 S
F
2A XC885506
2B XC897438
3A XC797795
3B XC808784
3C XC806712
1A XE215025 S
F
1A XDO62735 S
P
2A X0088672
1A XE258107 S
F
1B XE278108
1A XD190413 S
F
1B XD 1604 10
1C XD 160360
10 XD 170344
1A YD192384 S
F
IB YD 194395
1C YD125413
10 YD 1344QO
1A YB222955 S
F
18 YB228743
1A XD190414 S
f
1B XD 162343
1A YB227743 S
F
1B YB390S63
1A XD190414 S
F
1B XD162343
1A YB360543 S
F
1B YB387583
1C YB366635
1A C0105330 S 2 F
1A XD080880 S
F
16 XE230013
1A XD030853 S
1B XD045865
1C XD080880
2A XE 150010
2B XE 170018
2C XE225O03
2D XE230013
2E XE2 17024
600 1
648
660408
600 1
648
600
648
660408
600
648
660410
660410
660410
660410
660411 4
660412
660412
660412
660412
660412
6604 1 2
660412
660412
660415
660415
660415
660415
660415
660415
66O415
660416
660416
660416
660416
660416
660418
660418
660418 4
66O418 4
660418 4
660418 2
660418
660419
660419
660419 4
660420
660420
660420 2
660420
660420
660420
602
640
660423
660423
660423
660423
602
643
660423
660423
660423
660427
660427
660429
660429
01
U 01000 D
02
U 01000 D
U 000
20
U 00110 P
U 000
20
33
0 000D
20
0 000D
20
U 000D
20
0 000D
20
34
36
37
07
U
U
U
U
00015
00108
000
07
000
20
P
P
P
0
0 01700 D
36
U 00108 P
0 000D
20
07
U 020OO D
UNCLASSIFIED
U 00108
U 000D
20
U
0 000D
20
0 000D
20
m
1A YD205384 S
F
1B YD250415
F
1A YD 190400 S
1B YD115417
1C Y0200400
1D YD245430
1A XDS90300
1B XDS90268
1C XD581300
1D XD581268
G
1A XS481468 S
1A YS4565S7
1B YS481S18
1C YS490531
1D YS458S68
1E YS455574
1F YS437558
1G YS436S64
1H YS450675
1A XE2 15025 S
F
1B XE230020
1C XE2 10045
ID XE260093
1E XE260098
1F XE26S101
16 XE2S9106
1A XE258107 S
F
1B XE278108
1A XE28113S S
1B XE272177
1C XE283178
1A YB220280 S
F
1B YB42S3OO
1A XS53S334 5
G
1A WS986239 S
G
1A WS443568 S
G
1A BR42S627
1B BR480590
1A YB088277 S
F
IB YB218278
1A WS986239 S
G
1A XB868198 S
F
16 XB91521S
F
1A XB945213 S
1B YB015221
1C YB088276
1D YB050235
1A WS986239
1A XD1 18925 S , F
1B XD 11 5900
1C XD090878
1D XD055880
1E XD0208S5
1F XD0408SO
1A XB635315 S
F
1B X8780230
F
1A XD591181 S
1B XD453278
1A YB420297 S
F
IB YB071283
�UNCLASSIFIED
YYMMDD CT2 PRO
H
GAL
T
LEG
COORD
S I M
YYMMOD CTZ PRO
Page 17
H
GAL
T
LEG
COORD
S I M
* *
66O430 4
.660501 4
660501
66O502 4
660502
660503
660503
66O503 4
€60503
660504
660504
600 4
654
66O504
660505 4
660505 4
660505
66O506 1
660506
660506
660S06
660506 4
660506
600
656
600
656
600 4
657
66O507
660508 4
66O508
66O509 4
600
659
660510
660510
660510 4
66O510 4
660510
660511
66O511
660511
660511
6605 1 1 4
660511
66O512 4
66O512
66O5 1 3
660313
660513 4
660513
66O514
66O514
66O514 4
660514
660514
660514
660514 4
660514
66O515
660515
660515 4
66O51S
660517
34
36
U 00015 P
U 007 F
00
36
U 007 F
00
0 01800 D
36
U 007 F
00
U 0000
20
36
U 007 F
00
30
36
U 000P
02
U 007 F
00
05
U 02OOO D
0 000D
20
36
U 007 F
00
U 000
20
36
U 007F
00
36
U 007 F
00
36
U 007 F
00
U 000D
20
30
36
U 000P
02
U OO007 F
0 01900 D
36
U 007 F
00
36
U 007F
00
U 0000
20
36
U 007 F
00
U 0000
20
34
36
U 060F
08
U OOO07 F
U 000D
20
36
U 007F
00
U 0000
20
1A XS490377 S
U XS122190 S
1B XS123199
1A XS122190 S
1B XS123199
1A XB892123 S
18 XB835188
1A XS122190 S
1B XS123199
1A XD 300344 5
18 X0425276
1A XS122190 S
1B XS123199
1A XS762364 S
1A XS122190 S
1B XS123199
1A BS756070 S
1B BR843891 S
1A YB 120283 S
1B YB415310
1A XS122190 S
18 XS123199
1A XB852191
1B XB940201
1A XS122190 S
18 XS123199
1A XS122190 S
18 XS123199
1A XS122190 S
1B XS123199
1A XD 133958 S
18 XD021855
1A XS763366 S
1A XS122190 S
1B XS123199
1A YB428300 S
1B YB480285
2A XB934201
2B YB058240
1A XS122190 S
1B XS123199
1A XS122190 S
18 XS123199
1A XD30O345 S
18 XD220465
1A XS122190 S
18 XS123199
1A XD131963 S
18 XE225029
1A XS621267 S
18 XS640270
1C XS637253
10 XS620253
1A XS122190 S
1B XS123199
1A YB4 18296 S
18 YB125289
1A XS122190 S
18 XS123199
1A XB700147 S
G
G
G
F
G
H
G
G
G
F
F ,
F
G
G
G
G
F
G
G
F
6
G
F
G
F
G
G
F
G
F
660517
660519
660519
660519
660319
660520 4
660325 4
660525 4
660525 4
660525
660526 4
660527 4
660530
660531
660531
66033 1
660601 4
660602 4
660603
660603
660603
660603
660603
660603 4
600 4
663
600
663
600
664
600
664
600 4
665
600 4
666
600
667
600
667
600 4
667
600
668
660608*
600 4
668
600 4
668
600
669
600
669
600 4
669
660611
6 0 11
66
660613 4
6606 1 3
660614
66O614
660614 4
660616 4
660617
660617
660617 4
660617
660618
660618
660618 4
660618 4
660618 4
660620 1
602
660
660620 4
0 02000 D
30
34
30
40
34
40
U
U
U
U
U
U
U
U
U
•
000
04
00051
000
03
00016
01650
000
04
00016
P
P
P
P
P
P
000D
20
40
40
U 00016 P
U 00016 P
U 000D
40
4
0
4
0
U 000P
02
U 008 F
02
U 000 0
20
30
40
U 006 P
04
U 00016 P
U 000D
20
36
U 004 P
05
U 02OOO D
36
40
U 00054 P
U 00016 P
U 000D
20
40
U 00016 P
U 000D
20
43
U 000 F
02
U 000D
20
30
34
34
U 000 P
04
U 006 P
03
U 0000
20
U 007 P
02
U
U 000 0
20
03
U 000 P
04
U 00035 P
U 007 P
02
0
30
U 00024 P
34 '
34
34
UNCLASSIFIED
16 XB935235
1A YB590280 S
1B YB608399
2A XB682125
2B XB780162
1A XS7 11382 S
1A XS500361 S
1A XS696378 S
1A WS724150 S
1A BR478447
1A XS528305 5
1A WS721141 S
1A YC608810
1A YB445340 5
18 YB460365
1C YB365460
1A WS716130 S
1A WS714123 S
1A XB850190
1B YB000270
2A YC441278
2B YC482274
2C YC533167
1A WS789047 S
1A WS783038 S
1B WS788045
1A X04 70260 S
18 X0590180
1A XS725432 S
1A WS713111 S
1A XDO 18864 5
1B W0994905
1A WS910164 S
1A XD 133950 S
1B X0151995
1A WS910164 S
1A WS7 18071 S
1A XD500246 S
1B XD4 18280
1A WS713150 S
1A XB9 15225 S
1B YB097284
1A WR583228 S
1B* WR603233
1A WD991903 5
1B WD951933
1A XS693447 S
1A XS338364 S
1A WE892005 S
1B WD94S935
1A XS386369 S
1A YC565822
1A YB377620 S
18 YB380579
1A XS264362 S
1A XS305348 S
1A XS295373 S
1A BT266280 S E
1B BT256217
1A XS676455 S
F
G
G
G
G
G
G
F
G
G
F
G
G
F
G
G
F
G
F
G
G
F
G
F
G
F
G
G
F
G
F
G
G
G
F
G
�UNCLASSIFIED
YYMMDO CT2 PRO
H
GAL
T
YYMMDD CT2 PRO
Page 18
H
GAL
T
•*
660620 4 43
660624 4 34
660625
660625
660626
660626
660627 4 43
660627 4 43
660627
660630 4 36
660706
660706
660707
660707
660707
660712 4
34
660713
660713
660713
660713
6607 1 3
660714
660714
660714
660714
660714
660715 1
02
660715
660715
660715
660716
660716
660717
660717
6607 1 7
660720
660720
660722
660722
660724
660724
660724
660729
660730
660730
660730 3
31
660801 1
01
660801
660802 1
03
660802
600
682
600
684
660804
660804
660805
660805
660805
660805
660806
600
686
U 005 P
00
U 03000 D
U 02000 D
U 0000
20
U 005 P
00
U 00025 F
U 01243 P
U 0000
20
U 000D
20
0
0 000D
20
0 000D
30
U 0000
20
U 000
30
0 000D
30
U 000D
30
0 000D
20
0 000D
20
0 000D
20
U 0000
20
U
U 0000
20
U 02OOO 0
0 000D
20
0 0000
20
U 0000
20
1A WR565224 5
1A XR845595 S
G
F
F
1A YB353462 S
1B YB440340
1A YB370473 S
F
1B YB4 30340
1A WR505207 S
G
1A WR50S207 S
G
1B WR330149
1A XS040330 S
G
F
1A WE891010 S
1B WE870060
F
1A XC880620 S
18 XC900050
1C XC930052
1A XS450230 S Z F
F
1A YB5 10230 S
1B YBS90185
1C YB6201S5
~
2A YB590190
2B YB630210
1A XD020852 S
F
1B XD027764
1C WD994770
1D WD980820
1E XD025830
F
1A ZO 140946 S
F
1B ZD 170035 S
1C ZO 165065 5
F
10 ZD250060 S
F
F
1A XD340340 S
16 X04 15350
1A YC450288 S
F
IB YC490288
1C YC590120
F
1A YB500250 S
1B YB615150
F
1A XD3 10335 S
1B XD420285
F
1A YC430290 S
1B YC490290
1C YCS90120
F
1A YB360970 S
1A XD29035O S
F
1B X04 10290
1A XS285870 S R F
1A Y0700023 S
F
F
18 YC4309SO S
F
1A ZC072932 S
F
1B ZC062960 S
1C ZC072967 S
F
F
1A WD96090O S
1B XD000900
1C X0000860
F
1A XD5 10250 S
1B XD540250
2A XD5 10240
2B XD540240
F
1A XD380430 S
1B XD560380
LEG
COORD
S I M
•
660809
660809
660811
6 0 11
68
660813
660813
6608 1 5
660815
660816
660816
660816
660819
660819
660819
660819
660819
660819
660819
660820
660820
660821 3
660822
660822
660822
660824 2
660824
660825
660825
660826
660826
660829
660829
602 3
689
660829
66O831
660831
660902
660902
600
693
660903
600 3
694
600
694
600
699
66O9O9
660919
660919
660919
602
690
660920
660922
602
692
660922
661014
661014
661014
661014
661014
661014
661014
661014
0 000D
20
0 0000
20
0 000D
20
U 000D
20
0 000D
20
U 0000
20
0 01900
U 000D
20
24
W
0 02700
06
U 000D
20
U 0000
20
U 000D
20
0 000D
20
31
U
0 000D
20
0 000D
20
0 000D
20
23
UNCLASSIFIED
0
C
U 01800 D
0 01800 D
0 01800 D
0 02700 D
W 04500 C
W 01800 C
m
f
1A XD165592 S
1B XD 100657
F
1A XD350340 S
1B XD430270
F
1A WD953952 S
1B WD930910
F
1A WD953952 S
1B W0930910
F
1A WE572163 S
1B WE562082
1C WE560040
1A X0360634 S
F
1B X0392631
2A XD621671
2B XD564674
1A X0780035
1B XD760870
1C XC835S65
F
1A WD940690 5
1B XD060627
1A XT535385 S Z F
1A XC820850
1B XC8 15990
1C XC997930
F
1A YA860600 S
1B Y A 790540
1A Z 0 0 7 S
C790
18 ZC050930
F
1A XDS 10240 S
1B XD577225
F
1A W0890999 S
1B XD005935
1A XS345809 S R F
16 XS335810
F
1A YB 100288 S
1B YB385274
F
1A XB720120 S
1B XB920230
F
1A XB930230 S
16 XB085270
H
1A XT74Q320 S
16 XT660390
F
1A YC175990 S
18 YC095893
F
1A XD780035 S
16 XC760870
1C XC835865
1A XD810045 S
F
1B XC950962
F
1A XC820850 S
1B XC8 15990
1C XC997930
1A XC970850 S
F
1B YD003O40
2A XD950040
28 YC002850
F
1A YD005035 S
1B YC070930
2 A YD08504S
28 YC075980
�UNCLASSIFIED
YYMMDD CT2 PRO
H
GAL
T
LEG
COORD
S I M
YYMMDD CTZ PRO
Page 19
H
GAL
T
a *
661025
661025
661025
661025
661026
661026
661026
661026
661027
661027
661031 3
661101
661 101
661102 2
661102
661102
661102
661105
661105
661110
661110
661120
66 1 1 20
661123
661123
661124
661124
661 125
661125
661128
661128
661128
661128
661129
66 1 1 29
661129
661130
661130
661204 3
661204
661204
661204
66 1205 1
661205
661205
661208
661208
661208
661208
661210
661210
661210
661210
661210
661210
661210
661210
661210
661210
661211
U 03000 D
U 01000
U 02000 D
U 02000
U 000D
20
23
0
W O1 8 0 D
0
07
W 02700 D
W 02700 D
U 000 0
20
H 013OO D
W 02700 D
U 000D
20
U 000D
20
U 020OO D
W O18OO 0
W 01800 0
W 01800 0
26
01
0 070D
20
W 02700 D
W 0700
20
W 0270O 0
W 02700 0
W 018OO D
W 070D
20
p
1A XB930214 S
661211
661216
18 YS271270
1A Y8500230
661216
1B Y83S0275
661216
f
1A YS250720 S
661216
661223 3
21
1B YB360520
1A YB370520
661223
1B YS420420
661223 '
F
1A XB690125 S
661223
1B XB925238
661228 3
24
1A XT637439 S E f
. 661228
f
661228
1A W0930610 S
1B W0950450
661228
F
670103 3
26
1A BR300250 S
16 BR16014Q
670105
F
670106
1A W0900700 S
670107
18 W0920570
F
1A WE850100 S
670108
670109
1B WE780240
f
1A WD860980 S
670109
1B WE830100
670109
f '
1A XE230010 S
670110
16 XE230018
670111
F
670111
1A W0870870 S
1B WDS90870
6701-11
f
1A XD030750 S
670111
18 XD070770
670111 3
23
F
670111
1A XD125930 S
1B XD040864
670111
F
1A XO 120960 S
670111
1B XO 140980
670112
2A XO 130980
670112
670113
2B XO 140960
F
670113
1A XD12093O S
18 XD 120870
670113
1C WD990860
670113
F
670114
1A XD020870 S
670114
1B XD 100880
670114
F
1A YS358S52 S
F
670114
18 YS359810 S
F
670114
1C YS37S810 S
F
10 YS375850 S
670115
1A Y0030830 S
F
670121 3
27
F
670121
1B WD974820 S
f
1C XD023760 S
670121
F
670121
1A WE85O050 S
670121
1B WE820120
2A WE9O0960
670121
2B WE870960
670121
F
1A WE760190 S
670121
670121
1B XD020860
670124
1A WE810120
670124
16 WE830130
670124
2A WE 8 6 0 0
07
670124
26 WE870090
1A XD730610
670123 '
18 XD730630
670125
2A XD750630
670125
2B XD7S0610
670125 3
18
f
1A XD085850 S
670125
UNCLASSIFIED
LEG
COORD
5 I M
• S
W 01800 D
0
0
0
0
W
U
U
U
U
W 01800 D
U
U
W 02700 D
W 02700 D
U
U
U
U
U
W 01800 D
U
U
W 02700 D
W 070D
20
U
U
0 01800 D
0 01225
W 00810
0 01800 0
0 01800 D
0 01300 D
0 030OO D
1B XD118910
F
1A W08 10830 S
1B WD800840
2A WD880710
2B WD840720
F
1A YT340410 S
18 YT340480
2A YT4 10480
2B YT410410
F
1A XT520770 S
1B XT520840
2A XT590840
2B XT590770
1A YT045150 S R F
1A AR76048O
1A AR760480
1A AR760480
1A AR760480
1A WD560080 S
1B WD640980
1A AR760480
1A AR760480
F
1A WD9 20580 S
1B W0990230
F
1A WD63S980 S
1B WD785895
1A XT5 10590 S 2 F
18 XT530620
1A AR760480
1A BR475486
1A BR475486
1A AR76O480
F
1A WES 10440 S
1B WE33038O
1A BR475486
1A AR76048O
F
1A WOS90970 S
1B WD720920
F
1A W0800930 S
16 WD800760
1A AR760480
•
1A AR805540
1A YS750670 S
1B YS770692
1C YS923758
1A YA740503
16 YA677547
1C YA655555
1A YA740503
1B YA677547
1C YA6555S5
F
1A XD800030 S
1B YC060970
F
1A XD73O030 S
16 YC060970
1A XD733034 S
F
1B XD 7 38008
2A YC020980
F '
1A YS209900 S
16 YT 178020
�UNCLASSIFIED
YYMMDO CT2 PRO
670125
670126
670126 3
670126
670126
670127
670127
670127
670127
670127 2
670128
670128
670128
670128
670129
670129
670131
670203
670203
670205
670205
600 3
726
670206
600
726
670206
670210
6702 1 1
670212
670213 3
670213
670213
670214
670216
670216
670218
670218
670219 3
670219
670219
670219
670220
670220
670220 2
670220
670222
670222
670223 2
670223
670223
670223
670223 3
670223
670224 3
670224
670224
670224
670225 3
670225
670301 3
670304
27
H
GAL
T
0 02700 D
0 01800 D
10
U 01500 P
0 02700 D
W 02200
0
0 009OO D
0 01800 D
18
0 00OD
20
U
U
U
18
0 000D
30
U
U
0 01800 D
W 00180
25
0
0 02700 D
07
U 01500 P
U
0 02100 0
11
0 03750 D
19
W 000D
40
24
00000
30
21
0 000D
60
24
0 070
00
U
LEG
COORD
S I M
1C YT200200
1D YT 178004
1A YS430790 S
F
1B YS300790
1C YS340730
1A Y0180030 S
F
1B Y0090010
2A YD120010
2B YC080980
1A CO 152478 S
1A YC0709SO S
F
16 Y0090010
2 A YD 160030
2B YD 190030
1A XT900600
18 XT620550
1A XD320330 S E F
1A YB920640 S
1S YB940660
1A YB220900 S
F
16 YB2208OO
1A YT900490 S
F
16 YT956438
2A YT904489
28 YT863434
1A AR805350
1A AR805350
1A AR805350
1A YS866847 S
F
18 YS827832
1A AR805350
1A AR80S350
1A XC990080 S ' F
1B XC940160
1A ZA020420
1B ZA040430
1A XT906436 S R F
1B XT909436
1C XT904443
10 XT907443
1A WD930S70 S
F
1B XD010450
1A 8R465467 S
1A BR472444
1A WD900700 S
F
18 W0817768
1A 80875555 S
1B 80901535
2A 80865534
28 80890526
1A YT650390 S
F
1B YT651707
1A XT5 10640 S
F
18 XT550640
2A XT480570
2B XT505625
1A YT 193430 S
F
18 YT200600
1A XTS75365 S Z F
1A BR726666
Page 20
YYMMDD CT2 PRO
670304
670304
670304
600
734
670304
670304
670304
670304
670304
600
734
670304
600
736
670306
670306
670309
600
739
670312
670312
670312
670313
670313
670313
670314
670314
670314
670315 4
670315
670315 2
670315 2
670315
670315
670315
670316
670316
670316
670317
670317
670317
670318
670318
670318
670319 3
670319
670319
670319
670319
670319
670319
67032O
670320
602
730
670321
670321
670321
670324 2
670324
670324
670324
670324 2
670324
H
GAL
T
0040
20
U
U
~U
U
04
0 000D
50
10
09
B 020
05
B 070D
05
U
U
U
U
24
0 01700 D
U
U
U
10
0 000D
30
10
0
UNCLASSIFIED
LEG
COORD
S I M
1B BR740668
2A BR74Q664
28 BR727662
3A BR722652
38 BR735658
4A BR744649
4B BR725649
5A BR732673
58 BR734677
6A BR744673
6B BR746676
1A XT670297
1B XT727300
1C XT768204
1A ZA209946
18 ZA206953
1A YA6 10600
18 YA757386
1C YA732504
1A YA6 10600
1B YA757386
1C YA732504
1A YA610600
18 YA757386 .
1C YA732504
1A XR690595 S
F
18 XR518548
1A 80790710 S Z F
1A BQ790715 S
1A YA6 10600
18 YA757386
1C YA732504
1A YA61060O
1B YA757386
1C YA732504
1A YA6 10600
18 YA757386
1C YA7325O4
1A YA6 10600
18 YA757386
1C YA732504
1A XT630540 S
F
1B XT700580
1C XT700590
1D XT620550
1A YA6 10600
18 YA757386
1C YA732504
1A YA6 10600
18 YA757386
1C YA732504
1A YA6 10600
1B YA757386
1C YA732504
1A 80710890 S
F
18 80790920
1C BQ750850
1D 8 8 0 0
0090
1A B080O800 S Z F
1B 6 7 0 4
0786
�UNCLASSIFIED
YYMMDO CTZ PRO
H
GAL
T
LEG
COORD
S I M
YYMMDD CT2 PRO
Page 21
H
GAL
T
LEG
COORD
S I M
• X
670328
670329
670331 2
670331
670331
670331
600
747
670408 3
670408
600
748
670412 1
670412
670414
670415
670416 2
670420
670421
670422 2
670422
670422
670423 1
670423
670423
670424 2
670424
670424
602
744
670424
670428 2
670428
670501
670S01
600 4
754
670SOS 3
670505
67050S 2
670505
670505
670506 3
670506
670511 2
670511
6705 1 1
670512 2
670512 2
670513
670515 1
670515
670515
670515
670515 1
670515
670515
670515
670515 3
670515
670515
670515
670515 2
670515
U
U
02
0 01500 0
21
U
0 0000
30
03
U
U 01000
07
06
U
U
B
U
U
W 020F
00
U
02
B 040
00
10
U
0 000C
30
U
07
0 000C
60
0 02790 D
42
19
W
W 040
00
08
0 060P
00
19
0 000D
20
08
0 00100 D
06
07
W
U
U
B
03
05
00270 P
02500 P
000
30
030D
00
B 090 0
00
24
0 01800 D
08
0 000D
30
1A BR475486
1A BR475486
1A AT960920 S
1B AT960886
2A AT942B64
2B AT947920
1A YA770230
1A YT130360 S
1B YT130S32
1A YA770230
1A BT080700 S
1B BT070740
1A BN750870
1A BN750870
1A BR340670 S
1A AR805350
1A ARS05350
1A YA865483 S
1B YA857S27
1A AR805350
1A YD600240 S
1B YD640260
1A AR805350
1A B07 10890 S
1B B0790S20
1C B0750850
10 B 8 0 0
0090
U AR805350
1A BR500960 S
16 BR6O0700
1A YB490260 S
18 Y8560160
1A WR453128 S
1A YT690440 S
1B YT650420
1A AR792246 S
1B AR803353
1C AR8 10356
1A YT291325 S
1B YT294485
1A AR792246 S
1B AR803353
1C AR8 10356
1A AS959005 S
1A BR927755
1A BR478486
1A AT827215 S
1B AS995370
2A AT9 10009
2B AS930933
1A BS598477 S
18 BS603523
2A BS640369
2B BS543393
1A XT700640 S
1B XT657640
1C XT705657
10 XT657637
1A YA750500 S
1B YA800470
F'
F
Z F
R F
H
Z F
F
F
F
Z F
Z F
H
F
H
H
F
P
F
F
670516 1
670521
670522 3
670522
670522 3
670522
670522 3
670522
670524
670525
670526 2
670526
670526 2
670526
670526
670526
670526
670526
670526
670530 2
670530
670530 2
670530
670531
670601 2
670601
600
761
670602 2
670602
670602 2
670602
670602
670602
670602
670603 2
670603
670603
670603
600
764
600
764
600 1
765
670605
600
765
670605
600 3
766
670606
600
766
600
766
600 1
767
670607
670607
670607
670608
600
769
670610 3
670610 2
670610 3
670610
670610
670610
05
0
20
U
0 01860 D
20
W 01860 D
19
0 000D
40
12
U
U
0 000D
30
07
B 000C
60
07
0 000D
50
08
07
0 070D
02
U
U
0 000D
30
07
U 002
00
0 000D
60
08
0 00110 D
07
U 002
00
0 0 0 0 .D
60
U
U
U
24
U
U
U
W
U
U
U
U
03
0 O4650 D
05
002
00
002
00
050
00
002
00
P
U
U
23
08
24
UNCLASSIFIED
U
P
0 050D
00
U
P
1A BS280640 S R F
1A XTS95065
F
1A YT470380 S
1B YT470550
F
1A YT4703SO S
1B YT47055O
F
1A YT470350 S
1B \T470550
1A XT895065
1A XT895065
F
1A BOS 8 0 0 S
08
18 BR950994
F
1A BS735160 S
1B BS755005
1C BR280800
10 BR290670
1E BR780700
1F BR770800
1A XT895065
F
1A BS730160 S
16 BS740050
H
1A ZA010120 S
1A XT895065
1A BT550015
F
1A BS780160 S
1B BS780980
1A XT6S0160
F
1A BS770160 S
18 BS780980
H
1A AR792246 S
1B AR803353
1C AR8 10356
1A XT895065
1A XT650160
F
1A BS790160 S
18 BS790980
1A XT895065
1A XT650160
1A XT895065
1A XT650160
1A ZC1 50660 S Z F
1A XT230570
1A BT550015
1A XT650160
1A XT158514 S
16 XT161519
1C XT165515
1D XT 168520
F
1A YC542779 S
1B YC488840 S
2A YC458909 S
2B YC429944 S
U XT905058
1A XT905058
1A XT605155 S
1A ZA010130 S
H
1A XT158514 S
16 XT161519
1C XT165515
10 XT168520
�UNCLASSIFIED
YYMMDD CTZ PRO
670610
670610
670611
670613 3
670613
670615 2
670615
6706 13 2
670615
670615
670615
670616
670617 4
670617
670617
670618
670619 2
670619
670619 2
670619
670619
670621
67062 1
670622 1
670622
670622
670622
670622
670622
670626 2
670626
670626
670626
670626
670627
670627
670627
670628
670628
670628
670629 1
602
769
670629
670629
670629
602
769
670630 1
670630
670630
603 2
760
670630
670630
670630
670630
670701 2
670701
670701
670701
670701
670701
H
GAL
T
U
u
U
21
0 000 0
40
08
0 00450 P
08
0 00150 P
42
U
U
0 000D
60
U
u
12
0 000D
20
YYMMDD CTZ PRO
1A XT630130
1A XT905058
1A XT905058
1A YT060450
1B YT060614
1A YA823393
1B YA753383
1A AR792246
1B AR803353
1C AR810356
1A XT905058
1A XT 905058
1A V0940610
' 18 V0890420
1A XT905058
1A XT905058
S
F
S
H
S
H
S
F
1A BP870990 S
F
1B 8P9 10020
08
0 00600 P
23
U 01000 D
01
0 000D
30
1A AR792246 S
1B AR803353
H
1C AR8 10356
08
0 060 F •
00
02
U 002
00
U 00121
U 00121
U OOOO2
U 00121
U 00121
U 002
00
U 00121
U 00121
0 000D
20
01
U
U 002
00
U 00121
U 00121
0 000D
30
11
W 070 D
29
17
U 002
00
U 00121
U 00121
0 000D
70
U 00121
U 00121
1A YT057460 S
1B
1A
1B
1C
10
1E
1F
1A
18
1A
1A
1A
1A
1A
1A
1A
18
1A
1A
1A
1A
18
1C
1A
1B
1A
1A
1A
1B
2A
28
1A
YT057486
YD000350 S
YD030290
YD060350
YD160310
YD060350
YD 100290
YA832382 S
YA76038S
XT650160
XT650160
XT650160
XT650160
XT650160
XT650160
XT650160
XT650160
XT650160
YC620790 S
YC54O970
XT230570
XT650160
XT650160
XT650160
YD220135 S
YD160100
YD125148
B0930120 S
CQ060900
XT650160
XT650160
XT650160
BN 180248 S
8N993248
8R690880
BR700820
XT630160
XT650160
F
F
H
F
F
F
670702
670702
600
772
670703
600'
773
670704
600
774
670704
670705
670705
600 2
776
670707 2
670707 2
670711 3
670711
670711
670711
670711
670711
67071 1
670714 2
670714
670715 2
670715
670716 2
670716
670716
670717 2
670717
670717
670718 2
670718
670718
670718 2
670718
670718
670719 2
670719
670719
670720 1
670720 2
602
770
670720
670720
670721
670721
670721 2
670721
670721
670722 2
670722
670722
670723 2
670723
670723
670724 2
670724 2
602
774
670724
670725 2
Page 22
H
GAL
T
.10
08
08
26
U
U 00121
U 00121
U 00121
U 00121
U
U 00121
U 00121
U 00121
U 00121
0 020
05
0 040D
00
0 00100 C
0 050
00
08
U 000D
30
07
0 000C
20
08
0 040P
00
OS
0
P
08
0
P
07
0 040D
20
08
0
05
08
0
0
13
LEG
1A BR4 15400
XT650160
1A XT650160
XT650160
1A XT650160
1A XT230500
XT650160
1A XT650160
XT650160
1A XT650160
1A BQ830840
1A YA880650
1A YA880650
1A XT990360
1B XT940470
1C XT960160
1D XT980150
1E YT010150
1F YT020140
1G YT010130
1B
1A
1B
1A
1B
1C
1A
18
1C
1A
IB
1C
1A
1B
1C
YA630540
BR730700
BR750820
AR792246
AR8033S3
AR8 10356
AR792246
AR803353
AR8 10356
AR792246
AR803353
AR810356
BR400670
BR330600
BR4 10600
F
F
S
G
S
G
S
G
S
F
P
1A AR792246 S
G
P
18
1C
1A
1A
18
1C
1A
1A
P
1A
P
18
1C
1A
18
1C
08
0
08
0 00380 P
12
08
W
0
P
08
0
P
UNCLASSIFIED
S Z F
H
S
H
S
S 2 F
1A YA640710 S
1B
0
S I M
• »
S
U
U 000
30
08
COORD
1A
1B
1C
1A
1A
18
1C
1A
AR803353
AR8 10356
BS242709 S E F
AR792246 S
G
AR803353
AR810356
XT895065
YT057486 S
F
YT057640
AR792246 5
G
AR803353
AR8 10356
AR792246 S
G
AR803353
AR810356
AR792246 S
G
AR803353
AR810356
C0170170 S R F
AR792246 S
G
AR803353
AR810356
AR792246 S
G
�UNCLASSIFIED
YYMMOD CTZ PRO
H
GAL
T
LEG
COORD
S I M
•
670725
670725
670726 2
670726
670726
670727 2
670727
670727
670728 2
670728
670728
670729 2
670729
670729
670730 2
670730
67073O
670801 2
670801 2
670801 2
670801
670801
670801
670820 1
670821
67083 1
670826 2
670826
670826
670826
670830 1
670830 3
670831 2
67083 1
600 2
795
670907 2
670908 2
670912 2
670912
670913 3
670915
670915 3
670922
602
792
670922
670922
670922
670925 4
670925
670925 3
670927 2
670927
670927
670927
670927
670927
670928
670929 2
670929 2
602
799
08
0
P
08
0
P
08
0
08
U
'.
P
08
0 050P
00
07
08
U
U
17
0 050C
00
05
U
U
10
U
03
21
10
0 00055 F
U
P
0 00100 0
08
08
08
08
B
B
8
0
00150 D
00100 D
020D
00
000D
30
23
03
23
03
U
U
U
U
P
P
P
P
33
U
W 04650 D
P
P
D
27
15
0
0 02750 D
13
07
U
B
0 040D
00
18 AR8033S3
1C AR810356
1A AR792246 S
1B AR803353
1C AR8 10356
1A AR792246 S
1B AR8033S3
1C AR8 10356
1A AR792246 S
1B AR8033S3
1C AR8103S6
1A AR792246 S
1B AR803353
1C AR8103S6
1A AR792246 S
1B AR803353
1C AR8103S6
1A BR465465 S
1A AR305350 S
1A BN529830 S
18 BN523847
2A BN486889
2B BN51S891
1A BS493045 S
1A BR685430
18 8R620640
1A B0873078 S
1B B0947077
1C B0936056
1D 809 12042
1A BT541013 S
1A YT0767S9 S
1A B0920120 S
1B B0900130
1A YA850700 S
1A YA860700 S •
1A YA850670 S
1A BR 160490 S
1B BR 160270
1A XT495473 S
1A BT550015
1A XT89S065 S
1A BT467068
1B BT468068
1C 8T465073
1D BT467074
1A BS497066
1A XS672082 S
1B XS675021 S
1A YS610750 S R
1A YU570370 S
16 YU475325
2A YU538368
2B YU455297
3A YU520380
3B YU473290
1A XT895065
1A BP650130 S R
1A BR 1003 10 S
18 BR170310
YYMMDD CTZ PRO
Page 23
H
GAL
T
LEG
COORD
S I M
• M
0
G
G
G
G
H
H
H
H
H
G
F
H
H
H
F
f
F
F
F
F
H
670929
670929
670930 2
670930
670930
670930
670930
671001 2
671001
671001
671001
671001
671003 2
671003
671003
671003
671003
671003
671004 3
671004 2
671004
671004
6710O4
671004
671O04
671004 3
671005 2
671005
671005
671006 3
671006
671006 2
671006
671007 2
671007
671007
671007
671007
671O07
671007
671007 2
671007
671009 2
671009
671009
671009
671009
671009
671009
671009
67100S
671009
671009
671009
671009
671009
671009 2
671009
671009
671009
07
0 040D
00
07
U
0 00225 D
07
0 040D
00
23
07
U
P
0 00150 D
23
07
U
P
0 00100 D
25
B 050
00
07
U 02OOO D
07
W 005 D
07
07
U 000D
30
07
0 00250 D
W 001OO
07
UNCLASSIFIED
W 00100 D
1C
1D
1A
1B
1C
1D
BR 170270
BR1 10270
BR100310 S
BR170310
BR170370
BR1 10270
H
1A YT078757
H
1A BR 150220 S
1B BR150230
1C BR 160220
1D BR 160230
1E BR 1602 40
H
1A BR 130230 S
1B BR 130240
1C BR 130250
1D BR 140250
1E BR 140240
1F BR 140230
G
1A XT700140 S
H
1A BR160240 S
1B BR 160250
1C BR 160260
1D BR 1702 40
1E BR 170250
1F BR 170260
H
1A XT700140 S
H
1A BR 140260 S
1B BR 140270
1C BR 150270
1A YT079442 S Z F
1B YT069388
H
1A BR163473 S
H
1B BR-1 10260 S
H
1A BR 130290 S
1B BR 130300
1C BR130310
1D BR 140290
1E BR 140300
1F BR 1403 10
1G BR 150300
F
1A BR 145460 S
1B BR 123290 S
H
1A BR 180340 S
1B BR 180370
1C BR 190380
1D BR 190390
1E BR 190400
H
1A BR200320
1B BR200330
1C BR2 10320
1D BR230370
1E BR240370
1F BR240330
1G BR240390
1H BR240400
11 BR250410
H
1A BR 180340 S
1B BR 180370
1C BR 190380
10 BR 190390
�UNCLASSIFIED
YYMMDD CTZ PRO
67 1009
671009
671009
671009
67 1009
671009
671009
671009
671009
671009
671010 3
671010 2
671010
671010
671010
671010
671010 2
671010
671010
671010
671010
671010
671011 3
671011 3
671011
671012 3
671012 3
671012
671012
671013 3
671013 3
671013
671014 3
671014 3
671014 3
671015
671020
671020
671020
671021 3
671023
671024 3
671024
671025 3
671025
671027 3
671027 3
671029 3
671030
671030
671103 2
671103
671104 3
671104 3
671104 2
671104
671104
671106 3
671106 3
671106 3
23
07
07
23
23
23
23
23
23
24
24 •
24
H
T
GAL
U
P
0 00100 D
W 00150
W 00150 D
U
U
U
U
U
U
U
U
U
U
U
U
U
U
U
P
P
P
P
P
P
P
P
P
U
OS
B
U
S
U
B
U
U
U
W
U
B
0
23
23
06
U
P
B 03150 D
0 020P
00
23
23
23
B 000D
30
U
P
23
23
23
23
23
19
B
01500 C
0700
00
01700 D
P
P
O1000
000P
05
0
LEG
COORD
S I M
1E BR 190400
'IF BR200320
1G BR200330
1H BR2 10320
11 BR230370
10 BR240370
1K BR2403SO
1L BR240390
1M BR240400
1N BR250410
1A XT630130
G
1A BR200340 S
H
1B BR2 10340
1C BR220330
1D BR240320
1A BR240330
H
1A BR200340 S
H
1B BR210340
1C BR220330
10 BR240320 •
1E 8R240330
1A BR845945
1A XT593218 S
G
1A XT700140
H
1A BR845945
1A XT605155 S
1A XT630130 S
G
1A BR845945
1A XT70O140
1A XT605155 S
1A XT630130 S
G
1A XT700140
1A XT390240 S
G
1A XT391245 S
1A XT390240 S
U BR84594S
1A YT897992
18 YT849994
1C YT898985
1A XT600460 S
H
1A BR845945
1A XTS00200 S
H
1A BR845945
1A XT6O02OO S
H
1A BR845945
1A XT605155 S
1A XT630130 S
G
1A YS440970 S Z F
1A XT968490
1A AR796346
1A BR000020 S
G
1B BRO 10020
1A XT605155 S
1A XT600200 S
H
1A YB86025O S
G
1B YB880270
1C YB890270
1A XT600200 S
H
1A XT630130 S
U X600 S H
T020
Page 24
H
YYMMDD CTZ PRO
671107 3
671108 3
671108
671109 3
671109 3
671109
671109
671111 3
671111 3
67 1 1 1 1
67 1 1 1 1
671111
671111
671112 3
671112 3
671112
6711 12
671112
671112 3
671112 2
671 112
6711 12
671113 3
671113 3
671113
671113
671114 3
671114
671115 3
671116 3
671116 3
671116
671116
671116 3
671116
671116
671116
671116
671117 3
671117 3
671117 3
671117
671117
671117
671117 2
671117 3
671117
671118 3
671118
671119 3
671119
671120 3
671120
671121
671122
671124
671124
671124
671124
671127 2
LEG
D
D
P
P
P
1A XT600200 S
1A XT600200 S
1A XT90S058 S
1A XT760380 S
•1A XT770380 S
1B XT764380
1C XT750385
1A XT770380 S
1A XT700380 S
1B XT700420
1C XT660420
1D XT660380
1A BR478447
1A XT770380 S
1A XT700380 S
1B XT700420
1C XT660420
10 XT660380
1A XT68539S S
1A BR870960 S
1B BR871955
1C BR655855
1A XT770380 S
1A XT920060 S
1B XT938063
1A XT895065
1A XT770380 S
1A XT84Q150
1A XT770380 S
1A XT660420 S
1A XT770380 S
1A XT760370 S
1B XT770380
1A XT70O380 S
1B XT700420
1C XT660420
1D XT6603SO
1A AR805460
1A XT660380 S
1A XT770380 S
1A XT700380 S
1B XT700420
1C XT660420
10 XT660380
1A B0813154 S
1A XT685395 S
1A AR80546O
1A XT700380 S
1A AR805460
1A XT895065 S
1A AR805460
1A XT760370
1A AR805460
1A CR080240
1A BR845945
1A XT770380
1A XT760370
U XT760370
1A XT760370
1A B0870260 S"
23
23
29
23
23
B 090
00
B 01800
U
U
U
23
23
B 00443 C
B
0
23
23
U
B 00443 C
B
D
07
B
U
C
P
23
29
B 00443 C
U
P
23
U
B 00443 C
23
U
23
23
23
B 043 C
04
U
C
B 043 C
04
23
B
23
23
23
U
C
B 00443 C
B
D
11
23
U 00055 D
B
C
U
U
C
U
U
P
U
U
P
U
U
U
U
U
0
U
23
29
23
U
10
UNCLASSIFIED
U
U 005 W
05
COORD
S I M
T
GAL
H
H
H
H
C
H
H
H
H
H
H
H
H
H
C
C
H
C
H
H
H
H
�UIMOLMOOITICL/
YVMMDO CTZ PRO
671130 2
671130 3
671204 3
671210 1
671211 3
671213 3
671223 3
671226
671230 2
671230
680101 3
680101 1
680101
680101
680101
680101
680101
680102 3
680102 3
680102
680102
680102
680102
680102
680102
680102
680102
680103
680103
680103
680104 3
680106 3
680109 3
680111
6801 1 1
680111
6801 11
680111
680111
6801 11
680111
680111
680111
680111
680111
680111
680111
680111
680111
680111
6801 1 1
680112 3
680114 2
680114
680114
680116 3
680124
680124
680124
680129 2
H
GAL
T
11
25
31
03
29
23
23
U OOO53 D
0
0
U
U
P
U
P
U
P
06
0 0000
60
23
02
U
P
0 000D
30
0 0 0 0D
30
U
23
23
U
P
8 040P
00
W 040P
00
0 000D
30
0 000
30
23
26
23
U
U
U
U
0
U
B
080P
08
01000 D
090P
09
060
00
U
U
23
08
23
07
B 00550 P
0 0000
30
U
8
B
B
3
009OO P
01000
01000
01OOO
00100 P
LEG
COORD
S 1 M
1A BOS70260 S
H
1A YT200SOO S R F
1A X5365808 S Z F
1A BT 133690 S 2 F
1A XT89S065 S
1A XT760370 S
1A XT630130 S
H
1B YB875203
1A YB7901 10 S
F
1B YB880190
1A XT6051S5 S
1A YD160412 S
F
18 YD307412
1A YB737044 S
18 YA739898
1C YA723880
1A XT650160
1A XT605155 S
1A XT630130 S
H
U XT630130 S H
1A YB726045
1B YA72690S
1C YA709882
1A YA653887
1B YA635815
2A YA6 13730
2B YA63581S
1A XT854160
1A XT85416O
1A XT854160
1A XT630130 S
H
1A YS015912 S Z F
1A XT630130 S
H.
1A XT634177
2B XT662175
3C XT665166
40 XT6851S8
5E XT685153
6F XT637178
U XT634177
28 XT662175
3C XT665166
40 XT685158
3E XT685153
6F XT637178
1A XT634177
28 XT662175
3C XT665166
40 XT685158
5E XT6851S3
6F XT637178
1A XT6S715S S
H
1A YV930950 S
F
1B YA940010
1C YA850070
1A XT630130 S
H
1A XT650160
1A XT650160
1A XT6S0160
1A BR473435 S
H
Page 25
YYMMDD CT2 PRO
680129
680130 2
680130
680201 3
680204 3
600
824
680208 3
680208
680209 3
680209
600 3
829
680209
680216 2
680218 2
680218
680218
680218
680218
680218 3
680218 3
680222 3
680222
680222
680222
680308 3
600
838
680308 3
680308
600 2
838
680308
680320 1
680322 3
680327 3
600 1
847
680407
680407 2
680407
680407 2
600
847
600 3
848
600
848
680411 2
680413 3
680421 1
680421
680421
680421
680421 3
680421
680422 3
680423 3
680423
602 3
844
680424 3
680424
680426 3
680426 3
680426
680426
602
846
H
T
GAL
07
B 00150 P
23
24
W 00450 P
B 01100 F
25
W
24
B
0
24
W
0
07
11
U
P
U 00110 C
24
24
23
26
W
B
U
U
U
U
W
27
W 000 0
30
11
0 090D
40
02
26
24
02
U
U
U
06
U 000D
20
12
U 0800
20
25
W 000D
60
10
23
03
W
0
0 000D
30
22
W 02825 0
23
23
W
0
w
o
00220 F
065 F
00
02420 P
000 0
60
0
P
P
U
0
U
23
26
w
23
23
0 01000 0
W
0
UNCLASSIFIED
o
W 000D
30
LEG
COORD
S I M
1B BR46S467
H
1A BR473435 S
1B 8R466467
G
1A XT760380 S
H
1A XT333898 S
1B XT337856
1A YT070570 S 2 F
1B YT080640
H
1A XT390780 S
1B XT425760
H
1A XT390780 S
1B XT42576O
H
1A BR465465 S
H
1A B0800640 S
1B B0800680
1C 808 10840
10 BOS 10680
1E B0790690
H
1A XT280674 S
1A XT280674
H
1A XT953516 S
1A XT280680
1A XT280680
1A XT280680
F
1A YS188786 S
F
18 YS 120786 S
F
1A YS673620 S
F
1B YS6O3593 S
F
1A 80368100 S
F
1B B0373100 S
F
U Y0757138 S
1A YT340S02 S
1A YD00048S
1A YD409193 S
1B YD501178
F
1A YA724842 S
1B YA654723
F
1A BP877980 S
1B CP008031
F
1A XT7 17520 S
1B XT70735O
1A C0200950 S Z F
G
1A XT674378 S
F
1A 2C141260 S
1B 2C200319
1C ZC 156252
10 ZC213325
F
1A XT569759 S
18 XT6 18877
G
1A XT783388 S
H
1A" XT674378 S
1A BR930930
1A XT783388 S
G
F
1A YS 180739 S
1B YS966739
1A XT790150 S Z F
1A XT764380 S
G
1B XT770379
1C XT770380
1D XT773372
�WI\IV^I_AAO
YYMMDD CT2 PRO
680426
680426
680426
06
680502 2
680502
06
630505 2
680505
680506 1
06
680506
24
680506 3
680506
680508 3
27
680508
08
680509 2
600
859
24
680509 3
680509
6805 1 1
6805 1 1
6805 1 1
6805 1 1
6805 1 1
6 0 11
85
680S 1 1
6805 1 1
6805 1 1
6805 1 1
6805 1 1
6805 1 1
680516 3
29
680516
680516
680519 1
02
07
680520 2
06
680520 2
680520
680520
630520
680520
680520
680520
680520
680521 3
18
680521
680522 1
01
680523 4
42
680523
680523
680523
680523
602
854
680526 1
02
680526
680527 1
02
680S27 1
06
680527
680527
680528 1
02
08
680528 2
23
680530 3
H
GAL
T
0 000D
60
0 000D
60
U 000D
30
U 0000
60
U 000D
30
0 000D
60
W 000 D
60
U
U
U
0 020P
02
U
F
0 00110 P
U 000D
30
U
U
U
U
U
U
W 000
30
B 00110 P
U
U
U
U
U
U
0
P
U
0
0
0 000D
20
U
0
D
8 00165 P
W 000 0
09
LEG
COORD
S I M
1E XT777373
1F XT779384
1G XT777373
1A YB750040 S
F
1B YA750880
1A Y8750040 S
F
1B YA750880
1A YB74Q043 S
F
1B YA705860
1A XT437815 S
F
1B XT300920
1A YS673620 S
F
1B YS603593
1A YA720840 S
F
18 YA650710
1A XT070818 S
F
18 XT 168952
1A WR830950
18 WR822946
2A WR845920
2S WRB39917
1A WR830950
1B WR822946
2A WR845920
28 WR839917
1A WR830950
18 WR822946
2A WR845920
28 WR839917
1A YT 153027 S
H
18 YS163997
1C YS318667
1A YD706102 S
H
1A BR927757 S
H
1A YA917890 S
f
18 YA912020
1A XT151009
1A BT533094
1A XT151009
1A BTS33094
1A XT151009
1A BT533094
1A YS800837 S
F
18 YS632837
1A BS800177 S
H
1A WQ055487 S E F
1A YT1S1009
1A BT533094
1A YT151009
1A YT 15 1009
1A 6T533094
1A Y0808162 S
1A BTS33094
1A YD620095 S
H
1A AS890703 S
F
18 AS888880 S
1A BT533094
1A YD620095 S
H
U AR780330 S G
1A XT923252 S
H
Page
YYMMOD CT2 PRO
H
GAL
T
680530
680531 3
23
W 000D
09
680531
680S31 2
08
B 00550 P
26
630601 3
0 00150 0
680601
680601
680601
08
680601 2
B 00495 P
680601 3
21
W 0000
60
680601
680601
U 020
00
680601
U
600 3
862
26
0
-D
680602
680602
680602
27
680602 3
W 02825 0
680602
680602
28
680602 3
0 000D
30
600
862
600
862
0
600
862
U 020
00
680602
U
680603 3
26
0
0
680603 3
26
U
D
680603
680603 1
02
0 '
0
680603 3
21
U 000D
30
600
863
600
863
U 020
00
600
863
U
600 3
864
26
W 00110 D
600
864
U 020
00
600
864
U 00055 '
680605 3
26
U
D
680605
U 020
00
680605
U
600 1
866
02
U
0
600
866
U
600
866
U 002OO
600
866
U
600
866
600
866
600
866
68O606
600 1
867
02
0
F
600
867
600
867
600 1
867
01
0 020P
00
600 1
867
02
0 020D
00
600
867
U 020
00
04
680608 1
0 00010 D
600
868
U 020
00
600 3
869
26
U
D
18
W 0000
60
600 3
869
600
869
600
869
U 020
00
26
680610 3
0
0
UNCLASSIFIED
LEG
COORD
26
S I M
1B XT910233
H
1A XT896227 S
18 XT911233
G
1A AR780330 S
H
1A XT920256 S
1B XT933253
1C XT923227
10 XT913233
Q
1A AR780330 S
F
1A XT900692 S
18 YT070692
1A WS815135
1A YD620095
H
1A XT900220 S
2A XT900230
3A XT9 10220
4A XT9 10230
1A YS090780 S
18 YS020780
1C YS090780
1A XT268785 S
18 XT099770
1A YD620095
1A WS815135
1A BT533094
H
1A XT973049 S
H
1A XT9 10260 S
1B XT930250
H
1A YD620095 S
1A YT 133634 5
F
1B YT 105688
1A WS815135
1A BT533094
H
1.A XT900270 S
1A WS815135
1A BTS33094
H
1A XT890280 S
1A WS815135
1A BT533094
1A YD620095 S
H
1A YD878128
1A WS815135
1A BT533094
18
657895
1C
645889
1D
637897
2A
707884
H
1A YD625092 S
18 YD713106
2A YD803160
H
1A YD 150735 S
H
1A YD1 17702 S
1A WS815135
G
1A BT534030 S
1A WS815135
1A XT931234 S
H
1A YS780858 S
F
18 YS605859
1A WS815135
H
1A XT860150 S
�UNCLASSIFIED
YVMMDD CT2 PRO H
GAL
T
LEG COORD
S I M
X
680610
6806 1 1 1
680611 1
680611 2
6806 1 1
680612 2
680612
680613 2
680614 3
680614 2
680614
680614 2
680615 3
680615 1
680615 1
680615 1
680615
680618 1
680618
680618 3
680618
680618
680618
680618
680619 1
680619 1
680619
680619
680619
680619 2
680622 2
680623 1
680623 3
680623 3
680624 1
680624 1
680624 3
680624 3
680624 2
680624 3
680624
680625 2
680625
680625
602
865
680625
680626 1
680626
680626
680626
680626 1
680626
680626 2
680626 3
680626
680626
680626
680627 2
680627 2
680628 1
08
26
08
U
0
0
B
U
B
U
B
0
0
08
26
02
01
02
B 00495 P
0
D
0 00100 P
0 00100 P
0
D
02
U
27
U 000D
50
02
02
U
0
0
02
02
08
08
08
07
03
28
.28
02
02
28
28
07
27
020
00
00100 P
D
065 P
00
060P
06
00550 P
D
000D
60
D
W
0
a oosso P
B 00110 P
0
B 00275 P
W 045 P
06
U
f
0
B
W
B
W
D
P
P
P
D
00275
00465
040
04
02900
07
0 005P
05
U 00715
03
0 020D
00
03
0 00100 W
07
27
B 00110 P
U 000D
30
07
07
03
B 00110 P
B 00220 P
0 00300 F
Page 27
YYMMDO CTZ PRO
H
GAL
T
*
1A WS815135
1A Y0330335 S
H
H
1A YD795106 S
G
1A AR780350 S
1A YD704101
G
1A AR780340 S
1A XT860150
G
1A AR780340 S
H
1A XT910280 S
F
1A YA880020 S
1B YV8808SO
G
1A AR780340 S
H
1A XT860130 S
H
1A YD330335 S
1A YD372424 S
H
H
1A YD630170 S
1B YD650150
H
1A YD650150 S
1B YD640170
1A YS282687 S
F
1B YS282774
1C YS278687
10 YS278774
:1A YD808162
H
*1A Y069O030 S
H
1A YD740065 S
1B YD753065
1C YD762061
10 YD76105S
G
1A AR800360 S
1A BR9277S7 S
H
1A BT26S018 S Z F
H
1A XT6571S5 S
H
1A XT657155 S
H
1A YD704101 S
H
1A YD69O018 S
H
1A XT657155 S
H
1A XT657155 S
1A BR478486 S
H
F
1A YS568874 S
1B YS568800
H
1A BR4S3468 S
1A WR830950
2B WR823945
3C WR838917
40 WR845920
H
1A YC740065 S
1B YC750048
1C YC761055
1D YC715015
H
1A YC758127 S
1B YC779123
G
1A BR478486 S
1A YS863979 S
F
1B YS383977
1C YS968931
1D YS000035
1A BR478486 S
G
1A BR478486 S
H
H
1A YC705058 S
680628
680628
680628
27
680628 3
680628
680629 1
02
680629 1
02
680629 1
02
680629 2
06
680629
680629 1
03
26
680630 3
02
680701 1
680701
680702 1
02
680702
680702
680702
680702 2
08
26
680703 3
680703
680703
680703
680703
680703
600 1
873
02
680703
680703
600
873
680703 1
02
680703 2
08
680703
680703 2
08
600
874
600 3
874
26
680704
680704
680704
680704 2
08
' 6 0 0 208
874
600
874
680705 3
26
680705
600
875
600
875
600 3
876
26
600
876
600
876
680706
600
876
600
876
600
876
26
680709 3
680709
600
879
680709
600
879
600
879
24
600 3
879
08
600 2
879
UNCLASSIFIED
W 000D
40
0
0
D
0 080P
00
W 00150 C
W 00225 P
B
0 020D
00
0 030D
00
B 00240 C
W
0
0 020D
00
0 00100 D
B 020C
05
B 00350 C
W
D
B OOO75 C
B 00075 P
B 00110
W
0
W
D
W
D
W
B 00110 C
LEG
COORD
S I M
•*
1B YC740065
1C YC712018
1D YC764055
F
1A YS800808 S
1B YS632808
1A YC700950 S Z F
H
1A YD797109 S
H
1A YD808162 S
H
1A ZB780710 S
1B Z88 20320
H
1A ZB030930 S
1A YS140510 S R F
H
1A YC634985 S
1B Y0675002
H
1A YC620950 S
1B YC620960
1C YC620970
1D YC620980
H
1A BR1 10250 S
1A XT876094 S
G
2A XT877107
3A XT890100
4A XT880094
5A XT890105
6 A XT880100
H
1A YC620950 S
18 YC620960
1C YC620970
10 YC620980
1A YD60S302 S
H
H
1A BR 130250 S
1B BR 130260
H
1A BR120160 S
1B BR812176
G
1A XT890105 S
2A XT900105
3A XT890098
4A XT900098
H
1A BR120130 S
H
1A AR800330 S
1A BS814175
G
1A XT877093 S
2A XT880093
3A XT877072
4A XT880072
1A XT877072 S
G
2A XT880072
3A XT877068
4A XT880068
5A XT880080
6A XT885080
7A XT880075
1A XT880076 S
G
2A XT885076
3A XT885075
4A XT887072
5A XT880068
6A XT886068
1A XTOS0800 S Z F
1A BR 130230 S
H
�UNCLASSIFIED
YYMMDD CTZ PRO
H
GAL
T
LEG
COORD
S I M
YYMMDD CTZ PRO
Page 28
H
GAL
T
LEG • COORD
S I M
••
680710 3
680710
680710
680710
680710
680710
680710
680710
680710 2
680710 1
680710
680710 2
680710
680711 3
680711
680711
680711
6807 1 1
680711
680711 2
680711
680712 3
680712
680712
680712 3
680712 3
680712 3
680712
680713 3
680713
680713
680713
680713
680713
680713
680713 2
680713 3
680713
680714 3
680714 3
680714
680714
680714
680714 2
680714 2
680714 3
680714
680714
680714 •
680715 3
8 0 13
87
680715
680715
6807 13 1
680716 3
680716
680716
680716
680717 3
680717
W
26
D
1A XT890078 S
2A XT892077
3A XT898078
G
4A XT898079
08
02
B 00110 C
0000D
20
07
U 03400 D
26
W
D
5A
6A
7A
8A
1A
1A
1B
1A
1B
1A
2A
3A
XTS99080
XT899081
XT894080
XT894079
BR 150230
YC688959
YC638982
BR932895
BR929970
XT884076
XT884077
XT890079
S
S
H
F
S
F
S
G
4A XT887078
08
B 00110 C
26
W
28
28
28
26
06
28
26
D
B 00110 P
W 00165 P
0 040P
04
U
W
D
8 00110 C
U 000D
50
0 000P
07
W
D
06
08
28
B 00110 C
B 00150 P
00900
00
26
W
02
26
26
D
0 00100 D
W
D
W
D
3A XT890084
6A XT8S5077
1A BR 140230 S
1B BR090240
1A XT884076 S
2A XT890078
3A XT890O70
1A XT6S7155 S
1A XT6S71S5 S
1A XT6S71SS S
1A YD808162
1A XT890070 S
2A XT890074
3A XT895073
4A XT900074
5A XT902071
6A XT895068
7 A XT901069
1A YA890770 S
1A YS171695 S
1B YS068771
1A XS744698 S
1A
2A
3A
4A
1A
1A
1A
1B
1C
1D
1A
2A
3A
4A
1A
1A
2A
3A
4A
1A
2A
XT890075
XT890074
XT902074
XT902075
YA890770
AR800350
XS670700
XS720700
XS7 10660
XS660680
XT890074
XT890077
XT895074
XT895077
YD60528S
XT895074
XT895077
XT902075
XT902077
XT890084
XT895084
S
H
G
H
H
H
G
H
F
H
G
S
S
S
H
H
H
S
G
S
S
S
H
G
G
680717
680717
680717
680717
680718 3
680718
680718
680718
680718
680718
680718 3
680718 2
680719 3
680719
680719
680719
680719 2
680719 3
680719
680719
680719
680719
602 3
870
680720
680720
680720
680720
680720
680721 3
68072 1
680721
680721
680722 3
680722
680722
680722
680723 1
680723
680723
680723
680724 3
602 3
875
680725
680725
680725
680725 3
680726 2
680726
680726
680726
602 3
876
680726
680726
680726
680726
680726
680726 3
680727 3
680727 1
680727 1
3A XT895074
4A XT902080
26
W
29
O6
26
W
D
B 00330 P
W
D
08
26
0 00270 P
W 03000 D
26
U
W
D
26
W
D
26
W
D
10
U 03000 D
29
26
U
U
U
W
29
07
U
D
B 00110 D
26
W
D
29
29
02
02
U
U
0
0 00100
D
D
P
F
UNCLASSIFIED
D
D
D
5A XT902077
6A XT390077
G
1A XT890083 S
2A XT890087
3A XT896079
4A XT895079
5A XT895083
6A XT896087
G
1A XT915155 S
G
1A ZA230870 S
G
1A XT896085 S
2A XT903085
3A XT903080
4A XT896079
G
1A BR 140530 S
F
1A YT201267 S
1B YT200200
1C YT223200
1D YT223276
1A YD623302
G
1A XT908100 S
2A XT914100
3A XT9 15097
4 A XT915O93
3A XT9 13092
6A XT908095
G
1A XT900110 S
2A XT903110
3A XT904103
4 A XT900104
G
1A XT908110 S
2A XT903110
3A XT915100
4A XT900101
F
1A B0763920 S
1B B0845730
1A XT953726
1A XT913155
G
1A XT98O050 S
1A XT908117 S
G
2A XT915117
3A XT912110
4 A XT908110
G
1A XT 980050 S
H
1A BS657000 S
1B BS657026
1C BS680000
10 SS680026
1A XT900113 S
G
2 A XT908113
3A XT908103
4 A XT905104
5A XT903110
6A XT900110
1A XT980050 S
G
G
1A XT980050 S
H
1A YD472011 S
H
1A YD625092 S
�UNCLASSIFIED
YYMMDO CTZ PRO
680727
680728 2
07
680728 2
07
680728 1 02
680728 1
02
680728
680728 3
23
680729 3
26
680729
680729
680729
680729 2
07
602
879
680729
680730 3
26
680730
680730
603
870
680731 3
680731 2
08
680731
680731
680801 3
26
680801
680801
680801
680801
680801
680801 1 02
680801
680801
680801
680801
680802 1 02
680803 2
17
680803
680803
680804 3
26
600
884
6808O4
6808O4
600 3
885
26
680805
600
885
680805
680805
680805
680805
600
885
680805
680806
600
886
680811 1 02
680811 1
02
680811
680812 1 02
680813 3
25
680813
680813
680813
H
GAL
T
B
0
0
0
00055 C
00055 C
00075 P
00025 F
U
W
P
D
U 000D
20
W
D
W
D
B 01500 P
W
0
U 000 0
30
U
U
U
0 020P
00
(3
D
W
W
D
D
0
0
B
8
0
U
00100 P
00100 P
00100
020P
00
0
Page 29
YYMMDD CTZ PRO
1B Y0705100
1A BS875010 S
1A BS875010 S
1A YD472011 S
1A YD625092 S
1B YD705100
1A XT980050 S
1A XT900119 S
2A XT907119
3 A XT900113
4A XT907113
1A B0820350 S
1B 80820160
1C BQ790160
1A XT907119 S
2A XT915118
3A XT907118
4A XT914117
1A XT980050 S
1A AR780330 S
1B A R 780340
1C AR780350
1A XT907119 S
2A XT915118
3A XT915120
4A XT911120
5A XT911123
6A XT907124
1A YC761999 S
18 YD734094
1A XT 15 1009
1A XT953726
1A XT953726
1A YD473021 S
1A BR939970 5
1B BR937890
1C BR935970
1A XT902126 S
2A XT907126
3A XT907124
4A XT900124
1A XT9O8127 S
2A XT911128
3A XT913129
4A XT918129
5A XT917123
6A XT912123
7A XT912120
8A XT911120
9A XT911123
1A
637897
2B
713894
1A YD55003S S
1A Y0473021 S
1A XT640350
1A YD735135 S
1A XT940320 S
2A XT940290
3A XT000320
4A X 0 0 9
T020
H
H
H
H
G
G
F
G
G
H
G
F
H
F
G
G
H
H
H
680813 1
6808 1 3
6808 1 3
680814 1
680814
680814
680814
680821 1
680821
680821
680821
680823 2
602 2
886
680828 1
680830
680830
6SO831 2
680831
680831
680904
600
894
600 1
899
600
895
680905
68O905
680905
680905
600
896
68O907
600
897
600
897
600
897
600
897
600
897
680907
680908 1
680908
600 1
899
600
899
680910 1
680910
680911
680913 1
680914 3
680914
680914
680914
680914
680915 1
680915
680916 1
680916 1
680916
680916 1
680917 3
680917
680917 1
680918 1
680918
680918 1
H
05
U
U
0
0
U
U
U
B
B
02
02
GAL
T
LEG
P
G
1A BS578730 S
1A YD737133
1A YD735134
1A YD735134 S
H
1A BT 199389
1A YD623302
1A BT199389
1A Y0540546 S
G
1A BP220920
1B BP200890
1C BP 100840
1A BR465467 S
G
1A BP635995 S Z F
H
1A YD820130 S
1A WS85508S
1B WS843098
1A B09009SO S Z f
1A BT533094
1A YD598256
1A WS724151
1B WS713122
1A BT549016 S
1A WS738169
1B WS714113
2A WS713111
1A XT895065
1A XT798543
1A XT77361S
1A WS8 16026
1B WS812012
1C WS809003
10 W5795962
1E WR80899S .
1F WR803982
1G WR802983
H
1A YD590250 S
1A XT895065
H
1A YC555656 S
1A XT895065
F
1A YC576830 S
1B YC549980
1A XT895065
H
1A YD555955 S
1A XT 9 7 126 S
0
G
2A XT923133
3A XT913136
4A XT912130
5A XT907129
H
1A YOS37990 S
1B YD54994Q
1A BT549016 S
1A YD537990 S L H
1B YD549940
1A 8T533094 S
G
1A XT890080 S
G
18 XT890090
G
1A BT528110 S
1A YD537990 S
H
1B YD549940
1A BT528110 S
G
00100
00100 P
00027 P
000
20
07
12
02
B 00055 P
U
0 00100 P
B 00055
10
B
U
U 0010O
B 000
05
03
U
P
B 000
05
U
U
U
0 000
05
02
B 020 W
00
U
0 00100 F
U
0 000D
30
02
26
0
W
02
0 OO100 W
03
02
U
03
U
P
w
o
03
02
U
P
03
U
02
02
U
UNCLASSIFIED
D
0
P
0 00100 W
0 020W
00
P
COORD
S 1 M
�UNCLASSIFIED
YYMMDO CT2 PRO
H
GAL
T
LEG
COORD
S I M
YYMMDD CTZ PRO
Page 30
H
GAL
T
LEG
COORD
SI M
* «
680919 a
680919
680920 3
680921 3
680921
680921
680921
680922 3
680922
680922
680922
680924 2
680924
680924
680924
680925 3
680925
680925 3
680926 1
680926 1
680926 1
680926 1
602 3
896
602
896
680926
680926
680926
680926
680926
602
896
680926
602
896
680926
680926
680926
680926
680926
680926 3
680929 3
680929 3
680929
680930 3
680930 3
681002 3
681002
681002
681002
681002 1
681O03 1
681003 1
610 1
804
681005 1
681005 1
681006 2
681007
681007
681007
681007
681014 3
681014
07
29
26
26
W 01800 P
W 02400
W
D
W
D
W
D
07
B 050 C
20
23
W
23
02
02
02
02
23
W
B
B
B
B
W
23
31
21
24
19
26
03
02
03
03
02
03
07
D
00165
020
00
020
00
020
00
020
00
030
03
F
0
P
P
P
W 00165 P
U
U
U
W 030 P
05
U
P
W 020 D
02
U
P
0
P
U
P
U
P
0 020P
00
U
P
W 01800 P
U
29
U 020 0
02
1A BR470470 S
1A BR608456
1A XT900080 S
1A XT904120 S
2A XT904131
3A XT907131
4 A XT908142
1A XT908130 S.
2A XT912132
3A XT912127
4A XT908123
1A BR940000 S
1B B 9 0 0 S
0496
2A B0928875 S
2B B09 16868 S
1A XT890120 S
1B XT900120
1A XT6S7155 S
1A Y0620095 S
1A YD766070 S
1A Y0739132 S
1A YD706102 S
1A XT593218 S
1B XT605155:
1C XT635291
10 XT639151
1E XT642157
1F XT650168
1G XT653163
1H XT6S3164
11 XT6S5150
1d XT655151
1K XT657161
1L XT660150
1M XT662155
1N XT666156
10 XT698151
1A XT65715S S
1A XS4O83OO S 2
1A YT440930 S Z
1A XT895065
1A XT280674 S
1A YT280101 S
1A XT905150 S
2A XT908150
3A XT908160
4A XT905160
1A BT537004 S
1A V0808162 S
1A BT537004 S
1A BT5 11040 S
1A YD797109 S
1A BT5 11040 S
1A CR050150 S
1A WS797158
1B WS810147
2A WS777129
2B WS769141
1A XS976952 S
1B XS971959
H
G
G
G
G
H
H
H
H
H
H
H
F
F
H
H
G
G
H
G
G
H
G
H
G
• *
681014 3
681014
681014
681014
681016 3
681016 3
681016 3
681016
681017
681017
681017 3
681017 3
681017
681017
681017
681018 3
681019 3
681019
681019 3
681019
681019
681019
681021 3
681021
681021 3
681021
681021
681021
681021
68 1021
681021
681021
681021
681021
681022 3
681022
681022
681022
681022
681022 3
681022
681023 3
681023
681023 3
681023
681023 2
681023
681023
681023
681024 3
681024 3
681024
681024
681024
681024 3
681024
681024
681024
681024
681024
26
W 00275 D
24
24
24
B 020P
02
B 020P
02
B 040P
04
U
0 000D
60
24
24
B 00413 P
B 00412 P
B 00825 F
26
29
U 00385 D
U 005 W
05
18
U 00220
29
U 002 0
08
26
U 00110 0
U
U
18
U 00330 0
29
U 030 D
03
26
U 00275 D
29
U
13
U 000 D
20
23
26
0
D
U 040D
04
31
U 00330 0
UNCLASSIFIED
D
1A XT978235 S
2A XT770237
3A XT770220
4A XT780220
1A XT330903 S
1A XT080815 S
1A XT334904 S
1A XT895065
1A YB227348 S
18 XB941243
1A XT330903 S
1A XT080815 S
1A XT334904 S
2A XT09S753
3A XT280685
1A XT895065 S
1A XS947952 S
16 XS948947
1A YT900170 S
1B YT930170
2 A YT90014Q
2B YT93014O
1A YS034962 S
1B YS022963
1A XT907168 S
1A WS724151
1B WS722143
1C WS718'136
10 WS713122
1E WS712148
1A WS842094
1B W 8 4 9
S406
2A WS3510S6
2B WS854087
1A YT908147 S
2A YT912145
3A YT917147
4A YT914161
5A YT909161
1A XS997924 S
1B YS002933
1A XT912166 S
2A XT9221S6
1A XS971960 S
1B XS976952
U 2T270273 S
1B ZT233257
1C ZT207208
10 ZT260147
1A XT960499 S
1A- XT88S192 S
1B XT890182
1C XT888194
10 XT893183
1A XS025950 S
1B XS040945
1C XS045938
10 XS040920
1E XS034920
1F XS027930
G
H
H
H
F
H
H
H
H
H
H
G
G
H
H
G
H
F
H
H
H
�UNCLASSIFIED
YYMMDD CTZ PRO
681024 3
681024 2
681024
681024
681024
681025 3
681025
681025 3
681025
681025
681025
681025 3
681025
681025
681025
681026 3
681026 3
681026
681026
681026
681026 3
681O26 3
681026
681026
681026
681027 3
681027 3
681027 3
681027 3
681027
681027
681028 3
681029 3
681029
681029 3
681029
681029 3
681029
681029 3
681029
681030
681030
681030
681030
681031 3
681031
681031
681031
681101 3
681101
681101
681101
681103
681104 3
681104
681104
681104
681105 3
681105
681105
H
GAL
T
29
s 00010
11
U 000 D
30
29
8 00357 D
28
C 00963 W
28
0
D
23
26
0 002D
08
0 009 D
03
29
28
B 001
00
0 093 W
06
26
26
26
26
0 00163 D
0
D
0
D
0
D
8 010
00
0
26
29
B 020D
02
B 001 10 D
29
B 00110 D
29
B 00330 D
26
B 00110
U
26
26
U 00165
W 00330 W
0
26
U 040
04
26
W 065
00
LEG
COORD
S I M
•*
1A XS783967 S
1A 603 16045 S
1B BQ280050
1C B 2 0 8
0900
10 B03 16045
1A XS9S797S S
1B XS958964
1A XS566924 S
18 XS525953
2A XS530930
2B XS488965
1A XS566924 S
1B XS525953 S
2A XS530930 S
2B XS488965 5
1A XT974499 S
1A XT890189 S
2A XT893192
3A XT893183
4A XT897185
1A XS754940 S
1A XSS66924 S
1B XSS259S3
2A XS530930
2B XS488965
1A XT890192 S
1A XT894194 S
1A XT891189 S
1A XT895192 S
1A YD808162
1A YD808162
1A YS026935 5
1A XS974977 S
18 XS976982
1A XS977986 S
18 XS977994
1A XS975964 S
1B XS955967
1A XS978992 S
1B XS989972
1A WS7S4032
18 WS785028
2A WR726998
28 WR730996
1A XT932169 S
2A XT936173
3A XT936175
4A XT930171
1A YS036966 S
18 YS056967
1C YSOS0944
1D YS032962
1A BN750870
1A YS056956 S
1B YS046968
2A YS'016917
2B Y 504 2907
1A YS042939 S
1B YS043934
1C YS049954
G
F
H
H
F
F
F
F
G
G
G
H
G
G
G
G
H
H
H
H
H
G
G
H
H
YYMMDD CTZ PRO
681 105
681105
681105 3
681105
681106 3,
681106
681106
681107 3
681107
681107 3
681107
681107
681108 3
681108
681109 3
681109
681110
681110
681110
681110
681 110
681110
681111 3
681111
681112
681113
681113
681113
681113
681113
681114 3
681114
681114
681114
681115 3
681115
681115
681115
681115
681116 3
681116
681116
681116
681116
681117
681117
681117
681118 2
681118
681118
681118
681118
681118
681119 2
681122 4
681122
681122
681122
681122
681122
Page 31
H
GAL
T
19
U 000D
60
26
W 00330 D
25
U
0
19
0
26
U
W 025 W
07
26
W 040 W
05
W 040
05
23
B 090 P
09
U
U
W 00550
23
U
B 01650 F
23
B 065 F
00
23
U
B 01650 F
U
W 00330
O6
U
0 000
30
07
33
U
U
B
W 040P
00
UNCLASSIFIED
LEG
COORD
S IM
••
10 YS013916
1E YS006906
F
1A YT660303 S
1B YT524227
1A YS042907 S
G
1B YS041920
1A BT533094
1A YT215380 S Z F
18 YT080230
1A YT610770 S Z F
1B YT540630
1A BT533094
G
1A YS013916 S
18 YS019921
1A YS019921 S
G
18 YS024937
1A XS998898
1B XS997922
1C YS053944
1D YSOS5946
1E YS020976
1F YS011965
H
1A XT6S7155 S
1A BT533094
1A BT533094
1A YS0169S4
18 YS022963
2A YSO 19962
2B YS025937
1A BT533094
U XT6S3176 S
H
18 XT678194
2A XT665170
2B XT683183
1A XT677194 S
H
1B XT682183
2A XT692203
28 XT697194
1A BT533094
H
1A XT6922O1 S
18 XT697194
2 A XT705210
2B X7711210
1A BT533094
1A YS026940
1B YS020920
1A BT533094
1A YA670730 S
F
1B YA6407SO
1C YA630820
1D YA700870
1A XT700380
1A BT533094
U BR250260 S Z F
1A XS498460 S
G
18 XS499459
1C XS505459
10 XS505455
1E XS500450
1F XS505455
�UNCLASSIFIED
YYMMOD CTZ PRO
H
GAL
T
YYMMDD CTZ PRO
Page 32
H
GAL
T
LEG
COORD
S I
X •
681 122 2
681122
681122
681122
681122
681122 3
681122
681122
681122
681122
681126 2
681126
681126
681126
681126
681126
681126
681126
681126
681126
681126
681126
681126
681126
681126
681126
681126
681127 3
681128 3
681128 1
681128
681128
681128
681129. 3
681130 3
681130
681130
681201 1
681202 3
681202 3
681202
681202
681203 2
681203
681203
681203
681203 3
681203
681204 3
681205 3
681207 3
681207
681207
681207
681207
681207
681207
681207
681207
681207
06
0
23
B 01045 F
07
B 080P
00
U 00100
25
25
02
W
0
W
D
B 005 P
07
26
U
U
W
W
U
U
B
W
U
U
U
W
14
W 03OOO
25
25
26
W
W
W
25
25
02
25
23
000
02
000
02
0
D
000
02
000
03
01200 P
0
000
03
0000
20
0
0
P
1A YB7702SO S
16 YB8202.10
1C YB850240
1D YB870240
1E YB900270
1A XT663174 S
1B XT664172
2A XT697194
2B XT711210
3A XT709210
1A BR453493 S
18 BR457494
1C BR460457
10 8R460470
1E BR460490
1F 8R466467
1G BR473435
1H BR473470
11 BR475455
10 BR476476
1K BR476487
1L BR478434
1M BR480450
1A WS842094
18 WS844096
1C WS8S1086
10 WS8S6087
1A XT950240 S
1A XT950240 S
1A YD838138 S
1B YD842143
1A WS7241S1
1A WS722143
1A XT950240 S
1A XT950240 S
1A WS718136
1A WS713122
1A YD927073 S
1A XT590950 S R
1A XT950240 S
1A WS812168
1A Y0623302
1A XT953726 S
18 XT962780
1C XT963880
10 XS529928
1A YT719009 S
18 YT590946
1A XT9S0240 S
1A XT950240 S
1A YT13O050
18 YT130108
1C YT116105
10 YT 103095
1E YT 110080
1F YT093062
1G YT093050
1H YT 130050
2A YT060110
28 YT090112
F
H
G
G
G
H
G
G
G
F
G
F
F
G
G
681207
681207
681207
68 1 207
68 1 207
681208 3
68 1 208
681208
68 1 208
681208
681208
681208
681208
681208
681208
681208
681208
681208
681208
681208 2
681208
681208
681208
681208
681208
681208
681208
681208
681208
681208
681208
681208
681209 3
681209
68 1 209
681209
681209
681209
681209
681209
681209
681209
681209
681209
681209
681209
681209
681210 2
681240
681210
681210
681210
681210
681210
681210
681210
681210
681210
681210
681210
23
B 040 P
04
07
B 040 P
00
26
W
07
B 040 P
00
UNCLASSIFIED
P
2C YT090108
2D YT070107
2E YT066098
2F YT049099
2G YT060110
1A XT593218 S
18 XT605155
1C XT635291
1D XT639151
1E XT642157
1F XT650168
1G XT653163
1H XT653164
11 XT655150
10 XT655151
1K XT657161
1L XT650150
1M XT662155
1N XT666156
1A BR453493 S
16 BR457494
1C BR460457
1D BR460470
1E BR460490
1F BR466467
1G BR473435
1H BR473470
11 BR475455
10 BR476476
1K 8R476487
1L BR478434
1M BR480450
1A YT 130050 S
18 YT130108
1C YT116105
1D YT 103095
1E YT 110080
1F YTQ93062
1G YT093050
1H YT 130050
2 A YT0601 10
2B YT090112
2C YT090108
20 YT070107
2E YT066098
2F YT049099
2G YT060110
1A BR453493 S
18 BR457494
1C BR460457
1D BR460470
1E BR460490
1F BR466467
1G BR473435
1H BR473470
11 BR475455
10 BR476476
1K 8R476487
1L BR478434
1M BR480450
H
G
H
G
�UIVWL.MO oincL/
YYMMDD CTZ PRO
H
GAL
T
LEG
COORO
S I M
YYMMOO CTZ PRO
Page
H
GAL
T
LEG
COORD
33
S I M
9
681211
681215 3
681215 4
681215 2
681215
681215 4
681215
681217 3
681217
681217
681217
681217
681217
681217
681217
681217
681217
681217
681217
681217
681217
681217
681218 3
681218
681218
681218
681218
681218
681218
681218
681218
681218
681218
681218
681218
681218
681218
681219 3
681219
681219
681220 3
681220
681220
681220 2
681220
681220
681223 3
681223 3
681223
681226 3
681227 2
681227
681227
681227
681227 3
681228 3
681228
690103 4
690103 1
690103 1
24
34
07
33
26
26
U
U
D
W
D
B 060 P
00
0 00110
U
W
P
W
P
29
W
0
29
U
D
07
U 000D
30
23
23
U
P
B 040 P
04
28
07
B 00385 0
0 007P
00
28
22
B 00386 0
W 000 D
60
42
03
03
0
U
U
0
1A BS599919
1A XT25S557 S
1A XS910170 S
1A BR287455 S
1B BR308457
1A XS660630 S
1A XT895065
1A YT 130050 S
1B YT130108
1C YT1 16105
10 YT 103095
1E YT 110080
1F YT093062
1G YT093050
1H YT1300SO
2A YT060110
2B YT090112
2C YT090108
2D YT070107
2E YT066098
2F YT049099
2G YT060110
1A YT 130050 S
1B YT130108
1C YT1 16105
10 YT 103095
1E YT 110080
1F YT093062
1G YT093050
1H YT 130050
2 A YT060110
2B YT090112
2C YT090108
2D YT070107
2E YT066098
2F YT049099
2G YT060110
1A X5860970 S
1B XS860980
1C XS870960
U XS860970 S
1B XS86O980
1C XS870960
1A CR091440 S
1B CR087498
1C BR990590
1A XT605155 S
1A XT636157 S
1B XTJB64165
1A XS660630 S
1A BS880008 S
1B B5883055
1C BS875008
10 BS8 5 0 8
66
1A XS660630 S
1A XT782982 S
1B XT784139
1A WR680000 S R
1A BT452039 S
1A BT292229 S
G
G
G
M
H
H
'
G
G
F
H
H
G
H
F
F
690103
690103
690103
690103
690103
690103
690106 4
690106
690106 3
690106
690106
690106
690106
690106
690106
690106
690106
690106
600
916
690106
690106
690106
690106
690106
690106
690106
690106
690106
690106
690107 4
. 690107
690107 3
690107
690107
690107
690107
690107
690107
690107
69O107
690107
690107
690107
690107
690107
690107
690107
690107
690107
690108 3
690108
690108
690108
690108
690108
690108
690108
690108
690108
690108
38
U
U
U
U
U
W
24
B 00216 W
W
0 0 0 0D
30
38
W
24
B 00216 W
24
B 00216 W
UNCLASSIFIED
W
2A AT865681
1A BT421048
BT421048
BT452039
1A BT421048
1A BT452039
1A VS482526 S
1B VS564638
1A XT545350 S
1B XT553352
1C XT562348
10 XT555350
1E XT563353
1F XT565354
1G XT597325
1H XT566325
11 XT5 13350
U XT543357
1K XT545352
1L XT544363
1M XT537369
1N XT537365
10 XT515376
1P XT526364
2A XT5 12405
2B XT520394
1A YA679817
18 YA643760
1C YA642640
1A VS482526 S
1B VS564638
1A XT545350 S
1B XT553352
1C XT562348
10 XT555350
1E XT563353
1F XT56S354
1G XT597325
1H XT566325
11 XT5 13350
U XT543357
1K XT543352
1L XT544363
1M XT537369
1N XT537365
10 XT515376
1P XT526364
2A XT5 12405
2B XT520394
1A XT545350 S
1B XT553352
1C XT562348
10 XT555350
1E XT563353
1F XT565354
1G XT597325
1H XT566325
11 XT5 13350
U XT543357
IK XT545352
9
G
G
G
G
G
�VJIVWL.J"**.}Oil IL.LS
YYMMOO CT2 PRO
690108
690108
690108
690108
690108
690108
690108
690109 3
600
919
690109
690109
690109
690109
690109
690109
690109
690109
690109
690109
690109
690109
690109
690109
6901O9
690109
690110 3
690110
690110
690110
690110
690110
690110
690110
690110
690110
6901 10
690110
690110
690110
690110
690110
690110
6901 10
690111 3
690111
6901 1 1
6901 1 1
690111
690111
690111
6901 1 1
6901 1 1
690111
6901 1 1
690111
6901 1 1
690111
6901 1 1
6901 1 1
6901 1 1
24
24
24
H
GAL
T
B 00216 W
B 00216 W
B 00216 W
LEG
COORD
S I M
1L XT344363
1M XT537369
1N XT537365
10 XT515376
1P XTS26364
2A XTS 12405
2B XT520394
1A XT5453SO S
1B XT553352
1C XT562348
10 XT555350
1E XT563353
1F XTS653S4
1G XTS97325
1H XT56632S
11 XTS 13330
10 XT543357
1K XT545352
1L XT544363
1M XT537369
1N XTS37365
10 XT515376
1P XT526364
2A XTS 12405
26 XT520394
1A XT5453SO S
16 XT553352
1C XT562348
1D XTS55350
1E XT563353
1F XT56S3S4
1G XTS9732S •
1H XTS66325
11 XTS 13330
10 XT5433S7
1K XT545352
1L XT544363
1M XTS37369
1N XT537365
10 XTS 15376
1P XT526364
2A XTS 12405
2B XT520394
1A XT545350 S
16 XT5S3352
1C XT562348
1D XTS5S350
1E XT563353
1F XT565354
1G XT597325
1H XT566325
11 XTS 13350
10 XT5433S7
1K XT545352
1L XT544363
1M XT537369
1N XTS37365
10 XTS 15376
1P XT326364
2A XTS 12405
G
G
G
YYMMDD CT2 PRO
Page 34
H
GAL
T
690111
690112 1
01
U
P
690114 3
28
U
W
690114
690114
U
690114
U
690114
690114
690114
690114
690114
690115
U
690116 3
24
B 00330 F
690116
U
690117
U
690117
W 00165
690117
690117
690117
690117
(690117
'690117
690117
690117
0 00165
690117
690117
690117
690117
690117
690117
690117
690117
B 00110
690117
690117
690117
690117
690117
690117
690117
690118
B 000D
70
690118
690118
U
690119
U
690120
W 00016
690120
690120
690120
690120
690120
690120
B 000
03
690120
690120
690120
690120
690120
690121 3
23
B 040P
04
690121
690121
U
690121
W 00016
690121
UNCLASSIFIED
LEG
COORD
S I M
2B XTS20394
1A YD706102 S
1A XS66595S S
H
1B XT7 12070
1A BT533094
1A WS845116
16 WSSS1110
2A WS829103
26 WS829110
3A WS832117
36 WS836100
1A BT535039
1A XT280674 S
H
1A BT53S039
1A BT535039
1A WS774065
16 WS768056
1C WS778043
1D WS785046
1E WS784050
1F WS780048
1G WS77S035
1H WS777063
1A WS774065
16 WS768056
1C WS778043
10 W578S046
1E W 7 4 5
S800
1F WS780O48
1G WS77S055
1H WS777063
1A WS774O65
16 WS7680S6
1C WS778O43
10 WS78S046
1E WS7840SO
1F W 7 0 4
S808
1G WS775055
1H WS777O63
1A XD032502 S
F
16 XD080450
1A 8T533094
1A 6T535039
1A WS784026
16 WS783020
1C WS778017
1D WS782013
1E WS788018
.1F WS790026
1A WS784026
16 WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
1A XT636157 S
H
16 XT664165
1A BT535039
1A WS784026
1B WS783020
�UNCLASSIFIED
YYMMDO CTZ PRO
690121
690121
690121
690121
690121
690121
690121
690121
690121
690121
690122 1
690122
690122
690122
690122
690122
690122
690122
690122
690122
690122
690122
690122
690123 1
690123
690123 1
690123
690123
690123
690123
690123
690123
690123
690123
690123
690123
690123
690123
690123
690124
690124
690124
690124
690124
690124
690124
690124
690124
690124
690124
690124
690125
6901 23
690125
690125
690125
690125
690125
690125
690125
H
GAL
T
B 003
03
03
U
P
W 00016
B 003
03
23
U 000 0
70
03
U
P
U
W 00016
B 003
03
W 00016
B 003
03
W 00016
B 003
03
LEG
COORD
S I M
1C WS778017
1D WS782013
1E WS788018
1F WS790020
1A WS784026
16 WS783020
1C WS778017
10 WS782013
1E W5788018
1F WS7S0026
U BT5 11040 S
1A WS784026
1B WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790020
1A WS784026
18 W5783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
U YT066485 S
1B YT9S0360
U BT3 11040 S
1A BT535039
1A WS784Q26
18 WS783020
1C WS778017
10 WS782013
- 1E WS788018
1F WS790026
1A WS784026
1B WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
1A WS784026
1B WS783020
1C WS778017
1D WS782013
1E WS788013
1F W5790026
1A WS784026
1B WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
1A WS784026
WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
1A WS784026
15 WS783020
1C WS778017
F
Page 35
YYMMDD CTZ PRO
690125
690125
690125
690126
690126
690126
690126
690126
690126
690126
690126
690126
690126
690126
690126
690127
690127
690127
690127
690127
690127
690128 1
690128
690128
690128
690128 '
690128
690128
690128
690128
690128
690128
690128
690128
690129
690129
690129
690129
690129
690129
690129
690129
690129
690129
690129
690129
690131
690201 2
690201
600 3
922
600 2
922
600 2
922
600 2
926
690207 2
600 3
928
600
928
600
928
600
928
600
928
600
928
H
T
GAL
W 00016
B 003
03
W 00016
02
0
W 00016
B 003
03
W 00016 .
W OO016
10
26
10
12
12
12
23
UNCLASSIFIED
0 020
02
0 00150 0
U 00150
W
W
W
W
W
W
O0055
00110
000
05
00110
00350
D
0
0
D
W
LEG
COORD
S I M
1D WS782013
1E WS788018
1F WS790026
1A WS784026
1B WS783020
1C WS778017
10 WS782013
1B WS788018
1F WS790026
1A WS784026
18 WS 7 8 3020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
1A WS784026
1B WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
1A YD631430 S
1A WS784026
1B WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
1A WS784026
18 WS783020
1C WS778017
10 WS782013
1E WS788018 .
1F WS790026
1A WS784026
18 WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
1A WS784026
1B WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
1A XT920440
1A C0271326 S
1A C0934864
1A YT200100 S Z
1A C0934864 S
1A CP001848 S
1A BP993846 S
1A BP943766 S
1A XT590335 S
16 XT590328
2A XT590328
2B XT595330
3A XTS95330
36 XT566324
H
G
F
G
G
G
G
G
�VJIMOU/-\O^oint-L/
YYMMDD CTZ PRO
H
GAL
T
LEG
COORD
S I M
YYMMDD CTZ PRO
Page
H
GAL
T
LEG
COORD
36
S I M
a •
690208
690208
600
926
690208
690208
690208
690208
600
928
690208
600
928
690208
690208
690208
690208
600
928
690208
600
929
690209
690209
690209
690209
600
929
690209
600
929
690209
690209
690209
690209
600
929
690209
600
929
690209
690209
600
929
690209
600
929
690209
690209
690210
690210
690210
690210
690210
690210
690210
690210
690210
690210
690210
690210
690210
690210
690210
690211
690211
690211
69O211
690211
6902 1 1
6902 1 1
3
28
W 060 W
06
3
23
W 030W
00
1
3
02
23
B 00160 P
W 030W
00
2
13
W
P
3
23
W 030W
00
4A XT566327
48 XT560350
SA XT560330
58 XT543351
6A XT543351
6B XT5 17384
7A XTS 17384
7B XT52039S
8A XT520395
SB XT514912
9A XTS14412
9B XTS 104 12
10A XT510412
10B XT479436
11A XS574856 S
11B XS624887
1A XT59033S S
1B XT590328
2A XT590328
2B XT595330
3A XTS95330
38 XT566324
4A XT566327
4B XTS6O350
5A XT3603SO
SB XT5433S1
6A XT5433S1
6B XTS 17384
7A XTS 17384
7B XTS2039S
8A XTS2039S
86 XT514912
9A XTS 144 12
9B XTS 104 12
10A XTS 104 12
10B XT479436
11A XT479436
11B XT493450
1A YD878128 S
1A XT590335 S
1B XT590328
2A XT590328
2B XTS9S330
3A XTS95330
3B XT566324
4A XT56S327
4B XTS603SO
SA XT5603SO
SB XTS433S1
6A XT543351
6B XTS 17384
7A XT479436
7B XT493450
1A BN730870 S
1B BN765915
1C BN784888
1A XT590335 S
18 XTS90328
2A XT59032S
2B XT59S330
G
G
G
G
H
G
690211
69021 1
690211
690211
6902 1 1
6902 1 1
690211
6 0 11
92
6902 1 1
690211
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690213
690213
690213
690213
690213
690213
6902 1 3
690213
690213
6902 1 3
690213
690213
690213
690213
690213
690213
690213
690213
690213
690213
.
1
2
02
13
U
0
W
2
3
12
23
W 005 D
05
W 030W
00
3
27
0 000P
20
U
0
W 000D
03
W 030W
00
2
3
12
23
UNCLASSIFIED
P
P
3A XT59S330
3B XTS66324
4A XT566327
4B XT560350
SA XT5603SO
SB XT543351
6A XT543351
6B XTS 17384
7A XTS 17384
1A BTS33094
1A YDS16219
1A BN730870
1B BN765915
1C BN784888
1A CP026226
1A XTS9033S
1B XT590328
2A XTS90328
2B XT595330
3A XT595330
3B XTS66324
4A XTS66327
46 XT560350
SA XT5603SO
SB XT5433S1
6A XT543351
6B XTS 17384
7A XTS 17384
7B XTS20395
8A XT520395
SB XT514912
9A XTS 144 12
98 XTS 104 12
10A XTS10412
1OB XT479436
11A XT479436
11B XT493450
S
S
H
H
S
S
G
G
1A YS7 13941 S
F
1A
1A
1A
1A
1B
2A
2B
3A
36
4A
4B
SA
SB
6A
6B
7A
7B
8A
8B
9A
98
10A
BTS33094
YU80163S
CP001849 S
XT590335 S
XTS90328
XT590328
XT595330
XTS95330
XT566324
XT566327
XT560350
XT560350
XTS433S1
XT5433S1
XTS 17384
XTS 17384
XTS20395
XT520395
XTS14912
XTS14412
XT510412
XTS 104 12
G
G
�UNCLASSIFIED
YYMMDD CTZ PRO
H
GAL
T
LEG
COORD
S I M
YYMMDO CTZ PRO
Page 37
H
GAL
T
LEG
COORD
S I M
m 9
690213
690213
690213
690213 1
690214 2
690214 3
690214
690214
690214
690214
690214
690214
690214
690214
690214
690214
690214
.690214
690214
690214
690214
690214
690214
6902 f4
690214
690214
690214
690214
690214
690214
690214
690214
690214
690214
690214
690215 3
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
02
10
23
U 020 D
00
U
- 0
W 030 W
00
W 020
02
B 005
05
23
W
W 020
02
W
108 XT479436
11A XT479436
118 XT493450
1A Y0490198 S
1A CR094085 S
1A XT590335
18 XT590328
2A XT590328
2B XT595330
3A XT59S330
38 XTS66324
4A XT566327
46 XT560350
5A XT560350
SB XT343351
6A XT543351
68 XT5 17384
7A XT5 17384
78 XT520395
8A XT520395
88 XT514912
9A XT514412
9B XT510412
10A XT5 10412
108 XT479436
11A XT479436
118 XT493450
1A WS707108
18 WS7081O4
1C WS694105
10 WS69S098
1A WS707108
18 WS708104
1C WS694105
10 WS69S098
1A XT590335 S
1B XT590328
2A XT590328
2B XT595330
3A XT595330
38 XT566324
4A XT566327
48 XT560350
5A OCT560350
SB XT543351
6A XT643351
6B XT5 17384
7A XT5 17384
78 XT52039S
8A XT520395
88 XT514912
9A XT514412
98 XT510412
10A XT510412
10B XT479436
11A XT479436
118 XT493450
1A WS707108
18 WS708104
1C WS694105
H
F
G
690215
690215
690215
690215
690215
690216
690216
690216
690216
690216
690216
690216
690216
690217
690217
690217
690217
690217
690217
690217
690217
690218 2
690218
690218
690218
690218
690218
690218
690218 '
690218
690219
690219
690219
690219
690219
690219
690219
690219
690220
602
920
602
920
6 0 2
9 2 0
602
920
602
920
690220
690220
690221 3
69022 1
69022 1
690221
690222 1
690227
690302
690302
690302
690303 2
690303
690303
690303 2
600
933
B 005
05
W 020
02
B 00055
W 020
02
B 005
05
10
U
D
W 020
02
B 005
05
W 00220
B 0 0 5.
05
W 020
02
B 005
05
28
0 020 P
05
03
U
P
U
0 000D
30
06
0 03OOO D
06
0 000D
30
UNCLASSIFIED
10
1A
1B
1C
1D
1A
1B
1C
10
WS695098
WS707108
WS708104
WS694105
WS695098
WS707108
WS708104
WS694105
WS695098
WS707108
WS708104
WS694105
WS695098
WS 707 108
WS708104
W5694105
WS695098
WS707108
WS708104
WS694105
WS695098
1A CR021011 S
WS707108
WS708104
WS694105
WS695098
WS707108
WS7081O4
WS69410S
WS695098
WS707108
WS708104
WS69410S
WS69S098
WS707108
WS708104
1C WS694105
1D WS695098
1A WS707108
IB WS708104
1C WS694105
1D WS695098
1A WS707108
1B WS708104
1C WS694105
10 WS695098
1A XT410160 S
18 XT410180
1C XT420180
10 XT420160
U 8T5 11040 S
1A XT582034
1A YA682730
1B YA647630
1C YA647550
1A YB819450 S
1B YB809410
1C YB8 10290
1A YA678888 S
18 YA630730
F
H
f
F
F
�UNCLASSIFIED
YYMMDD CT2 PRO
690304 1
690304 3
690304 3
690304
690304
690304
690305
600 1
936
600
936
690306
690307 3
690307
690308
690308
600 3
939
600 2
939
600
939
600
939
690310 2
690310
690310
690310 2
690310
690310
690312 3
690312
690312
690312
690312
690312
690312 3
690312
690313 2
690313
690313
690313
690313
690313
690313
690313
690313
690313
690313
690313
690313
690313
690314
690314
690314
690314
690314
690314
690314
690314
690314
690314
690314
690314
690314
690315 3
H
01
23
23
GAL ^
LEG
B 00130 P
W
P
W 00715 F
B 00220
03
U
U
0
U
26
W
P
* U
U
U
26
07
W
U
P
F
U
06
0 000D
30
06
0 000D
30
U
23
W 01045 P
t
23
U
P
U
12
W
D
U
W 00641
W 00641
U
29
0 040P
04
COORD
S I M
1A YD116701 S
H
1A XT650160 S
H
1A XT6S0165 S
H
1B XT665155
1A XT760370
1A 8T533094
1A BT533094
1A YC940563 S R F
1B YC983574
1A BT533094
1A YT080070 S
H
1A BT533094
1A BT533094
1A XT963490
1A YT08O070 S
H
1A BR840040 S
F
1B BR980880
1A YD808162
1A YA698730 S
F
1B YA662635
1C YA662550
1A YA669888 S
F
1B YA620710
1A BT533094
1A XT648137 S
H
18 XT640145
1C XT635155
10 XT650170
1E XT670160
IF XT620177
1A XT639151 S
G
1A BT533094
1A CP001848 S
G
1A 8TS33094
1A XSS87925
18 XS640925
1C XS587900
1D XS596907
1E XS640900
1F XS635907
1G XS603850
1H XS625865
11 XS660865
10 XS605810
1K XS640810
1L XS653835
1A XS587925
16 XS640925
1C XS587900
10 XS596907
1E XS640900
1F XS635907
1G XS603850
1H XS625865
11 XS660865
U XS605810
1K XS640810
1L XS653835
1A BT533094 .
1A XS633996 S
G
YYMMOD CTZ PRO
690315 3
690315
690315
690315
690315
690315
690315
690315
690315
690315
690315
690315
690315
690315
690315
690315 .
690316 3
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690317
690318 3
690318
690318
690319
690319
690320 1
690321 3
690321
690322 3
690322
690322
690323 3
690323
690323
690323
690323
690324 2
690324
690325 3
690325
690326 2
690326 3
28
Page 38
H
GAL
T
W 00275 W
U
U
W 00641
28
0 0 4 0F
04
W 00641
23
U
W 00110 F
23
U
U
B 020
02
U
P
W 00385 P
U
W 00330 F
28
U
W 00165 P
07
W 01000 F
23
0
D
U
B
P
W 01210 W
03
24
07
24
UNCLASSIFIED
LEG
COORO
S I M
1A XS740884 S
1B XS745870
1A BT533094
1A XT582034
1A.XS587925
1B"xS640925
1C XSS87900
1D XS596907
1E XS640900
1F XS635907
1G XS603850
1H XS623865
11 XS660865
10 XS605810
1K XS640810
1L XS65383S
1A XS550940 S
1B XS570940
1C XS570943
1D XS575950
1E XS575960
1F XSS67960
1G XS967955
1H XSS50955
11 XSS50940
1A XS587925
18 XS640925
1C XS587900
1D XS596907
1E XS640900
1F XS635907
1G
603850
1H
625865
11
660865
10
6058 10
1K
640810
1L
653835
1A BT533094
1A XT650170 S
18 XT670160
1A BT533094
1A BTS33094
1A XT760370
1A BT549016 S
1A XT279598 S
1A BT533094
1A XT683156 S
18 XT627168
1A BT533094
1A XT655151 S
18- XT653163
1C XT655150
1D XT657161
1E XT653164
1A BR57045S S
1B BR57Q445
1A XT980020 S Z
1A BT533094
1A CR070190 S
1A XT 105463 S
G
H
H
H
H
G
H
F
H '
H
�UNCLASSIFIED
YYMMDO CTZ PRO
H
GAL
T
LEG
COORD
S I M
YYMMDD CTZ PRO
Page 39
H
GAL
T
LEG
COORD
S 1 M
• •
690326
690327 1
690327
690327
690327
690327
690327
690327 2
690328 2
690328 3
690328
690328 1
690328
690329
690331
690401 1
690401
690401
690402 1
690402
690402
690402
690402
690402
600 1
942
690402
690402
690402
690402
600
942
690402 3
690402
690402
600
943
600
944
6 0 0 4
9 4 7
69O407
690408
600
949
6904 1 1 1
690411
03
07
B
W
07
24
B
P
B
P
W 065 W
00
01
u
03
OS
u
u
u
u
u
u
B
21
0
P
P
U 000D
20
U
U
. U
34
0
U
U
U
0
03
B 01300
690411
02
23
690412 1
690412 3
690412
690414
690415
•
690416
690416
690417 2
690417
690417
690417
690417
690418 3
690418
690418
690418
690418
690418
08
28
0 00165 P
0
U
U
U
U
B 00495
0 020C
05
U
U
8 00495
0 005SO F
U
XT2 15430
AT970570
A T9 7 6 0
00
AT980600
AT983600
BT012560
AT970570
CR060185
CR045220
XT 100500
XT045545
YD895150
BT533094
BT333094
BT533094
S
H
1A
1A
1A
1B
1C
10
1E
1F
1A
1B
1C
10
1E
1F
1A
18
1A
1A
1A
S
S
S
H
H
H
S ZF
BTS33094
BT421048
BS809398 S
BS809374
BS828374
BS828390
BS81439O
BS8 14398
8S809398 S
BS809374
BS828374
6S828390
BS8 14390
8S8 14398
YT020585 S
YT070586
BTS33094
BT533094
BT533094
H
H
f
1A XS6O4247 S C F
1A
1A
1A
1A
1A
1B
1A
1A
1A
1A
1A
1A
1A
1A
1B
1A
1A
1A
1A
16
1C
10
1E
1A
BT533094
BT533094
BT533094
YC90040O
YD323128
YC457998
YD808162
YT050670
BT533094
BTS33094
BT533094
BT533094
XT780380
BR131249
BR13S249
BT533094
XT653153
XT780380
XT516012
XSS22996
XS518990
XS511999
XT516012
BT533094
690418
690419 1
690419
690419 2
69O419
690419
02
B 00330
0 00165 F
06
U 03000 D
6 0 19
9 4
1A BT549016 S
fc
OS
1B
1A
1B
1C
10
1E
1F
1A
1A
1A
1B
1A
1A
1A
1A
S Z F
S
H
S Z F
S
S
H
H
690419
690419
690419
690420
690420
602
940
690420
23
69O421 3
69042 1
690421
69042 1
690421
690421
03
690422 1
690422
69O422
690422
690422
69O422
690423 3
23
690423
690423 1 . 05
690423
690423
690423
690423
690423
690423
690423
690423
690424 1
03
6 O 2 1
9 4 4
05
6 0 2
9 4 4
6 0 2
9 4 4
6 0 2
9 4 4
6 0 2
9 4 4
69O424
69O424
6 0 2
9 4 4
6 0 2
9 4 4
6 0 2
9 4 4
6 0 2
9 4 4
69O425 3
690425
690425
69O425
690425 1
690425
690425
690423
690425
690425
690425
U
W
W
W
B
W
W
W
W
U
W
U
W
W
B
U
U
W
W
W
B
U
00 165
00327
00348
00330
000 0
20
0
E
OO16S
00327
00348
OO165
00348
00165
00327
0003 S
D
00348 •
00327
00165
00163
1A XT780380
H
1A YD62009S S
1B YDS50035
r
1A YB911780 S
1B YB388620
1A BT533094
1A BR465467
1A BR465467
1A BR465467
1A XT780380
U BR465467
1A BR465467
1A BR465467
1A XT905038
3
1A XT674378 S
1A BR465467
1A BT533094
1A BR465467
1A BR46S467
1A XT7S0380
1A BT480230 S R F
1A BR533094
1A BR465467
1A BR465467
1A SR465467
•
1A XT780380
F
1A YTO 17580 S
18 YT017480
H
1A BS914239 S
H
18 BS917239 S
H
1C BS914246 S
10 BS916256 S
H
H
1£ BS9 12259 S
H
1F BS901259 S
1A BR465467
W 00165
W OO327
W 00348
0
0
E
1A BS914239 S
0 00150
1B
1C
10
1E
1F
U
1A BR465467
1A BR465467
1A BT040540 S Z F
BS917239
BS914246
BS9162S9
BS912259
BS901259
XT49O480
S
S
S
S
S
H
H
H
H
H
H
1B XT490493
23
W 00327
0 00038 P
05
0
UNCLASSIFIED
W 00327
E
1C
10
1A
1A
18
1C
10
1A
18
1C
1D
1E
1F
XT500490
XTS00475
BR465467
XT490480 S
XT490493
XT500490
XT500475
BS914239 S
BS917239
BS914246
BS916256
BS9 122S9
BS901259
1A BR463467
G
H
�UNCLASSIFIED
YYMMDD CTZ PRO
H
GAL
T
LEG
COORD
S I M
YYMMDD CTZ PRO
Page 40
H
GAL
T
LEG COORD
S I M
•
690425
690426 3
690426
602
946
690426
690426 1
690426
690426 1
690426
690426
690426
690426
690426
690426
602
946
690427 3
602
947
690427
602
947
690427
69042S 3
690428
690428
690429 3
690429
690429
690430
690502 3
690502
600
952
690502
600 1
955
690505
600
955
690505
690505
690505
690505 1
690505
690505
690505
690505
690505
6905O5
690505
690507 3
600
957
690507
600
957
690507
600
957
690507 3
690507
690507
690508
690510 2
690510
690510
690511 1
6905 1 1
23
W 00390
0 008 P
03
02
8
D
05
0
£
23
W 00327
W 01200
0 006 P
03
.
29
29
24
05
W 00327
W 00175 D
W 00327
W 060
00
W'00 D
030
B 040
00
W 00327
U
0 050P
05
B
P
*
05
0
P
U
24
0 00550 P
24
0 00530 W
08
B
U
05
U
B
P
P
1A BR465467
1A XT490480 S
G
1B XT490493
1C XT500490
10 XT500475
1A AT958930 S
F
18 AT957891
1A BS914239 5
H
1B BS917239
1C 8S914246
10 BS916259
H
1E BS912'2S9 S
1F BS901259 S
1A BR465467
1A BR465467
1A XT4 9 4 0 S
08
G
1B XT490493
1C XT500490
1D XT500475
1A BR465467
1A XT9 10030 S
G
1A BR465467
1A BR465467
1A XT9 10020 S . G
1A BR465467
1A BR465467
1A XT776066
1A XT270615 S
G
1B XT27661S
2A XT276615
28 XT287640
1A BS809398 S
H
1B BS809374
1C BS828374
1D 8S828390
1E BS8 14390
1F 8S8 14398
1A BSS09398 S
H
1B BS8O9374
1C BS828374
10 BS828390
1E BS8 14390
1F 858 14398
18 XT8 13077
1A BT555035
1A XT253373 S
H
1B XT253340
2A XT253340
26 XT347330
3A XT350296
38 XT373263
1A XT270615 S
G
18 XT276615
1C XT28764Q
1A YD872150
1A YA936931 5
H
16 ZA030930
1A BT533094
1A BS809398 S
H
1B BS809374
6905 1 1
690511
690511
690511
690511 1
690511
690511
69051 1
690511
690511
690512
690512
690512
690512
690512
690512
690513
690514
690514
690514
690515 3
690515
690515
690515
690515
690516
690516
690516
690517
690519 3
690519
690519
690519
690519
690519
690519
690519
690519
690519
690519
690520 1
690521 3
690521
690521
6 0 21
95
690522
690523
690524
690525
690525
690526 2
690526
690526
690526
690527
690528 3
690528
602
958
690528
602
958
05
0
P
U
0 030
00
U
U
U
U
0 020
02
0 020
00
28
0 00150
0 00220 D
0 020
00
U
W 020
02
24
0 000
05
0 01400 5
02
23
U
B 00055 P
0 000D
40
U
U
U
U
U
07
0 005
05
0
F
29
U
8 00220 D
UNCLASSIFIED
W 00110
1C BS828374
10 BS828390
1E BS8 14390
IF BS814398
1A BSS09398 S
18 BS309374
1C BS828374
10 BS828390
1E BS814390
1F BS814398
1A BT533094
1A XT905058
1A XT629663
. 1A XT962497
1A XT481715
1A XT538806
1A XT905058
«
H
1A XT488390
18 XT463400
1A XT905058
1A XT508003 S
1B XT508014
1C XT513018
10 XT5 11009
1A XT905058
1A 8T533094
1A YA960964
18 ZA008964
1A XT905058
1A XT420390 S
18 XT458390 S
1C XT464400 S
10 XT482410 S
1E XT484418 S
1F XT498385 S
1G XTS38344 S
1H XT520345 S
11 XT5 10327 S
10 XT492317 S
1A 8T533094
1A Y0808162 S
1A XT679771 S
18 XT101712
1C XT197891
1A BT533094
1A BT533094
1A BT534036
1A BT533094
1A BT533094
1A YA427525
1ft BR340040 S
18 BR800970
1C BR850050
1D BR860970
1A BT533094
1A XS960870 S
18 XS970900
1A WS307138
18 WS805135
2A WS319130
H
H
H
F
*
F
H
�UNCLASSIFIED
YYMMDD CT2 PRO
H
GAL
T
LEG
COORD
S I M
YYMMDD CT2 PRO
Page 41
H
GAL
T
* •
•
690528
690529 1
690529
690529
690529
690S30
690531
690602 1
690602 3
690602
690602
690602
690602
690602
690602
690602
690602
690602
690602
690602
690603
600
964
600
964
690605 1
600
965
690605
690605
690605
690605
600 1
966
600
966
690607 1
690607
600 1
968
690608 2
690608
690608
69O610
690610
690610
690610
690611 3
6906 1 1
690612 3
690613
690613
690613
690613
690613
690613
69O613
690613
69O615 3
690615
690615 3
690615
690615 3
690615
690615
690615
U
U
05
U
02
26
U
U
U
0 004P
07
U 000D
20
0
8
0
B
U
U
00073
00018
00073
00018
U
U
0 00110
0 0000
30
U
01
W
U
01
W
P
U
W
P
0 000D
30
01
11
H
H
F
1A XT914584
U
05
2B WS817126
1A BS538824 S
1A XT527588
1A BR929756
1A XT481715
1A BT534036
1A BT533094
1A Y0405036 S
1A YT020S85 S
18 YT0705S6
1A YA427525
1A YA427525
1A YD355072
1A YD355072
1A BT533094
P
1B
1C
1A
18
1A
1A
1A
1A
18
1C
2A
2B
1A
1A
1A
1A
1A
1A
1A
YT020585
YT070586
YT020585
YT070586
BT533094
BT533094
YA427525
BS636300
BS684300
BS746507
BS675532
BS672400
BT533094
YD335480
BT533094
Y033S480
BT533094
YD335480
ZV203Q55
S
F
S
H
S
H
S
S
H
F
18 ZV174148
26
26
U
U
U
U
0
P
U
0
P
W 00520
W 00355
29
0 00120 D
29
B 000D
05
24
U
P
1C
1A
1A
1A
1A
1A
1A
1A
1A
18
2A
2B
1A
18
2A
2B
1A
1B
1A
18
1A
18
1C
1D
ZV098222
XT9SS490
XT483553
YT678256
BT533094
YT051111
8T533094
YT051111
WR859890
WR856885
WR860886
WR864886
WR865914
WR956885
WR880980
WR86S918
XT773065
XT779065
XT773065
XT779065
XT764380
XT770379
XT770380
XT773372
S
H
S
H
S
G
S
G
S
G
690615
690615
690615
690615
690616 3
690616
690616
690616
690616 3
690616
690616
690616 3
690616
690616
690616
690616
690616
690616
690616
690617 1
690617
690617
690617
690617 3
690618 3
690618
690618
690618
690618
690618
690618
690618
690618 3
690618
690618
690618
690618
690618
69O618
690620 3
690621 1
690621 3
690621
690621
69O621
690621 3
69062 1
69062 1
690621
69062 1
690621 1
690621
690621 1
690621
69062 1
690621
69062 1
690621
690621
690621
1E XT777372
1F XT779384
23
U
U
1G XT783388
1H XT784379
1A XT774066 S
G
1B XT774067
24
U
D
24
U
P
02
24
24
0
0
0
0
U
U
004P
08
OOO84 P
004P
08
004P
08
P
P
24
0 00550 P
0 00550
24
O1
24
0 01100 D
W
P
0 00330 0
1C XT776067
10 XT774066
1A XT430870 S
1B XT41080O
1C XT330750
1A XT764380 S
1B XT770379
1C XT770380
1D XT773372
1E XT777372
1F XT779384
1G XT783388
1H XT784379
1A YD542030 S
1A YA42752S S
1A YD355072 S
1A YD535020 S
1A XT370630 S
1A XT764380 S
1B XT770379
1C XT770380
10 XT773372
1E XJ777372
1F XT779384
1G XT783388
1H XT784379
1A XT 150506 S
1B XT150510.
1C XT158513
10 XT165515
1E XT 142523
1A XT630120
18 XT660130
1A XT6 10290 S
1A YD335480 S
1A XT055595 S
18 XT08S598
F
G
H
H
H
H
G
H
H
H
1C XT086595
28
0 OO465 P
02
0 00213 P
0 00212
0 000 0
30
03
UNCLASSIFIED
10
1A
18
1C
10
1E
1A
1A
XT055592
XT653163 S
XT653164
XT655150
XT655151
XT657161
YD355072 S
YS225804
1A BT728168 S
18
1C
2A
28
2C
3A
38
BT760168
BT792153
BT727166
BT760166
8T788152
BT726163
8T766163
H
H
H
F
�UNCLASSIFIED
YYMMOD CTZ PRO
H
GAL
YYMMDD CTZ PRO
T
Page 42
H
GAL
T
a •
690621
690622 1
690622
690622
690622
690622
690622
690622
690622
690622
690622
690622
690622
690622
690622
690622
690622
690623 3
690623
69O623
69O623
690623
690623
690623
690623
690623
690623
690623
690623
690623
690623
€90623
690623
690623
690623
690623
690624 3
690624
690624
690624
602 1
964
690624 1
69O624
690624
690624
690624
690624
690624
690624
690624
690624
690624
690624
690624
690624
69062S 3
690625
690625
690625
690625
02
0
0
0
0
W
00110 P
00110 P
00110 P
00110 P
000
04
W 000
02
W 005
02
23
0 00330 P
W 000
04
W 000
02
W 005
02
23
03
03
U
U
0 00330 P
U
0
U
W 000
04
W 000
02
W 005
02
24
U
P
3C BT7851S2
1A YD355072 S
1A YD620095
1A Y0435010
1A YS225804
1A WS7 17039
1B WS 7 6 3
000
2A WS7 11025
2B WS720036
1A WS765036
1B WS775036
2 A WS 7 6 3
600
28 WS775030
1A WS866013
1B WS874010
2A WSS65005
2B WSS73O03
1A XT490470 S
1B XT490480
1C XT491473
10 XT492472
1E XT495473
1F XT495479
1G XT496477
1A WS717039
1B WS706030
. 2 A WS711025
26 WS72O036
1A WS765036
1B WS775036
2A WS76603Q
2B WS775030
1A WS866013
18 WS874010
2A WSS65005
2B WS873003
1A XT774066 S
1B XT774067
1C XT776067
10 XT774066
1A BT549014 S
1A AT865681 S
1A BT421048
1A WS7 17039
1B WS706030
2A WS7 11025
2B WS720036
1A WS76S036
1B WS775036
2A WS766030
2B WS775030
1A WS866013
18 WS874010
2A WS865005
2B WS873003
1A XT764380 S
1B XT770379
1C XT770380
10 XT773372
1E XT777372
H
H
H
H
H
G
H
G
G
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625 '
690625
690625
690625
690625
690625
690626 3
23
690626
602
966
690626
690626
690626
690626
690626
690626
602
966
690626
602
966
602
966
690626
602
966
602
966
602
966
69O627 1
02
690627 2
07
690627
690627
602
967
690627
690627
69O627 •
690627
690627
690627
690627
690627
690627
690627
690627
690627
69O627
690628 2
07
690628
690628
690628
690628
690628
602
968
690628
UNCLASSIFIED
W 00025
W 000
04
W 000
02
0 030
00
U
U
U
W 005
02
W 000
04
W 000
02
0
U
B
W
030
00
00110 P
00250 >
008
09
0 00110
W 005
02
W 000
04
W 000
02
0
W 008
09
W 005
02
F
1F XT7793S4
1G XT783388
1H XT784379
1A WS866013
1B WS874010
2A WS865005
2B WS873003
1A WS717039
1B WS706030
2A WS7 11025
2B W5720036
1A WS765036
1B WS775036
2A WS766030
2B WS775030
1A XT895065
1A XT387624
1A XT774066 S
1B XT774067
1C XT776067
10 XT774066
1A WS866013
1B WS874010
2A WS865005
2B WS873003
1A WS7 17039
1B WS706030
2A WS711025
2B WS720036
1A WS765036
1B WS775036
2A WS766030
2B WS775030
1A XT905058
1A YD797109 S
1A BR034535 S
1A WS8 10054
1B WS8 13000
1A XT615227
1B XT598263
1A WS866013
1B WS874010
2A WS865005
2B WS873003
1A WS7 17039
1B WS 7 6 3
000
2A WS7 11025
2B WS720036
1A WS765036
1B WS775036
2A WS766030
2B WS775030
1A CR820040 S
1B CR850950
1A WS8 10054
1B WS8 13000
1A WS866013
1B WS874010
2A WSS65005
2B WS873003
G
G
H
F
�UNCLASSIFIED
YYMMOD CTZ PRO
690628
690628
602
968
690628
690628
69O628
690628
690628
602
968
690628
690628
690628
690629
602
969
690629
602
969
690629
69O629
690629
690629
690629
690629
690629
690629
690629
602
969
602
969
602
969
602
969
602
969
602
969
602
969
602
969
602
969
602
969
690629
690629
603 3
960
603
960
603
960
603
960
603
960
603
960
603
960
690630
690630
603
960
690630
603
960
603
960
603
960
690630
603
960
690701
690701
690701
690701
690701
600
971
690701
H
GAL
T
W 000
0^
W 000
02
W 00130
W 008
09
0 01000
W 005
02
W 000
02
24
W
P
W 008
09
W 005
02
W 000
04
W OO020
0 010
00
W OO040
W 000
02
LEG
COORD
S I M
1A WS7 17039
1B WS706030
2A WS7 11025
28 WS720036
1A WS76B036
1B WS775036
2A WS766030
2B WS775030
1A WS730086
1B WS730083
2A WS741088
28 WS730083
1A WS8100S4
1B WSB130OO
1A XT592280
1B XT605300
1C XT636307
10 XT636305
1E XT60S296
1F XT59S280
1G XT623283
1H XT638268
11 XT6S0269
10 XT650253
1K XT6382S4
1A WS866013
1B WS874010
2A WS865O05
2B WS873003 '
1A WS7 17039
1B WS706030
2A WS7 11025
2B WS720036
1A WS765036
1B WS775036
2A WS766030
2B WS77S030
1A XT388627 S
G
1A WS8 10054
1B WS8 13000
1A WS866013
1B WS874010
2A WS86500S
2B WS873003
1A WS7 17039
16 WS7O6030
2A WS7 11025
2B WS720036
1A WS765036
16 WS775036
2A WS766030
2B WS775030
1A XT9050S8
1A WS7 17039
18 WS706030
2A WS7 11025
28 WS720036
1A WS765036
18 WS775036
2A WS766030
YYMMDO CTZ PRO
690701
690701
690701
690701
690701
600 1
972
600 1
972
690702 3
600 2
972
690702
690702 2
600
972
690702
690703 1
690703
690703 3
690703 3
690703
690703
690703
690704 3
600 3
975
600
975
600
975
690705
600
975
600
975
600
973
600
975
600
975
600 1
976
600
976
600
976
600
976
600 1
976
600
976
690707 1
600
977
600
977
600
977
600 1
977
600
977
600
977
600
977
600
977
600
977
600
977
600
977
600
977
600
977
600 1
978
600
978
600
978
690708
600 3
978
600 1
978
600 1
979
600
979
600
979
600
979
Page 43
H
T
GAL
W 005
02
02
02
24
07
0 04S P
06
0 00165 P
W
P
0 020D
20
11
0 02575 D
02
24
26
W
0
0
W
U
030
00
00110 P
00110 P
00110 P
000D
40
,
24
24
W
U
P
P
0 01150
03
.03
U
0
U
D
U
03
U
03
0
U
0 080
00
03
U
24
03
03
U 005 P
05
U
0
U
0
UNCLASSIFIED
D
LEG
COORD
S I M
2B WS775030
1A WS866013
1B WS874010
2A WS865005
28 WS373003
1A YD324258 S
1A YD355072 S
1A XT388627 S
1A BR810135 S
1B BR793050
1A BP079619 S
18 AP890648
1A XT770380
1A YD405036 S
1A Y0355072
1A XT388627 S
1A YT070256 S
18 YT984304
1C YT070258
1D XT985308
1A XT38S627 S
1A XT490470 S
1B XT490480
' 1C XT491473
10 XT492472
1E XT495473
1F XT495479
1G XT496477
1A XT 118684
1B XT093780
1A BT 5 7 3 S
006
18 BT5 14505
1C BT515051
2A BT545064
1A "BT549016 S
1A 8S601920
1A BT507036 S
18 BT5 14505
1C BT515051
2A BT545064
1A BT549016 S
1A XT640210
18 XT640227
1C XT654228
1D XT665240
1E XT696210
2A XT680178
28 XT693185
2C XT688176
20 XT 80173
1A BT507036 S
18 BT5 14505
1C BT515051
2A BT545064
1A XT388627 S
1A BT549016 S
1A BT507036 S
18 BT5 14505
1C BT515051
2A BT545064
H
H
G
F
r
H
H
G
F
G
H
H
H
H
H
G
G
H
�UNCLASSIFIED
YYMMDD CT2 PRO
690709 3
690709
690709
690709
690709
690709
690709
690709
690709
690709
600
979
690710 3
690710
690710
690710 2
690710
690710 3
690712
690712
6907 1 2
690712
690712
690714
690714
690714
690714
690717 2
690717
690717
€90718 3
690718
690718
690718
690718
690718
690718 2
690718
690718
690718
690719 2
690719
690719
690721 3
690721
690721
690721
690721
690721
690721
690722 3
690724 2
690724
690724
690729 1
690729 2
690730 1
690730 2
690731 3
690731
690731
24
H
GAL
T
P
U
LEG
1A
18
1C
10
1E
1F
1G
1A
1B
1C
10
0 01SOO
24
0 00330 P
11
U
24
W 00220 P
0 OO600
07
23
U
U
U
U
U
D
0 01000 P
07
U
D
07
B 060
06
U
D
24
U
P
COORD
S I M
XT490470 S
XT490480
XT491473
XT492472
XT495473
XT49S479
XT496477
XT1 10040
XT 130040
XT1 10030
XT 130050
H
1A XT048665 S
H
2A XT05S635
3A XTO9363S
1A ZV180110 S Z F
16 ZV173133
1A XT388627 S
G
1A XT640176
18 XT6S617S
1C XT6841S6
10 XT6831S3
1E XT640168
1A XT9589O8
1A YU036067
1A XU905022
1A XT9S5490
1A BS920207 S
H
18 BS919202
1C 8S9 16208
1A XT660168 S
G
16 XT660167
1C XT665160
10 XT663150
1E XT6S0140
1F XT646140
1A BS920207 S
H
1B BS919202
1C BS9162O8
1A BR264470
1A 8S920207 S
1B BS9 19202
1C BS9 16208
H
1A XT49O470 S
H
1B XT490480
1C XT491473
23
07
W 030P
00
U
D
03
08
03
08
24
U
U
U
U
0 0049S
D
D
D
D
P
10 XT492472
1E XT49S473
1F XT495479
16 XT496477
1A XT770380
1A BS920207
1B BS919202
1C BS9 16208
1A BTS 10040
1A ZA230530
1A BTS 10040
1A ZA230S30
1A XT273682
2A XT056593
3A XTS03377
S
S
G
H
S
S
S
S
S
H
H
H
Page 44
YYMMDD CTZ PRO
690731 1
69073 1 3
690731 3
690731 2
690801 1
690801
690801
690801
690801 3
690801 3
690801
690801
690801
600
981
690801
690801
690801
690801
690801
690801
690801
690801
690801
690801
690801
690801
690801 2
690802 1
690802 3
600
982
690802 3
690802
690802
690802
690803 4
690803
690803
690803 4
69O803
690803 4
69O803
690803
600
983
600 4
984
690804
600
984
690804 4
600
984
690804 4
600
984
600 4
984
690804
690804 4
600
984
690804
690804
600 3
984
690805 4
€90805
€90805
H
T
GAL
03
24
24
08
03
U
D
0 00200 P
0 00200 P
U
D
U
0
24
26
0 00110 P
0 01700 P
08
03
28
U
0
U
D
B 00295 W
22
0 00295 W
40
U
40
U 00055 F
40
U
F
4O
U
F
40
U 005 F
05
40
U 00055 F
F
40
U 00055 F
40
U
29
U
P
40
U
F
UNCLASSIFIED
F
LEG
COORD
S
I M
1A BTS 10040 S
1A XT056593 S
1A XT273682 S
1A ZA230530 S
1A BT507036 S
1B BT51450S
1C BTS 15051
2A BT545064
1A XT273682 S
1A YT007123 S
1B YT 142002
1C VT150010
1D YT 1540 15
1E YT155015
1F YT 160005
1G YT160010
1H YT161006
11 YT162998
2A YT 165000
2B YT 165004
2C YT 165005
2D YT 166002
2E YT 167007
3A YS145982
3B YS 167994
3C YS3 18667
1A ZA230530 S
1A BT507036 S
1A XS623887 S
1B XS576857
1A XS564851 S
1B XS5818S6
1C XS608876
10 XS624860
1A WS791080 S
1B WS8000SO
1C WS791084
1A WS820075 S
18 WS827073
1A WS793077 S
1B WS798073
1C WS802080
10 WS801084
1A WS791080 S
1B WS800080
1C WS791084
1A WS700030 S
1B WS7 12032
H
H
H
1A WS7 12024 S
1B WS7 14033
1A WS820075
16 WS827073
1A WS793077
1B WS798073
1C WS802080
10 WS801084
1A XS752937
1A WS7910SO
1B WS800080
1C WS791084
H
H
H
H
H
H
G
G
G
G
G
G
S
G
S
G
S
S
G
G
�UNCLASSIFIED
YYMMDD CTZ PRO
H
GAL
T
LEG
COORD
S I M
a
690805 4
690805
690805 4
690805
690805 4
690805
690805
690805
690805 1
690305
690805
690805
600 3
985
690805 1
690806 4
690806
600 4
986
690806
6908O6
690806
690807 1
690807
600
987
690807
690807 3
600
987
600 1
987
600 3
988
600
988
690808
600
988
690808 1
600
988
690808
690808
690808 3
690808
690808 3
600 1
988
690808 3
600 1
989
690810 2
690810
690810
690810
690810
690810 2
690810
690810
690811 1
690812 1
690812
690812
690812
690812 1
690813 1
690813
690813
690813
690813 1
40
U 00055 F
40
U 00055 F
40
U
03
U
F
D
28
02
40
0 0 0 0P
02
W 000P
04
U 005 F
05
40
U
03
U
F
P
22
0 00385 P
02
23
W 000P
06
0 00350 P
03
U
P
28
0 00320 W
23
02
24
02
11
0 000P
02
W 000P
06
11
01
03
02
03
02
U
P
W 00100 P
0 000D
20
0 01600 D
W OOO60 P
U
P
W 000P
02
U
P
W 00140 P
1A WS700030 S
1B WS712032
1A WS7 12024 S
16 WS7 14033
1A WS793077 S
18 WS798073
1C WS802080
1D WS801084
1A BT5Q7036 S
1B BTS 14505
1C BT513051
2A BT545064
1A XS808028 S
1A YC433967 S
1A WS700030 S
18 WS7 12032
1A WS793077 S
18 WS798073
1C WS802080
1D WS801084
1A BT507036 S
18 BT514505
1C BTS 15051
2A BT545064
1A XT640164 S
18 XT650167
1A YC433967 S
1A XT653155 S
18 XT645165
1C XT645162
10 XT637154
1A BT507036 S
18 BTS 14505
1C BT5150S1
2A BT54S064
1A XS623887 S
18 XS660928
1A XT857164 S
1A YC433967 S
1A XT482715 S
1A YC433967 S
1A BP635260 S
18 BP573230
2A BP600254
2B BP58220O
2C BP575240
1A ZU078720 S
1B ZU088819
1C ZU067832
1A YC433967 S
1A BT507036 S
18 BTS 14505
1C BTS 15051
2A BT545064
1A YC433967 S
1A BTS07036 S
18 BTS 14505
1C BTS 15051
2A BTS45064
1A YC433967 S
YYMMDD CTZ PRO
Page 45
H
GAL
T
LEG
COORD
S I M
• c
ai
G
G
G
H
G
H
G
G
H
G
H
G
H
H
G
H
G
H
F
H
H
H
H
H
690815 1
690815
690815
6908 1 5
690815 3
690815
690815
690816 1
690816
690816
690816
690817 3
690817
690817 3
690817
690817 1
690817
690817
690818 1
690818
690818
690818
690818 1
690818
690818
690820
690821 3
690821
690822 1
690822
690823 1
690823
690825 4
690825
690825 3
690825
690825
690825
690825 3
690825 1
690825
690826 4
690826
690826 3
690826 1
690827 4
690827
690828 1
690829 1
690829
690829
690829
690830 1
690830
690830
690830
690830 1
690830
690831 4
690831
P
03
U
27
0 060D
00
03
W 00220
P
U
21
U
.
C
21
U
c
03
U 000 D
60
03
U
03
U 000 D
40
P
U
0 005 P
05
.0004
00
02
W OO180 P
U
02
W 00140 P
23
U
40
U 000 F
05
24
0 00220 .0
23
03
0 00010 P
U 000 D
30
40
U 000 F
05
23
02
40
0 000P
03
U
D
U 000 F
05
02
03
W OOO80 P
P
U
03
U
02
W 000 P
02
40
U OO045 F
UNCLASSIFIED
P
1A BT507036 S
1B 8T514505
1C BT515051
2A BT545064
1A YS248824 S
1B YS266834
1A YD878128
1A BT507036 S
18 BTS 14505
1C 8TS1S051
2A BT545064
1A YU241070 S
1B YU233066
1A YU270090 S
1B YU278086
1A ZC060930 S
1B ZC060860
1C ZC1 10848
1A BT507036 S
18 BT514505
1C BTS 15051
2A BT545064
1A ZC053927 S
18 ZC053867
•1C ZC1 10852
1A XT955490
1A XT660160 S
1A XT056593
1A YD535020 S
1A XT16S315
1A YD535020 S
1A XT925442
1A WS716131 S
18 WS713124
1A XTO92546 S
1B XT093627
1C XT176697
1D XT493333
1A XT857164 S
1A ZC 1 55224 S
18 ZC213162
1A WS716131 S
18 WS713124
1A XT857164 S
1A YD706102 S
1A WS716131 S
• 18 WS713124
1A YC685925 S
1A BT507036 S
18 BT514505
1C BT515051
2A BT545064
1A BT507036 S
18 BTS14505
1C BT515051
2A BT545064
1A YC685925 S
2A YC7S7854 S
1A WS699075 S
18 WS705074
H
H
H
H
F
H
F
H
H
H
G
H
G
F
G
G
H
G
H
H
H
H
H
G
�UNCLASSIFIED
YYMMDD CT2 PRO
H
GAL
T
LEG
COORD
S I M
YYMMDO CTZ PRO
Page 46
H
GAL
T
LEG
COORD
S I
m •
690831 1
69083 1
690831
690831
690901 4
690901
690901 4
€90901
690901 3
690902 4
690902
690902 1
690902
690902
690902
690902 3
690903 4
690903
69O903 1
690903
690904 4
600
994
600 1
994
600
994
600
994
690904
690904
600
994
690905
690905
690905
600
999
600 1
996
600
996
600
996
690906
690906
600
996
600
996
600
996
600
996
600
996
690906
600
996
600
996
600
996
600
997
600
997
600
997
690907
690907
600 3
998
690910 3
690912 1
690912
690912
690912
690913 1
690913
69O913
03
U
P
40
U 00045 F
40
U
F
23
40
0
U
P
F
03
U
P
25
40
U
U
C
F
03
U
P
40
U
F
03
U
P
0
U
U
03
U
'
P
P
U
U
U
24
25
03
03
0 00055 P
U
C
U
P
U
P
1A BT507036 S
1B BT5 14505
1C BT5 15051
2A BT545064
1A WS699075 S
1B WS705074
1A WS694049 S
1B WS708046
1A XT615226 S
1A WS694049 S
1B WS708046
1A BT507036 S
1B BT5 14505
1C BT5 15051
2A BT545064
1A XT863S92 S
1A WS694049 S
1B WS708046
1A BT507036 S
1B BSS659S7
1A WS694049 S
16 WS708046
1A BT507036 S
1B BT5 14505
1C BT515051
2A BT545064
1A XT 160450
1A XT955490
1A BT507036 S
16 BT5 14505
1C BT5 15051
2A BT345064
1A BT507036 S
1B BTS14S05
1C BT5 15051
2A BT545064
1A TF830650
1B UH022660
2A TF840610
2B TF830650
1A UF300820
1B UF350830
2A UF340790
2B UF 240770
3A UF240800
3B UF300820
1A TF730610
1B TF8O0620
2A TF800635
2B TF725640
3A TF730610
1A XT273682 S
1A XT863593 S
1A BT507036 S
18 BT5 14505
1C BT5 15051
2A BT545064
1A BT507036 S
1B BT5 14505
1C BT515051
H
G
G
H
G
H
H
G
H
G
H
H
H
H
H
H
H
690913
690915 1
690915
690915
690915
690919 3
690919 3
690920 4
690920
690921 4
690921
690921 4
690921
690921 3
690921
690921
€9092 1
69092 1
69092 1
690922 4
690922
690922 4
690922
690923 4
690923
690923 3
690923
690923
690923
690923 3
690923
690924
690924
690925 1
690926 3
690927 4
690927
690928
690928
690930 3
690930
690930
690930
690930 3
690930
690930
690930
690930 3
690930
690930
690930
690930
690930
690930
690930
690930
690930
691001 3
691001
691001
03
U
P
24
26
40
0 00150 F
U
P
U 000F
04
40
U 000F
04
40
U 000F
04
47
U 00160 D
U
U
40
U 00160
U 000F
04
40
U 000F
04
40
U 000F
04
24
0 00100 W
24
U 00110 P
B 00110
U
03
25
40
U
P
B 00220 P
U 000F
04
21
U 020
02
U 00110
U 00025 C
21
U 000C
03
21
U 00055 C
2A BT545064
1A BT507036 S
1B BT5 14505
1C BT515051
2A BT345064
1A XT373682 S
1A YT069120 S
1A WS605100 S
18 WS590066
1A WS605100 S
1B WS590066
1A WR556993 S
16 WS556004
1A XT967449 S
1A XT098763
1B XT098550
1A XT098763
1A XT098558
1B XT967490
1A WS605100 S
1B WS590066
1A WR556993 S
18 WS556004
1A WR556993 'S
1B WS556004
1A XT508260 S
1B XT545245
1C XT5 16224
10 XT511210
1A XT482715 S
1A XT387624
1A XT098763
1B XT098558
1A BT529088 S
1A XT963449 S
1A WR734937 S
1B WR773956
1A XT955490
1A AT945405
1A YU236187 S
1B YU235188
1C YU243193
10 YU243190
1A YU264107 S
1B YU267108
1C YU274097
1D YU268094
1A YU254168 S
1B YU260169
1C YU269167
1D- YU364167
1E YU264160
1F YU272140
H
H
G
G
G
G
H
G
G
G
H
H
H
*H
G
H
H
H
1G YU260144
1H YU267143
24
UNCLASSIFIED
B 00220
U
P
11
1A
1A
1B
1C
YU254168
XT955490
XT764380 S
XT770379
XT770380
H
�vsi WL.mw 1*711
YYMMOD CTZ PRO
691001
691001
691001
691001
691001
691002 3
691002
691002
691002
691002
691002
691002
691002
691003 3
691003
691003
691003
691003 3
691003
691003
691003
691003 3
691003
691003
691003
691003 3
691003
691003
691003
691003 3
691003
691003
691003
691003 3
691003
691003
691003
691003
691003
691003
691003
691003
691003
691003
691003
691003
691003
691004 3
691004 3
691004 3
691004 3
691004 3
691006 3
691006
691006
691006
691006
691006
691006
691006
24
H
GAL
U
T
P
21
0 000C
02
21
0 000 C
02
21
21
21
24
0 000C
02
0 003 C
02
0 005 C
02
U
P
U
U 00110
U
U
21
21
21
21
21
24
B
B
8
B
S
U
005
02
OOO25
000
02
000
02
000
02
C
C
C
C
C
P
LEG
COORD
S I M
10 XT773372
1E XT777373
1F XT779384
1G XT783388
1H XT784379
1A XT764380 S
18 XT770379
1C XT770380
10 XT773372
1E XT777372
1F XT779384
1G XT783388
1H XT784379
1A YT2S7979 S
1B YT258981
1C YT277985
10 YT25S984
1A YT253987 S
1B YT254986
1C YT2S6988
1D YT248988
1A YT249989 S
1B YT2S0988
1C YT2S4989
10 YT25299O
1A YT245987 S
16 YT250988
1C YT2S4989
10 YT250990
1A YT245987 S
18 YT247988
1C YT246990
10 YT244990
1A XT764380 S
18 XT770379
1C XT770380
1D XT773372
1E XT777372
1F XT779384
1G XT783388
1H XT784379
1A XT90SOS8
1A YU 1 0 7
400
1A XT098763
18 XT098550
1A XT098763
1B XT098558
1A YT020970 S
1A YT040960 S
1A YT050980 S
1A YT060000 S
1A XT050950 S
1A XT764380 S
18 XT770379
1C XT770380
10 XT773372
1E XT777372
1F XT779384
1G XT783388
1H XT784379
H
H
H
H
H
H
H
H
H
H
H
H
H
/
IL.li.
YYMMDD CTZ PRO
691006 1
691006
691006 3
691008 3
691008
691008 3
691008
691008 3
691008 3
691008 3
691008 3
691008 3
691008 3
691008 3
691008 3
691008
691009 3
691009
691009 2
691009
691010 3
691010 1
691010
691011 1
691011
691012 1
691012
691013 3
691013
691013
691013
691013 3
691013
691013
691013
691013 2
691014 3
691014
691014
691014
691014 1
691014 3
691014
691014
691014
691014
691014
691015 3
691019
691015
691015
691015 1
691013 1
691015 3
691013 3
691015 3
691015 3
691016 3
691016
691016
Page 47
H
GAL
T
02
U 000 D
60
24
23
0 00055 P
W 00550 P
21
U
21
21
21
21
21
21
21
21
23
U
C
U
C
U
C
U
C
U
C
U
C
U
C
U
C
0 00220
W 040 P
00
15
0
24
02
W 020 F
05
U
P
U 00110
0 050F
04
02
0 00195 F
24
W 003 P
02
24
W 00275 P
21
24
U 00110 P
W 00023 P
02
19
0 00520 F
U 000D
30
03
C
D
0 00520
24
W 003 P
02
02
02
21
21
21
21
24
0
0
U
U
U
U
W
UNCLASSIFIED
00110 P
005 P
05
000 D
04
000D
04
000 D
03
020 D
02
OOO23 P
LEG
COORO
S I M
1A YC490839 S
18 YC363998
1A XT1 15708 S
1A XT660167 S
18 XT6661S3
1A XU996155 S
1B XU992146
1A XU993148 S
1A XU977149 S
1A XU987147 S
1A XU994140 S
1A XU999148 S
1A XU991455 S
1A XU990145 S
U XU9891S5 S
1A YU254146
1A XT633156 S
18 XT640164
1A ZU000205 S
1B ZU100155
1A XT518256 S
1A BT 173077 S
1A XT629652
1A YD706102 S
18 Y 6 0 9
0205
1A YD620095 S
18 YD706102
1A XT167525 S
1B XT171526
2A XT160513
28 XT 1645 13
1A XT158514 S
18 XT161519
1C XT165515
10 XT 168520
1A YU036067 S
1A XT165525 S
18 XT171526
2A XT160513
28 XT 1645 13
1A YD662095 S
1A YT 199543 S
18 YT262488
1C YT263400
10 YT248378
1A YD706102
1B YD62009S
1A XT167525 S
18 XT171526
2A XT160513
28 XT 1645 13
1A YC83S998 S
1A YC863988 S
1A XU960030 S
1A YT020990 S
1A YT080950 S
1A YU250090 S
1A XT165525 S
18 XT171526
2A XT160513
F
G
H
H
H
H
H
H
H
H
H
H
G
H
G
F
H
H
G
G
G
H
F
G
H
H
H
H
H
H
G
�UNCLASSIFIED
YYMMDD CT2 PRO
H
GAL
T
LEG
COORD
S I M
YYMMOD CT2 PRO
Page 48
H
GAL
T
• a
691016
691016 3
691016 3
691017 3
691017
691017
691017
691017 3
691017 3
691017
691017 3
691017 3
691017
691017
691017
691018 3
691018
691018
691018
691018 3
691019 3
691019
691019
691019
691019 3
691019 3
691019
691020 3
691020
691020
691020
691020 3
691020 1
69102O
691021 3
691021
691021
691021
691021 3
691021 3
691021 2
691022 3
691022
691022
691022
691022 3
691022 3
691022
691022
691023 3
691023
691023
691023
691023 3
691023 3
691023 1
691024 3
691024
691024
691024
28
21
24
W 00010 F
U 005 D
06
W OO023 P
28
23
W 000F
01
W OO400 P
21
19
U 020D
02
U 000D
60
24
W OO023 P
28
24
W 000F
01
W 00023 P
28
21
W O0010 F
U 00110 D
U
24
W 003 P
02
28
03
W 00010 F
U
P
U 005
07
W 003 P
02
24
28
21
21
24
W
U
U
W
00010 F
00110 D
00110 P
003 P
02
21
21
U 00110 D
U 00110 D
B
B
24
28
21
05
24
W 003 P
02
W 007
02
U 020
02
U
W 003
02
F
0
P
P
2B XT164513
1A XT357147 S
1A YT 130990 S
1A XT167525 S
18 XT 17 1526
2A XT160513
2B XT164513
1A XT357147 S
1A XT644166 S
16 XT655168
1A YT070950 S
1A YT4 18563 S
1B YT364515
1C YT363437
1D YT380410
1A XT 165525 S
1B XT171526
2A XT160513
26 XT164513
1A XT3S7147 S
1A XT 165525 S
1B XT171526
2A XT160513
2B XT164513
1A XT357147 S
1A XU9S0140 S
1A XT629652
1A XT 165525 S
1B XT171526
2A XT160513
2B XT164S13
1A XT357147 S
1A BT549016 S
1A XT059888
1A XT 165525 S
1B XT171526
2A XT16O513
2B XT164513
1A XT357147 S
1A YUOOO150 S
1A YU036067 S
1A XT167S25 S
1B XT171526
2A XT160513
2B XT 1645 13
1A YU 190230 S
1A YU210180 S
1A YD282114
1A XT526746
1A XT 165525 S
1B XT171526
2A XT160513
2B XT164513
1A XT488048 S
1A YU270100 S
1A BS630855 S
1A XT 165525 S
1B XT171526
2A XT160513
28 XT164513
G
H
G
G
H
H
F
G
G
G
G
H
G
G
G
G
G
H
F
G
H
H
G
G
H
G
G
691024 3
691024 3
691024
691024
691025 1
691026 3
691026 1
691027 3
691027 1
691028 3
691028 3
691028
691028 3
691028
691028
691028
691028
691028
691028
691028
691029 3
691029
691030 3
691030
691031 1
691105 1
691105
691107 1
691109 3
691109
691109
691109
691109
691109
691109
691110 3
691110
691111 3
691111
691111
691111
691111
691111
691111
691111
691111
691112 2
691112
691112
691112
691112
691113 3
691113
691113
691 114 3
691114
691114
691114
691114
691114
28. . W. 0 0 8 F
02
24
U 00220 P
U
05
28
05
28
05
28
21
0
U
W
U
W
U
W
0
D
00010 F
D
000F
01
D
000F
01
D
24
U
P
28
W 00010 F
U 00110
W 00010 F
28
00150
U
02
02
B
P
B 00055 P
02
24
B 000P
04
U
P
16
U 000
30
24
U
U
P
B 030
02
16
B 01100 D
U
U
18
24
UNCLASSIFIED
B OO080 P
0 00055
0 00280
U
P
LEG
COORD
S I M
» *
1A XT488048 S
1A XT330900 S
1A BTS33094
1A XT770380
1A BS510750 S
1A XT357147 S
1A BS510750 S
1A XT357147 S
1A BS510750 S
1A XT357147 S
1A YT260990 S
1B YT280970
1A XT764380 S
1B XT770379
1C XT770380
1D XT773372
1E XT777372
1F XT779384
1G XT783388
1H XT784379
1A XT357147 S
1A YU254149
1A XT357147 S
1A XT895065
1A YD490197 S
1A Y0662095 S
1A XT780380
1A Y0662095 S
1A XT490470 S
1B XT490480
1C XT491473
10 XT492472
1E XT495473
1F XT495479
1G XT496477
1A YT548771 S
1B YT570730
1A XT490470 S
1B XT490480
1C XT491473
1D XT492472
1E XT495473
1F XT495479
10 XT496477
1A YC860980
18 YD890990
1A YU960200 S
1B YT5 10970
1C YT980980
1A XT522588
1A XT495473
1A YS8 13966 S
1A XT595270
1A C0068464
1A XT490470 S
1B XT490480
1C XT491473
10 XT492472
1E XT495473
1F XT495479
G.
H
H
G
H
G
H
G
H
H
G
G
H
H
H
H
F
H
F
H
H
�UNCLASSIFIED
YYMMDD CTZ PRO
H
GAL
T
LEG
COORD
S I M
YVMMDO CTZ PRO
Page 49
H
GAL
T
a *
691114
691115 3
691115 3
691115
691 115
6911 15
69111S
691116 1
691116
691116 3
691116
691117 3
691117
691117
691117
691119 3
691 119 3
691119 3
691119 3
691119
691119
691119
691120 3
691120 3
691121 3
691121
691124 3
691124 3
691125 3
691125 3
691125 3
691125
691126
691127
691128 3
691128
691128
691128 3
691128
691129 3
691129
691129
691201 1
691202 3
691202
691203 3
691203
691203
691203
691204 3
691204 3
691204
691204 3
691205 3
691205 3
691205 2
691206
691206 3
691206 1
691206
23
21
0
U 00100 P
U 00110
0 00110
02
0 00150 F
21
U 020P
02
U 00220
23
0
0 00110
24
24
23
24
W 00275 P
W 00275 D
0
0 005 0
05
0 00110
24
W 00275 F
23
24
0
23
23
21
21
21
0
0
0
0
U
U
U
U
005 0
05
005
05
0 3 0D
03
005D
03
00O D
04
000D
04
000D
03
U
23
U
0.00165 P
24
W 020 F
02
U
23
0
02
23
0 005 P
08
0 00330 P
21
U 00110 D
P
8
26
23
W 008 P
08
0 00165 P
23
23
26
17
0
0
W
U
0
W
0
26
05
00165 0
00165 P
008 P
08
0
00165 F
008 P
08
P
1G XT496477
1A XT650150 S
U YT265998 S
U BR499489
1A XT565275
18 XT577272
1C XT575240
1A YD6 20095 S
1B YD706102
1A YT268988 S
1A BR499489
1A XT650150 S
1A XT56S275
1B XT577272
1C XT575240
1A XT146567 S
1A XT295490 S
1A XT650150 S
1A XT573237 S
1A XT565275
1B XT577272
1C XT575240
1A XT146567 S
1A XT573237 S
1A XT573237 S
U XTS40240
1A XT540240 S
1A XT755160 S
1A YU225030 S
1A YU 105040 S
1A YT 188990 S
1A BS5 10750
1A BS5 10750
1A BS510750
1A XT572240 S
2A XT575275
3A XT540240
1A XT443345 S
1A XT770380
1A XT572240 S
2A XT575275
3A XT540240
1A YC863988 S
1A XT650170 S
1B XT685162
1A YU260170 S
1B YU260180
1C YU270170
1A XT905058
1A YT069120 S
1A XT68S162 S
16 XT690150
1A XT681265 S
1A XT540240 S
1A YT069120 S
1A BN020590 S
1A XT570240 S
1A YT069120 S
1A BS809398 S
1B BS809374
H
F
H
F
H
G
G
H
H
G
H
H
H
H
H
H
H
H
G
H
H
H
H
G
H
H
H
G
F
H
G
H
691206
691206
69 1 206
69 1 206
691206
691207 3
691207 1
691207 1
691208 3
691208 3
691208 1
691208
691208
691208
691208 1
691208
691208
691208
691210 1
691211 1
691213 3
691214 1
691214 1
691219 3
691219
691219
691220
691221 3
691221
691221
691221
691222 1
691222 1
691222 1
691222 1
691223 1
691223
691226 3
691226 1
691226 1
691226 1
691226
691226
691226
691226
691226
691227 3
691227 1
691227 1
691227 1
691229 1
691229
691229
691229
691229 1
691229 3
691229
691229
691230 3
691230 1
26
05
02
23
26
05
0
W
U
0
0
W
0
00165
008 P
08
P
00160 P
00165
008 P
08
P
05
0
P
02
02
28
02
02
21
0
0
0
0
0
U
005 P
05
00055 P
00220 P
00110 P
005 P
05
0000
30
24
U 000
04
U
D
U
02
02
02
03
03
23
03
02
02
U
U
U
U
U
U
U
0
U
0
0
0
000
04
D
D
0
P
>
000
04
01320 D
P
00110 P
00110 P
00110
U
23
02
02
02
03
0
0
0
0
0
02
23
0 00110 P
U 000D
90
23
02
0 01320 D
0 00330 P
UNCLASSIFIED
020D
02
0 2 0P
02
005 P
05
005 P
05
P
LEG
COORD
S I M
« •
1C BS828374
10 BS328390
1E BS814390
1F BS8 14398
1A XT600180
1A YT069120 S
1A BS630855 S
1A YD490195 S
1A XT570280 S
1A YT069120 S
1A BS865339 S
1B BS880339
1C BS88031S
10 BS864315
1A BS927222 S
1B BS927219
1C BSS31219
10 BS931222
1A YD620095 S
1A YD490198 S
1A XS570930 S
1A YD490198 S
1A Y0324258 S
1A YU702533 S
1B YU671450
1C YU671400
1A YD638274
1A XT045609 S
1B XT045552
1A BT533094
1A YD638274
1A ZD058031 S
1A Y0689274 S
1A ZD1 17014 S
1A BT549014 S
1A BT549014 S
1A ZD058031
1A XT680180 S
1A BT549016 S
1A YD660O95 S
1A YD490198 S
1A BS927222
1B BS927219
1C BS931219
1D BS931222
1A XS6 18748
1A XT670180 S
1A YC863998 S
1A YD662095 S
1A YD490198 S
1A BT507036 S
1B BT5 14505
1C BT515051
2B BT545064
1A YC863998 S
1A XT749230 S
1B XT689268
1C XT680299
1A XT680170 S
1A YC863988 S
G
G
H
H
G
H
H
H
H
H
H
H
F
F
G
G
G
G
G
H
G
H
H
H
H
H
H
G
H
F
H
H
�UNCLASSIFIED
YYMMOD CTZ PRO
H
GAL
T
LEG
COORD
S I M
YYMMDD CTZ PRO
Page 50
h
GAL
T
LEG
COORD
S I M
* *
691230
691230
691230
691231 3
700102
700102
700106 1
700107 3
700107
700107
700107
700107
700107
700107
700108 3
700108 3
700111
700111
700111
700111
700112 1
700115 3
700116 1
700120
700122 1
7 0 12S 1
0
700125
700125
700125
700125 1
700125
700125
700125
700131 1
700131
700131
700131
700131
700131
700131
700131
700201 1
700201
700201
700201
700201
700201
700201
700201 1
700201 1
700 1
021
700201 1
700201 1
700202
700202
700
022
700202
700202
700
022
700202
23
U 000
06
0 00165
0 00110
0 080D
08
U
U
05
21
U
P
U 000D
50
0 040
04
21
24
0 000D
08
B 070P
07
U 00110
U 00110
05
26
05
U
P
W 050
00
U
P
U
02
03
0 060P
00
0 00215 P
03
0 00110 P
02
B 005 C
09
03
03
03
03
03
05
W
P
0 020P
02
0 00110 P
0 00110 P
0 00110 P
0 040P
00
U
W 005
05
1A YD638274
1A YC863998
1A YD490197
1A XT670170 S
H
1A YD492279
1A BT533094
1A BS571963 S
1A YT376954 S
F
1B YT409793
1A XT632178
1B XT692164
1C XT701212
10 XT668243
1E XT604224
1A YU260170 S
H
1A XT500830 S
H
1A YT289939
1B YT298950
1A YT 130781
1B YT170819
1A BS571963 S
1A XT995122 S L
1A BSS71961 S
H
1A ZDOS8031
1A Y0620095 S
H
1A BT170079 S
H
1B BT 17 1077
1C BT173075
1D BT 175077
1A BT903235 S
H
1B BT901233
1C BT906233
10 BT903231
1A YC561825 S
H
2A YC516814
3A YC505815
4 A YC606809
5A YC844860
6A YC706882
7A YC624940
8A YC631941
1A BT538020 S
H
1B BT542022
1C BT548018
1D BT556008
1E BT551006
1F BT548006
1G BT541014
1A BT547015 S
H
1A BT437078 S
H
1A BT452039 S
H
1A BT451039 S
H
1A BS708608 S
G
1A AT987249
1B AT991252
1C AT991250
1D AT987248
1A BT 170074
1B BT 178081
1C BT 178075
700202
700 1
024
700 3
025
700
025
700205
700
025
700
02S
700
025
700
025
700
025
700
025
700
025
700
025
700 3
026
700 1
029
700
029
700210 2
700210 2
700210
700210
700210
700212 2
700213
700213
700213
700213
700215 2
700215
700217 2
702 1
020
700221 1
700221 1
702 1
022
702 1
022
702 1
023
700223 1
700224 1
700224 2
702
024
700225 1
702 3
026
702 1
026
702 3
026
702
026
702
026
702 1
027
700227
702
027
702
027
702
027
702
027
700227
700227
700227
700227
702
027
702
027
702
027
700227
702
027
03
26
0 00220 P
0 050
00
B 085
02
0 005
05
26
05
0 050
00
0 020P
00
U
15
11
U
07
W 040P
00
U 000D
30
U
U
U
07
W 00100 0
07
05
05
05
05
05
05
05
05
07
0
0
0
0
0
0
0
0
0
W
040P
00
020P
05
030P
02
00010 P
00320 P
OOO10 P
030P
02
00010 P
00320 P
020 P
00
U
05
26
05
23
0 00320 P
U
P
0 030P
02
U
P
U
U
05
UNCLASSIFIED
0 030P
02
0 00165
10 BT170081
H
1A BT547015 S
1A XT995122 S L
1A XT632178
1B XT692164
1C XT701212
10 XT668243
1E XT604224
1A XT632178
1B XT692164
1C XT701212
10 XT668243
1E XT604224
1A XT995122 S L
G
1A BS708608 S
1A YS21293S
1A YU590020 S R f
F
1A AQ890730 S
1B A0800730
2A A0890727
2B A0800727
1A BR465467 S
G
1A XS598964
1A XS470970
1A B0350620
1B BO 3 0 9
940
H
1A BR470640 S
1B BR470760
1A BR465467 S
G
1A BS8 14384 S
G
G
1A BS868320 S
G
1A BS635382 S
1A BS868320 S
G
G
1A BS635382 S
G
1A BS868320 S
G
1A BS635382 S
G
1A BS868320 S
H
1A BR550680 S
1A C0250210
G
1A BS868320 S
1A YT155015 S
G
1A BS868320 S
G
1A XT741330 S
1A YS 160990
1A XT741330
1A BS868320 S
G
1A BR525949
1A BR538988
16 BR508988
1C BR508958
1D BR530987
1E BR5 10965
1F BR924979
1G BR535985
1H BR542986
11 BR551959
1d BR553953
1K BR561941
1L BR565975
1M BR496002
�VI HVSk./" W Wll ll~l«/
1
YYMMOD CTZ PRO
H
T
GAL
700227
700227
700227
700228 1
700228 2
700228 2
700301 3
700302 2
700303 2
700303
700303
700303
700305 2
700306 3
700306 3
700 2
036
700307 2
700307
700308 2
700309 3
700309 1
700
039
700
039
700
039
700309 2
700310 2
700311 2
700312 2
700312
700312
700312
700312
700312
700312 2
700313 2
700314 2
700315 2
7003 13 2
700315 2
700316 2
700316
700316
700316
700316
700316
700316
700316
700318 2
700319 2
700320 2
70032 1 1
70032 1
70032 1
700321
700321
700321 2
700322 2
700323 2
700324 1
700324 1
OS
07
07
26
07
0
6
07
23
23
07
07
07
23
03
0
0
0
0
0
U
U
0
U
B
0
0
U
0
00310 P
00100 P
00100 P
050
70
00180 0
03000 0
030P
00
P
00110 P
00100 P
00100 P
00100 P
B oo no
0 040
04
07
07
07
27
0
0
0
U
00280 P
020P
00
00100 P
0000
30
07
07
07
07
07
07
11
W
W
W
U
0
W
U
000P
05
000P
05
000P
05
000C
20
000P
05
00100 P
000C
30
07
07
07
05
07
07
07
03
03
W
W
W
0
W
W
W
0
0
000P
05
00150 P
00100 P
000P
05
00100
00100
00100
00150
00310
P
P
P
P
P
LEG
COORD
S I M
1N BS505023
10 BS499004
IP BS467003
1A BS868320 S
G
H
1A BR478908 S
1A BR531971 S
H
1A XT995122 S L
1A BS877009 S
H
1A Y8773110 S
F
1B Y8745032
1C YA740920
1A XTS82034
1A 8R465467 S
G
1A XT60S155 S
G
1A XT665162 S
1A BR465467 S
G
1A BR465467 S
G
1A XT495475
1A BR46S467 S
G
1A XT66S162 S
G
H
1A BT163232 S
1B BT 163234
1C BT 167236
10 BT 168203
1A BR465467 S
G
1A BR465467 S
G
1A BR465467 S
G
H
1A B0450270 S
18 80800170
1C B0860120
10 8 8 0 4
0620
1E B0920330
1F 80890380
• 1A BR465467 S
G
1A BR46S467 S
G
1A BR465467 S
G
F
1A B0700980 S
1A SR421820 S
H
1A BR465467 S
G
1A BP030820 S
F
1B BP090830
1C BP 140835
10 BP 170850
1E BP 180880
1F BP200890
1G BP200850
1H BP 130840
1A BR465467 S
G
1A 8R465467 S
G
1A BR465467 S
G
H
1A BS8 13398 S
18 BS816392
1C BS825387
10 BS823379
1E BS8 12378
1A BR465467 S
G
1A BR465467 S
G
1A BR46S467 S
G
1A BT549016 S
G
H
1A BT 126458 S
YYMMDD CTZ PRO
700324
•• 700324
700324
700324
700324
700324 2
700325 1
700325 2
700325
700325
700325
700325
700325
700325
700325
700326 3
700326 2
700326
700326
700326
700326 2
700327 2
700328 2
700329 2
700329
700329
703 1
030
700330
700330
700330
700330
700330
700330
703 2
030
700331 2
700331
700331
700331
700331 2
700401 2
700401
700401 2
700 2
042
700 1
043
700 2
043
700
043
700
043
700 2
044
700 2
045
700 2
046
700 2
047
700 1
048
700
048
700
048
700
048
700 2
049
700
049
700
049
700
049
700
049
Page 51
H
GAL
T
07
03
07
W
0
W
0
21
33
U
C
U 000D
30
07
07
07
06
W
W
0
0
03
0 020C
02
07
11
W 000P
05
U 03000 C
07
07
U
07
07
03
07
00100 P
00150 P
00100 P
00200
00050 P
00100 P
OOO50 P
0000
20
W 00100 P
P
W 00150 P
W 00100 P
0
P
W 00150 P
0 00220
07
07
07
07
03
W
W
W
W
W
07
W 00100
0 020C
00
UNCLASSIFIED
00150
00100
00100
00100
00320
P
P
P
P
C
LEG
1B
1C
1D
1E
1F
1A
1A
1A
1A
16
1C
10
1E
1F
1G
1A
1A
18
1C
10
1A
BT134437
BT 134449
BT 137446
BT 130445
BT 130449
BR465467
BT549016
BR465467
BT 160030
BT 180030
BT 180040
BT 170040
BT 170050
BT 160050
BT 160030
YU000150
ZU 100240
ZU 180240
ZU 180340
ZU 100340
BR465467
S I M
COORO
S
S
S
G
G
S
S
H
F
S
G
G
H
1A BR465467 S
1A
1A
18
1C
1A
18
1C
1D
1E
1F
1G
BR522819 S
YB781110 S
YB747018
YB747920
BT160030 S
BT 180030
BT 180040
BT 170040
BT 170050
BT16O050
BT 160030
1A BR465467 S
1A
1B
1C
10
1A
1A
18
1A
1A
1A
1A
1A
1B
1A
8P430800 5
BP430900
BP060900
BP060800
BR465467 S
BS5 18069 S
BS627088
BR465467 S
BR465467 S
BT558003 S
BR465467 S
XT650250
XT660250
BR465467 S
1A BR465467 S
1A
1A
1A
1B
1C
BR465467 S
BR465467 S
BT250080 S
BT260080
BT220090
H
G
F
G
G
F
G
G
G
G
H
1A BR465467
1A
2A
3A
4A
5A
BR580700 S
SR600710
BR600720
BR600730
BR590750
H
�UNCLASSIFIED
YYMMOD CT2 PRO
H
GAL
T
LEG
COORD
S I M
YYMMDD CT2 PRO
Page 52
H
GAL
LEG
COORD
S 1 M
• «
700 2
049
700410 3
700410 1
700410
700410 3
70O410 2
700410 2
700412 2
700413 3
700413 2
700414 a
700416 2
700416 2
700416
700416
700416
700416
700416
700416
700416
700417 3
700417 1
700417
700417
70O417
700417 2
7004 1 7
700418 1
700418
700418
700418
700418
700418
70O418
700418
700418
700418
700418
700418
700418
70O418
700418
700418
700418
700419 2
700420 1
70O420
700420
700420
700420 2
700421 2
70042 S
700425
700425
700425
700425
700425
700426
700426
700426
07
23
03
0 00250 P
U
P
B
23
07
07
07
23
07
07
07
07
W 00055 f
0 00100 D
0 00250 0
0 00100 D
U
P
0 000D
05
0 00100 D
00000
05
0 000C
05
28
02
07
02
07
05
07
07
W OO110 W
0 00255 0
0
0
0
0
OO200 D
020
00
005P
06
020
00
0 020D
00
W 00100 P
0 00100 P
0 020P
00
8 00581
B 00581
1A BR464433 S
1A XT605155 S
1A BS360620 S 2 F
1B BS36564S
1A XT655166 S
G
1A BR464483 S
G
1A BR454450 S
G
1A BR454483 S
G
1A XT655157 S
G
1A BR464483 S
G
1A SR464483 S
G
1A BR464483 S
G
1A BR480860 S
H
1B BR480880
1C BR470890
10 BR460890
1E BR46090O
IF BR450900
1G BR490900
1H BR500900
1A XS524656 S
G
1A Y0680100 S
H
16 YD70O120
1C YD680120
10 YD70010O
1A BR464483 S
G
1A BR465467
1A YD340190 S
H
1A 8R590740
1B BR590750
1C BR580740
1D BR570750
1E BR580720
1F BR590720
16 BR580870
1H BR480880
11 BR500880
10 BR500890
1K BR420020
1L BR4 30020
1M BS4 10030
1N BS4 10020
2A BR5808S9
2B BR478970
1A BR464483 S
G
1A
1B
1C
1D
1A
1A
1A
1B
1C
1D
1E
1F
1A
1B
1C
H
BS632385 S
BS639381
BS63237S
B5629378
BR465467 S
BR46S467 S
AT948125
AT975132
BT015125
BT020100
BT020080
AT945108
AT948125
AT975132
BT015125
G
G
700426
700426
700426
700426
700427 1
700427
700427
700427
700427
700427
700427
700427
700427
702
048
700428
700428
700428
700428
700428
702 1
049
700430 1
700431 2
70043 1
700431
700431
700S01 1
700502
700503 1
700 1
054
700 3
057
700 1
058
700 1
058
700508
700508
700
058
700508 1
700 1
059
700 1
059
700
059
70O509
70O509
700510 1
7COS10 1
700510
700510
700510
700510 1
700510
700510
700510
700510
700510
700513 1
700513
700513
700513
70O514 1
70O514 1
700514
700514
03
U
B 00300 C
B 00581
B 00581
05
05
07
W
P
W
P
U 03000 D
05
05
05
24
03
03
W
P
U
W
P
W
P
U
P
0 00275 P
W 00105 P
02
03
03
B 00410 P
W
P
W 00105 P
03
03
W 00110 P
W 00105 P
02
B 00150 D
B
03
B
W 00105 P
03
03
0
P
W 00105 P
UNCLASSIFIED
1D
1E
1F
1A
1A
16
1C
1A
1B
1C
10
1E
1F
BT020100
BT020080
AT945108
YD827137
BT080230 S
BT090230
BT 1002 30
AT948125
AT975132
BT015125
BT020100
BT020080
AT945108
H
1A AT948125
1B AT975132
1C BT015125
10 BT020100
1E BT020O80
1F AT945108
1A BS815383 S
1A BS815383 S
1A BP430800 S
1B BP430900
1C BP060900
10 BP060SOO
1A BS812383 S
1A 20116013
1A BS752435 S
1A BS752435 S
1A XT492472 S
1A BT231315 S
1A BT225318 S
1B BT229317
1C BT229312
10 BT226312
1A Y0662095 S
1A BT232315 S
1A BT225318 5
1B BT229317
1C BT229312
10 BT226312
1A BT265266 S
1A BT225318 S
1B BT229317
1C BT229312
10 BT226312
1A Y0550035 S
1A YD640105
18 Y0640130
1C YD670130
10. YD670105
1A YD550035
1A BT225318 S
1B BT229317
1C BT229312
10 BT226312
1A BT231315 S
1A BT22S318 S
1B 8T229317
1C BT229312
H
H
F
H
G
G
G
H
G
G
G
H
G
G
G
�UIVV^U./nooin 1-1jr
YYMMDD CTZ PRO
700514
700315
700515
700515
700515
700517 1
700517 1
700517
700517
700517
700519 1
700521 3
700522 2
700523 1
700523 2
700524
700525 1
700525 3
700529 1
700530 3
700530 1
700601 1
700 1
062
700603 3
700 3
063
700 1
063
700 3
064
700611 1
700611
700611
700611
700611
700612 1
700612
700612
700612
700612 1
700612
700612
700612
700612 3
700612
700612
700612
700612
700613 3
7O0613
700613
700613
700613
700615 1
700616 1
700618 1
700618
700618
700618
700618 1
7 0 1-8
06
700618
700618
H
GAL
T
W 001 10
P
P
03
03
0
W
02
22
07
02
07
B 00225 P
B 00175 P
W 000 D
05
B 00170 P
W OOOSO D
8 030
00
B 00225 P
B 00330 P
B 00350 P
B 00110 P
B 020 P
07
P
W
B 020 P
04
B 00110 P
P
U
B 030 P
00
P
B
W
P
W
02
22
02
22
02
02
02
22
21
02
21
05
03
W 00165 P
03
B 00110 P
21
B
W
21
S OO110 P
P
P
P
W 00165 P
05
OS
03
W
W
03
B 00110
LEG
COORD
S I M
1D BT226312
1A BT051250
1B BT058251
1C BT058249
10 BT051249
1A BT231315 S
1A BT225318 S
1B 8T229317
1C BT229312
10 BT226312
1A YOS50035 S
1A XT8 18905 S
1A BR464483 S
1A YC834996 S
1A BR464483 S
1A YC834997
1A Y0550035 S
1A XT8 18905 S
1A Y0550035 S
1A XT8 18905 S
1A YD550035 S
1A YC835998 S
1A YC835998 S
1A XT967490 S
1A YC 1 0 7 S
400
1A YC83S998 S
1A YU 140070 S
1A BS872327 S
1A BS873327
18 BS876325
1C BS868317
10 BS867321
1A BT047245 S
18 BT04.7256
1C BT058245
10 BT058256
1A BT047245 S
1B BT047256
1C BT058245
10 BT058256
1A YU 140070 S
1A BS873327
1B BS876325
1C BS868317
10 BS867321
1A YU340450 S
1A BS873327
1B BS876325
1C BS868317
1D BS867321
1A BS8 12396 S
1A BS812383 S
1A BT047245 S
1B BT047256
1C BT058245
10 BT05S256
1A BT047245 S
1B BT047256
1C BT058245
10 BT058256
G
G
H
F
G
H
G
H
F
H
"H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
YYMMOD CT-Z PRO
700618 3
700618
702 3
060
700621 3
700623 3
700624 3
700628 1
700628
700628
700628
702 1
069
700629
702
069
70O629
703 1
060
703
060
703
060
700630
700702 1
700 1
072
700702
700702
700
072
700 1
078
700 1
079
700710 1
700711 1
700714 1
700715 1
700801 1
700 1
082
700 1
083
700 1
084
700 1
085
700 1
086
700807 1
700 1
088
700 1
089
700810 1
700812 1
700812 1
700812
700812
700812
700812
700812
70O812
700813 1
700813
700813
700813
700813 1
700814 1
700814
700814
700814
700814 1
700814
700814
700814
Page
H
T
GAL
21
B 00110 P
21
21
21
21
03
B
B
B
B
B
W
03
W OO130 P
03
W 00140 P
03
03
0 00220 P
U 001 10 P
03
02
02
02
02
02
03
03
03
03
03
03
03
03
03
03
01
OS
0
B
B
B
B
B
0
0
0
0
0
0
0
0
0
0
B
B
05
B 040C
00
02
05
W 000P
05
B 030 C
00
05
B 030C
00
UNCLASSIFIED
00075
00025
00130
00075
00130
P
P
P
P
P
00385 P
020P
07
00150 P
00150 P
00270 F
00225 F
047P
00
047P
00
00407 P
047P
00
047P
00
00407 P
047P
00
047P
00
047 P
00
047P
00
00550 P
OO650 C
LEG
COORO
53
S I M
1A YU 140070 S
1A BIOS 1249
1A YU 140070 S
1A YU 140070 S
1A YU 140070 S
1A YU 140070 S
1A AT95S002 S
1B AT964997
1C AT966994
10 AT950996
1A AT9S8002 S
1B AT964997
1C AT966994
10 AT950996
1A AT958002 S
1B AT964997
1C AT966994
1D AT950996
1A BT102140 S
1A AT958002 S
1B AT964997
1C AT966994
10 AT950996
1A BT 177078 S
1A Y0620095 S
1A YD620095 S
1A Y0620095 S
1A Y0620095 S
1A Y0620095 S
1A ZCOOS080 S
1A ZC005080 S
1A ZC005080 S
1A ZC005080 S
1A ZC005080 S
1A ZC005080 S
1A ZC005080 S
1A ZC005080 S
1A ZC005080 S
1A ZC005080 S
1A YD 110700 S
1A BS632548 S
1B BS624470
1C BS620503
10 BS616468
1E BS615567
1F BS597529
1Q BS590498
1A BS490690 5
1B BS490730
1C BS4S0730
10 BS440690
1A YD415212 S
1A BS520414 S
1B 8S520420
1C BS535397
10 BS540403
1A BSS20393
1B BS520388
1C BSS40393
10 BSS40400
h
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
�UNCLASSIFIED
YYMMDD CTZ PRO
700814 1
700814
'700814
700814
700815 1
700815
700815
700815
700815 1
700816 1
700816
700816
700816
700817 1
700818 1
700818
700818
700818
700818
700818
700818
700818
700818
700818
700819 1
700819
700819
700819
700819
700819
700819
700819
700819
700819
702 1
080
702
080
700820
700820
700820 1
700820
702
080
702
080
702 1
080
702
080
702
080
700820
700820 1
700820
700820
700820
700820 1
700820
700820
702
080
700821 1
700821
700821
700821
700821 1
700821
H
GAL
T
05
B 00500 C
05
B 00500 C
02
05
02
05
05
W 00150 P
B 01000 C
W 00150 P
W 00525 C
W 00525 C
03
W 020P
00
03
B 040C
00
03
B 00450 C
03
03
03
03
B 00100 C
B 00550 C
W 00100 C
W 040C
08
LEG
COORD
S I M
U BS500460 S H
16 BS500420
1C BS470420
10 8S470460
1A BS500460 S
H
18 BS500420
1C BS470420
10 BS470460
1A YD415212 S
H
1A BS370420 S
H
1B BS370488
1C BS440505
10 BS456563
1A YD415212 S
H
1A BS335449 S
H
1B BS3S4446
1C BS375434
10 BS380450
1E BS377470
1F BS 360480
16 BS3SOS50
1H BS338549
11 BS33Q525
10 BS344485
1A BS335449 S
H
16 8S354446
1C BS375434
10 BS380450
1E BS377470
1F BS360480
1G BS3S0550
1H BS338549
11 BS330525
10 BS344485'
1A AT981250 S
H
1B AT986247
1C AT991254
10 AT986253
1A BT093237 S
H
1B BT093230
1C BT 110230
10 BT1 10237
1A BT020200 S
H
1B BT020230
1C BT060200
10 BT060230
1A BT090250 S
H
1B BT09026O
1C BT 100260
10 BT 100250
1A BT080220 S
H
1B BT 130235
1C BT130218
10 BT080200
1A BT 110240 5
H
1B BT1 10250
1C BT 120250
10 BT 120240
1A BT1 15255 S
H
1B BT 135280
YYMMDD CTZ PRO
700821 1
700821
70082 1
70082 1
700821 1
700821
700822 1
700822
700822
700822
700822 1
700822
700822
700823 1
700823
700823 1
702
083
700824 1
700824
700824
700824
700824 1
702
084
700827 2
700827
700827
700827
700827 1
70O827 1
700827
700827
700827
700827 1
700827 1
702
087
700827
700827
702 1
087
700827
700827
702
087
700827 1
700827
700827 1
702
087
700827 1
700827
' 700827 1
7O0827
700827 1
700827 1
700827
700827 1
700827 1
700827
700828 1
700828
700828
700828
700828 1
Page 54
H
GAL
T
03
W 00480 C
03
W 00360 C
03
W 040C
08
W 00480
03
W 00120 C
03
W 00360 C
03
W 00360 C
03
W 00120 C
06
B 01200 C
03
03
U 00055 P
B 00100 C
03
03
B 005 C
00
B 000 C
09
03
B 00140 C
03
B 00250 C
03
B 005 C
00
03
B 00120 C
03
B 000C
09
03
03
B 005 C
00
B 00320 C
02
03
B 00225 P
B 000C
09
03
8 007C
07
03
B 000C
07
UNCLASSIFIED
LEG
COORD
S I M
1A BT135220 S
1B BT 160220
1C BT 160230
1D BT140230
1A BT145247 S
1B BT 170255
1A BT138010 S
1B BT150010
1C BS 135985
10 BS 125995
1A BT 150008 S
1B BT 164000
1C BS 180995
1A BT 135290 S
1B BT145279
1A AT945120 S
1B AT945098
1A AT945098 S
1B AT945120
1C AT940120
10 AT940098
1A BT 135290 S
1B BT145279
1A AS950950 S
1B AS990980
1C BS045975
10 BS030950
1A BT265266 S
1A B SOS 1964 S
1B BS034963
1C BS028954
10 BS023953
1A BS032971 S
1A BS041975 S
1B BS045979
1C BS042979
10 BS039976
1A BS040960 S
1B BS040950
1C BS035960
10 BS035950
1A AS980960 S
1B AS987954
U AS986968 S
1B AS991968
1A AS999975 S
18 BS007970
1A BS011978 S
1B BS014973
1A BS037969 S
1A AS94S953 S
18 AS984947
1A YD415212 S
1A BS002969 S
1B BS015966
1A AT950130 S
1B BT010130
1C BT020080
10 AT946100
1A AT968129 S
H
H
H
H
H
H
H
H
G
H
H
H
H
H
H
H
H
H
H
H
H
H
H
�UNCLASSIFIED
YYMMDO CTZ PRO
H
GAL
T
LEG
COORD
S I M
Page 55
YYMMOO CTZ PRO
H
LEG
GAL
COORD
S I'M
• a
700828
700828
700828 1
700828
700828 1
700828
700828 1
700828
700828 1
700828
700828
700828
700828
700828"
700828 1
700828
700828 1
700828
700828
700828
700828 1
700828
700828 1
700828 1
702 1
089
700829
700829
700829
700829 1
700829
700829 1
700829 1
703 1
080
700830
700830
700830
700830 1
700830
700830 1
700830
700830
700830
703
080
700830 1
700830 1
700830
700830 1
700830
703 1
080
700830
700830 1
700830
700830
700830 1
700830
703 1
080
700830
700830
700830
700830 1
03
B 000C
09
03
B 00025 C
03
B 000C
06
03
B 00120 C
03
B 00300 C
03
B 000C
07
03
B 00015 C
02
03
03
B 0022S P
U
' P
B 07S C
06
•
03
B 030C
00
02
03
03
B 00225 P
U
P
B 00765 C
03
B 00025 C
OS
8 00075 C
OS
03
B 00015 C
B 000C
09
03
B 00110 C
03
B 00280 C
03
B 00275 C
03
03
03
B 000 C
09
B 00110 C
B 000C
04
1B
1C
1A
1B
AT972134
AT980121
AT990123 S
BT010119
1A AT979103 S
18
1A
1B
1A
1B
1C
1D
1E
1F
1A
1B
AT987099
AT967094 S
AT971084
BT001096 S
8T004104
BT019104
BT020099
BT008099
BT00509S
AT953116 S
AT972104
1A AT949123 S
1B AT952122
1C AT951106
1D AT945108
1A AT952122 S
1B AT966125
1A YD490198 S
1A BTS33094 S
1A AT950130 S
1B BT010130
1C BT020080
10 AT946100
1A AT984132 S
18 BT000124
1A YD490198 S
1A BT533094 S
1A AT9S0130 S
18 BT010130
1C BT020080
1D AT946100
1A AT990980 S
1B AT993975
1A AS996970 S
1B BS003980
1C BS006975
10 BS000975
1E AS999970
1A 8S003965 S
1A BT002130 S
1B BT012125
1A BT012125 S
1B BT018115
1A AT977123 S
1B AT990110
1A AT980110 S
1B 8 0 4 9
T000
1C AT992110
1A AT972110 S
1B AT980104
1A AT953103 S
18 AT970103
1C AT970097
10 AT965095
1A AT96908S S
H
H
H
H
H
H
H
H
G
H
H
H
G
H
H
H
H
H
H
H
H
H
H
H
700830
700830 1
700830 1
700830
700830
700831 1
70083 1
700831 1
700831 1
700831 1
700831 1
700831 1
700901 1
700901
700 1
097
700907 1
700 1
098
700
098
700
098
700
098
700
098
700
098
700
098
700 1
099
700 1
099
700911 1
700911
700911
700911
700917 1
700917
702 1
090
702
090
702
090
700921 1
700921
700921
700921
700921 1
700923 1
700923
700923
700923
700923
700925 1
700925
700925
700925
701001
701001
701001
701001
701001
701007 1
701007 1
701009 1
701009 1
701009
701009
701010 1
02
02
B 00075 P
B 00075 P
B 000
09
03
B 080C
00
02
02
02
02
03
02
B
B
B
B
U
B
01
02
05
B 00110 P
B 000C
04
B 090C
00
00075
O0030
000
03
000
03
P
P
P
P
P
00225 F
"
01
01
02
B 00100
U
P
U
P
B OO200 C
1B AT977082
1A YD47611 1 S
1A YD415212 S
1A AT975100
1B AT982093
1A BT080290 S
1B BT160210
1A YD415212 S
1A YD476111 S
1A YD428122 S
1A YD490198 S
1A BT533094 S
1A YD490198 S
1B YD532315
1A YD13S643 S
1A YC700740 S
1A BS169810 S
1B BS2157SO
2A BS 175750
3A BS 195728
4A BS150772
4B BS 176784
1A Y0495289
1A YD1 17702 S
1A YD135643 S
1A YC580940 S
1B YC60O940
1C YC580920
10 YC600920
1A YC634S62 S
1B YC636862
1A YC635862 S
1B YC633863
1C YC667869
1A YC62083S .5
18 YC625830 '
2A YC668892
3A YC668868
1A YD620095 S
1A YC607812 S
2A YC882780
3A YC888763
4A YC886745
02
B 00100 C
02
B 00100 C
02
B 00100 C
02
02
B 00225 P
B 00025 C
B 005
09
01
B 000C
02
1A
2A
3A
4A
B
1A
1B
1A
1A
1A
1A
H
H
H
H
H
G
H
H
H
H
H
H
H
1A YC844749
1B YC854757
1C YC884747
B
H
H
H
H
H
H
H
5A YC881726
01
03
02
02
03
UNCLASSIFIED
B OO030 C
U
P
B 00115 P
B 000C
03
0 000
08
B
P
YD070143 S
YD 100 128
YD095130
YD096148
XC595925
XC6 12930
YD121231
BT533094
YD630080
YC792801
S
S
S
S
2A YDS 16854
3 A YDS 15857
1A AT865582 S
H
H
G
H
H
�UNCLASSIFIED
YYMMOD CTZ PRO
H
GAL
T
LEG
COORD
S I M
YYMMOD CT2 PRO
Page 56
H
GAL
T
m
701013 1
701013
701013
701013
701014 1
701014
701014 1
701014
701014
701014
701015 1
701018 1
701018 1
701018
701019 1
701031
701 102 3
701201 3
701202 3
701229 3
710114
710122
710319 1
710319
710319
710319 1
710319
710319
710319
710319
710319
710319
710319
710319
710320 1
710320
710320
710320
710320
710320
710320
710320
710320
710321 1
710321
710321
710321
710321
710321
710321
710321
710321
710322 1
710322
710322
710322
710322
710322
710322
710322
01
B 000 C
06
03
8 00022 C
01
8 000 C
03
B 000
07
02
01
02
01
8
B
B
0
B
U
B
B
B
U
U
U
B
01
B
02
21
21
21
24
00100
005
00
00100
000
04
00100
00110
OOOSO
00170
000
03
C
C
P
P
P
0
008 F
03
0
01
B
D
01
B
D
01
B
D
1A YD06724L. S- • H .
2A YD063242
3A YD058239
4A YOOS8293
1A ZC1S7218 S
H
1B ZC164215
1A Y0908790 S
H
2A YD919793
1A AT200188
1B AT210180
1A YD630O80 S
H
1A XD943325 S
H
1A YD630080 S
H
1A XU9 3 0 0
08
1A YD630080 S
H
1A YD490198
1A YU140O70 S
H
1A YU140070 S
H
1A YU140070 S
H
1A XT086818 S
1A B5630855
1A BTSS5035
1A YD030570 S
H
18 YDO 10570
2A XD985S51
1A XD982S42
1B XD982510
1C XD98SS10
1D XD988S47
1E XD982542
2A XD979544
2B X0978510
3A X0992523
3B YD015S60
1A XD982542
1B XD982510
1C XD985510
10 X0988547
1E XD982542
2A XD979544
2B XD978510
3A XD992523
3B XDO 1S560
1A X0982542
1B XD982510
1C XD985510
10 XD988547
1E X0982542
2A XD979544
28 X0978510
3A X0992523
38 Y0015S60
1A XD982542
1B X0982510
1C XD98S510
10 X0988547
1E X0982542
2A XD979544
28 XD978510
3A XD992S23
710322
710323 1
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323 1
710323
710323
710323
710323
710323
710323
710323
710323
710425 1
710504 1
711124 3
711128
711129
711130
711214 3
711216 3
711217 3
711219 3
711227 3
01
B 0007S D
01
B
D
03
03
19
U
U
U
U
U
U
B
B
B
B
B
01600 P
080 P
00
D
26
26
26
26
19
UNCLASSIFIED
070
20
01350
01800
000
50
00100
P
P
P
P
P
36 YD015560
1A XD982542 S
1B X0982510
1C X098S510
10 XD988547
1E XD982542
2A XD98S550
2B XD979544
2C XD978510
20 XD975510
2E XD975544
2F XD985550
3A YD020558
38 XD99S548
3C X0992551
3D YDO 15560
3E Y0020558
1A XD982542
1B X0982510
1C XD985510
10 XD988547 S
1E XD982542 S
2A XD979544 S
28 XD978510 S
3A X0992523 S
3B YDO 15560 S
1A BT533094 S
1A BT533094 S
1A YT603120 S
1A XT990130
1A XT990130
1A XT990130
1A YT041166 S
1A YT041166 S
1A YT041166 S
1A YT041166 S
1A YT603120 S
m
H
G
G
H
H
H
H
H
H
�Page
�UNCLASSIFIED
FOR DATE OF 603198 THERE ARE
FOR DATE OF 610810 THERE ARE
FOR DATE OF 610824 THERE ARE
FOR DATE OF 610907 THERE ARE
FOR DATE OF 6 1 1 0 - - THERE ARE
FOR DATE OF 620110 THERE ARE
FOR DATE OF 620201 THERE ARE
FOR DATE OF 620202 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
223
FOR DATE OF 6 0 0 THERE ARE
224
FOR DATE OF 620205 THERE ARE
FOR DATE OF 620206 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
227
FOR DATE OF 6 0 0 THERE ARE
228
FOR DATE OF 6 0 0 THERE ARE
229
FOR DATE OF 620210 THERE ARE
FOR DATE OF 620211 THERE ARE
FOR DATE OF 620212 THERE ARE
FOR DATE OF 620213 THERE ARE
FOR DATE OF 620214 THERE ARE
FOR DATE OF 620215 THERE ARE
FOR DATE OF 620216 THERE ARE
FOR DATE OF 620217 THERE ARE
FOR DATE OF 6203
THERE ARE
FOR DATE OF 620305 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
293
FOR DATE OF 6 0 0 THERE ARE
294
FOR DATE OF 6 0 0 THERE ARE
295
FOR DATE OF 6 0 0 THERE ARE
296
FOR DATE OF 6 0 0 THERE ARE
297
FOR DATE OF 620920 THERE ARE
FOR DATE OF 620921 THERE ARE
FOR DATE OF 620924 THERE ARE
FOR DATE OF 620927 THERE ARE
FOR DATE OF 620930 THERE ARE
FOR. DATE OF 621001 THERE ARE
FOR DATE OF 621003 THERE ARE
FOR DATE OF 621004 THERE ARE
FOR DATE OF 621008 THERE ARE
FOR DATE OF 621009 THERE ARE
FOR DATE OF 621010 THERE ARE
FOR DATE OF 621011 THERE ARE
FOR DATE OF 621121 THERE ARE
FOR DATE OF 621122 THERE ARE
FOR DATE OF 621123 THERE ARE
FOR DATE OF 621214 THERE ARE
FOR DATE OF 621218 THERE ARE
FOR DATE OF 621224 THERE ARE
FOR DATE OF 630216 THERE ARE
FOR DATE OF 630218 THERE ARE
FOR DATE OF 630219 THERE ARE
FOR DATE OF 630220 THERE ARE
FOR DATE OF 630224 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
366
FOR DATE OF 6 0 0 THERE ARE
367
FOR DATE OF 630608 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
369
FOR DATE OF 630715 THERE ARE
FOR DATE OF 630716 THERE ARE
FOR DATE OF 630717 THERE ARE
FOR DATE OF 630718 THERE ARE
FOR DATE OF 630719 THERE ARE
FOR DATE OF 631026 THERE ARE
FOR DATE OF 631027 THERE ARE
FOR DATE OF 631029 THERE ARE
1 RECORDS.
1 RECORDS.
2 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
3 RECORDS.
3 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
1 RECORDS.
4 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
UNCLASSIFIED
Appendix B Page 58
�UNCLASSIFIED
FOR DATE OF 631031 THERE ARE
FOR DATE OF 631113 THERE ARE
FOR DATE OF 631114 THERE ARE
FOR DATE OF 631116 THERE ARE
FOR DATE OF 631119 THERE ARE
FOR DATE OF 631121 THERE ARE
FOR DATE OF 631122 THERE ARE
FOR DATE OF 631123 THERE ARE
FOR DATE OF 631208 THERE ARE
FOR DATE OF 631209 THERE ARE
FOR DATE OF 631223 THERE ARE
FOR DATE OF 640131 THERE ARE
FOR DATE OF 64020S THERE ARE
FOR DATE OF 64030* THERE ARE
FOR DATE OF 640304 THERE ARE
FOR DATE OF 640419 THERE ARE
FOR DATE OF 640420 THERE ARE
FOR DATE OF 640421 THERE ARE
FOR DATE OF 640422 THERE ARE
FOR DATE OF 640423 THER£ ARE
FOR DATE OF 640424 THERE ARE
FOR DATE OF 640425 THERE ARE
FOR DATE OF 640430 THERE ARE
"FOR DATE OF 640526 THERE ARE
FOR DATE OF 640531 THERE ARE
FOR DATE OF 640624 THERE ARE
FOR DATE OF 6 0 2 THERE ARE
465
FOR DATE OF 640626 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
478
FOR DATE OF 640722 THERE ARE
FOR DATE OF 6 0 2 THERE ARE
480
FOR DATE OF 640826 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
495
FOR DATE OF 640926 THERE ARE
FOR DATE OF 641003-THERE ARE
FOR DATE OF 641004 THERE ARE
FOR DATE OF 641005 THERE ARE
FOR DATE OF 641006 THERE ARE
FOR DATE OF 641011 THERE ARE
FOR DATE OF 641012 THERE ARE
FOR DATE OF 641013 THERE ARE
FOR DATE OF 641022 THERE ARE
FOR DATE OF 641119 THERE ARE
FOR DATE OF 641222 THERE ARE
FOR DATE OF 641223 THERE ARE
FOR DATE OF 641224 THERE ARE
FOR DATE OF 650101 THERE ARE
FOR DATE OF 650111 THERE ARE
FOR DATE OF 650112 THERE ARE
FOR DATE OF 650113 THERE ARE
FOR DATE OF 650118 THERE ARE
FOR DATE OF 650119 THERE ARE
FOR DATE OF 650121 THERE ARE
FOR DATE OF 650122 THERE ARE
FOR DATE OF 650123 THERE ARE
FOR DATE OF 650124 THERE ARE
FOR DATE OF 650125 THERE ARE
FOR DATE OF 650126 THERE ARE
FOR DATE OF 650127 THERE ARE
FOR DATE OF 650129 THERE ARE
FOR DATE OF 650201 THERE ARE
FOR DATE OF 650202 THERE ARE
FOR DATE OF 650203 THERE ARE
FOR DATE OF 650204 THERE ARE
FOR DATE OF 65020S THERE ARE
FOR DATE OF 650206 THERE ARE
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
1 RECORDS.
10 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
6 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
12 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
12 RECORDS.
1 RECORDS.
5 RECORDS.
5 RECORDS.
5 RECORDS.
5 RECORDS.
5 RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
1 RECORDS.
1 RECORDS.
5 RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
6 RECORDS.
4 RECORDS.
2 RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
2 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
UNCLASSIFIED
Page 59
�UNCLASSIFIED
FOR OATE OF 6S0207 THERE ARE
FOR DATE OF 650215 THERE ARE
FOR DATE OF 650216 THERE ARE
FOR OATE OF 650217 THERE ARE
FOR DATE OF 650218 THERE ARE
FOR DATE OF 650301 THERE ARE
FOR DATE OF 650302 THERE ARE
FOR DATE OF 650303 THERE ARE
FOR DATE OF 650304 THERE ARE
FOR DATE OF 660305 THERE ARE
FOR OATE OF 650306 THERE ARE
FOR DATE OF 650312 THERE ARE
FOR OATE OF 650318 THERE ARE
FOR DATE OF 650329 THERE ARE
FOR OATE OF 650330 THERE ARE
FOR DATE OF 650401 THERE ARE
FOR OATE OF 650402 THERE ARE
FOR DATE OF 650412 THERE ARE
FOR DATE OF 650413 THERE ARE
FOR DATE OF 650414 THERE ARE
FOR DATE OF 650417 THERE ARE
FOR DATE OF 650418 THERE ARE
FOR DATE OF 650420 THERE ARE
FOR DATE OF 650430 THERE ARE
FOR DATE OF 650301 THERE ARE
FOR DATE OF 650S07 THERE ARE
FOR DATE OF 650525 THERE ARE
FOR DATE OF 650721 THERE ARE
FOR DATE OF 650722 THERE ARE
FOR DATE OF 650724 THERE ARE
FOR OATE OF 650725 THERE ARE
FOR OATE OF 650726 THERE ARE
FOR DATE OF 650727 THERE ARE
FOR OATE OF 650728 THERE ARE
FOR OATE OF 650729 THERE ARE
FOR DATE OF 650901 THERE ARE
FOR DATE OF 651101 THERE AR.E
FOR DATE OF 651203 THERE ARE
FOR DATE OF 651204 THERE ARE
FOR OATE OF 651205 THERE ARE
FOR DATE OF 651208 THERE ARE
FOR DATE OF 651209 THERE ARE
FOR DATE OF 651210 THERE ARE
FOR DATE OF 651211 THERE ARE
FOR DATE OF 651213 THERE ARE
FOR DATE OF 651214 THERE ARE
FOR DATE OF 651215 THERE ARE
FOR DATE OF 651220 THERE ARE
FOR DATE OF 651221 THERE ARE
FOR DATE OF 651222 THERE ARE
FOR DATE OF 651223 THERE ARE
FOR DATE OF 651224 THERE ARE
FOR DATE OF 651227 THERE ARE
FOR DATE OF 651228 THERE ARE
FOR DATE OF 651229 THERE ARE
FOR DATE OF 651230 THERE ARE
FOR OATE OF 651231 THERE ARE
FOR DATE OF 660101 THERE ARE
FOR DATE OF 660102 THERE ARE
FOR DATE OF 660103 THERE ARE
FOR DATE OF 660104 THERE ARE
FOR DATE OF 660105 THERE ARE
FOR DATE OF 660106 THERE ARE
FOR DATE OF 660107 THERE ARE
FOR DATE OF 660108 THERE ARE
FOR DATE OF 660109 THERE ARE
2 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
4 RECORDS.
4 RECORDS.
8 RECORDS.
8 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
13 RECORDS.
9 RECORDS.
6 RECORDS.
9 RECORDS.
5 RECORDS.
2 RECORDS.
4 RECORDS.
2 RECORDS.
4 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
1 RECORDS.
1 RECORDS.
8 RECORDS.
12 RECORDS.
9 RECORDS.
4 RECORDS.
10 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
6 RECORDS.
4 RECORDS.
6 RECORDS.
2 RECORDS.
8 RECORDS.
5 RECORDS.
10 RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
7 RECORDS.
6 RECORDS.
6 RECORDS.
2 RECORDS.
7 RECORDS.
16 RECORDS.
18 RECORDS.
10 RECORDS.
10 RECORDS.
UNCLASSIFIED
Page 60
�UNCLASSIFIED
FOR DATE OF 660110 THERE ARE
FOR DATE OF 660111 THERE ARE
FOR DATE OF 660112 THERE ARE
FOR DATE OF 660113 THERE ARE
FOR DATE OF 660114 THERE ARE
FOR DATE OF 660115 THERE ARE
FOR DATE OF 660116 THERE ARE
FOR DATE OF 660117 THERE ARE
•FOR DATE OF 660118 THERE ARE
FOR DATE OF 660119 THERE ARE
FOR DATE OF 660120 THERE ARE
FOR DATE OF 660124 THERE ARE
FOR DATE OF 660125 THERE ARE
FOR DATE OF 660126 THERE ARE
FOR DATE OF 660127 THERE ARE
FOR DATE OF 660128 THERE ARE
FOR DATE OF 660129 THERE ARE
FOR DATE OF 660130 THERE ARE
FOR DATE OF 660131 THERE ARE
FOR DATE OF 660201 THERE ARE
FOR DATE OF 660202 THERE ARE
FOR DATE OF 660203 THERE ARE
FOR DATE OF 660205 THERE ARE
FOR DATE OF 660206 THERE ARE
FOR DATE OF 660207 THERE ARE
FOR DATE OF 660208 THERE ARE
FOR DATE OF 660209 THERE ARE
FOR DATE. OF 660210 THERE ARE
FOR DATE OF 660211 THERE ARE
FOR DATE OF 660212 THERE ARE
FOR DATE OF 660213 THERE ARE
FOR DATE OF 660214 THERE ARE
FOR DATE OF 660215 THERE ARE
FOR DATE OF 660216 THERE ARE
FOR DATE OF 660218 THERE ARE
FOR DATE OF 660219 THERE ARE
FOR DATE OF 660220 THERE ARE
FOR DATE OF 660224 THERE ARE
FOR DATE OF 660225 THERE ARE
FOR DATE OF 660226 THERE ARE
FOR DATE OF 660227 THERE ARE
FOR DATE OF 660228 THERE ARE
FOR DATE OF 660301 THERE ARE
FOR DATE OF 660302 THERE ARE
FOR DATE OF 660304 THERE ARE
FOR DATE OF 660305 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
636
FOR DATE OF 660307 THERE ARE
FOR DATE OF 660308 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
639
FOR DATE OF 660310 THERE ARE
FOR DATE OF 660311 THERE ARE
FOR DATE OF 660312 THERE ARE
FOR DATE OF 660313 THERE ARE
FOR DATE OF 660315 THERE ARE
FOR DATE OF 660316 THERE ARE
FOR DATE OF 660318 THERE ARE
FOR DATE OF 660325 THERE ARE
FOR DATE OF 660329 THERE ARE
FOR DATE OF 660330 THERE ARE
FOR DATE OF 660331 THERE ARE
FOR DATE OF 660401 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
644
FOR DATE OF 6 0 0 THERE ARE
643
FOR DATE OF 6 0 0 THERE ARE
646
FOR DATE OF 6 0 0 THERE ARE
648
4 RECORDS.
2 RECORDS.
12 RECORDS.
11 RECORDS.
2 RECORDS.
8 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
6 RECORDS.
4 RECORDS.
4 RECORDS.
22 RECORDS.
7 RECORDS.
8 RECORDS.
9 RECORDS.
4 RECORDS.
4 RECORDS.
3 RECORDS.
2 RECORDS.
6 RECORDS.
5 RECORDS.
2 RECORDS.
4 RECORDS.
2 RECORDS.
5 RECORDS.
2 RECORDS.
4 RECORDS.
4 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS..
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
8 RECORDS.
8 RECORDS.
4 RECORDS.
4 RECORDS.
6 RECORDS.
3 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
6 RECORDS.
3 RECORDS.
6 RECORDS.
3 RECORDS.
2 RECORDS.
4 RECORDS.
4 RECORDS.
2 RECORDS.
4 RECORDS.
2 RECORDS.
3 RECORDS.
1 RECORDS.
2 RECORDS.
8 RECORDS.
6 RECORDS.
UNCLASSIFIED
Page 61
�UNCLASSIFIED
FOR DATE OF 660410 THERE ARE
FOR DATE OF 660411 THERE ARE
FOR DATE OF 660412 THERE ARE
FOR DATE OF 660415 THERE ARE
FOR DATE OF 66O416 THERE ARE
FOR DATE OF 660418 THERE ARE
FOR DATE OF 660419 THERE ARE
FOR DATE OF 660420 THERE ARE
FOR DATE OF 660423 THERE ARE
FOR DATE OF 660425 THERE ARE
FOR DATE OF 660427 THERE ARE
FOR DATE OP 660429 THERE ARE
FOR DATE OF 660430 THERE ARE
FOR DATE OF 660501 THERE ARE
FOR DATE OF 660S02 THERE ARE
FOR DATE OF 660503 THERE ARE
FOR DATE OF 660504 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
655
FOR DATE OF 6 0 0 THERE ARE
656
FOR DATE OF 660507 THERE ARE
FOR DATE OF 660508 THERE ARE
FOR DATE OF 660S09 THERE ARE
FOR DATE OF 660510 THERE ARE
FOR DATE OF 660511 THERE ARE
FOR DATE OF 660512 THERE ARE
FOR DATE OF 660513 THERE ARE
FOR DATE OF 660514 THERE ARE
FOR DATE OF 660515 THERE ARE
FOR DATE OF 660517 THERE ARE
FOR DATE OF €60519 THERE ARE
FOR DATE OF 660520 THERE ARE
FOR DATE OF 660525 THERE ARE
FOR DATE OF 660526 THERE ARE
FOR DATE OF 660527 THERE ARE
FOR DATE OF 660530 THERE ARE
FOR DATE OF 660531 THERE ARE
FOR DATE OF 660601 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
662
FOR DATE OF 660603 THERE ARE
FOR DATE OF 66O604 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
665
FOR DATE OF 6 0 0 THERE ARE
666
FOR DATE OF 660607 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
668
FOR DATE OF 6 0 0 THERE ARE
669
FOR DATE OF 66O611 THERE ARE
FOR DATE OF 660613 THERE ARE
FOR DATE OF 660614 THERE ARE
FOR DATE OF 660616 THERE ARE
FOR DATE OF 660617 THERE ARE
FOR DATE OF 660618 THERE ARE
FOR DATE OF 660620 THERE ARE
FOR DATE OF 660624 THERE ARE
FOR DATE OF 660625 THERE ARE
FOR DATE OF 660626 THERE ARE
FOR DATE OF 660627 THERE ARE
FOR DATE OF 660630 THERE ARE
FOR DATE OF 660706 THERE ARE
FOR DATE OF 660707 THERE ARE
FOR DATE OF 660712 THERE ARE
FOR DATE OF 660713 THERE ARE
FOR DATE OF 660714 THERE ARE
FOR DATE OF 660715 THERE ARE
FOR DATE OF 660716 THERE ARE
FOR DATE OF 660717 THERE ARE
FOR DATE OF 660720 THERE ARE
4 RECORDS.
1 RECORDS.
8 RECORDS.
7 RECORDS.
5 RECORDS.
7 RECORDS.
3 RECORDS.
7 RECORDS.
6 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
4 RECORDS.
4 RECORDS.
3 RECORDS.
8 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
5 RECORDS.
6 RECORDS.
2 RECORDS.
4 RECORDS.
8 RECORDS.
4 RECORDS.
2 RECORDS.
4 RECORDS.
1 RECORDS.
4 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
3 RECORDS.
1 RECORDS.
1 RECORDS.
8 RECORDS.
2 RECORDS.
1 RECORDS.
1 RECORDS.
3 RECORDS.
4 RECORDS.
3 RECORDS.
2 RECORDS.
2 RECORDS.
3 RECORDS.
1 RECORDS.
4 RECORDS.
5 RECORDS.
4 RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
3 RECORDS.
1 RECORDS.
2 RECORDS.
3 RECORDS.
1 RECORDS.
5 RECORDS.
5 RECORDS.
4 RECORDS.
2 RECORDS.
3 RECORDS.
2 RECORDS.
UNCLASSIFIED
Page 62
�UNCLASSIFIED
FOR DATE OF 660722 THERE ARE
FOR DATE OF 660724 THERE ARE
FOR DATE OF 660729 THERE ARE
FOR DATE OF 660730 THERE ARE
FOR DATE OF 660801 THERE ARE
FOR DATE OF 660802 THERE ARE
FOR DATE OF 660804 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
685
FOR DATE OF 660806 THERE ARE
FOR DATE OF 660809 THERE ARE
FOR DATE OF 660811 THERE ARE
FOR DATE OF 660813 THERE ARE
FOR DATE OF 660815 THERE ARE
FOR DATE OF 660816 THERE ARE
FOR DATE OF 660819 THERE ARE
FOR DATE OF 660820 THERE ARE
FOR DATE OF 660821 THERE ARE
FOR DATE OF 660822 THERE ARE
FOR DATE OF 660824 THERE ARE
FOR DATE OF 660825 THERE ARE
FOR DATE OF 660826 THERE ARE
FOR DATE OF 660829 THERE ARE
FOR DATE OF 660831 THERE ARE
FOR DATE OF 660902 THERE ARE
FOR DATE OF 660903 THERE ARE
FOR DATE OF 660904 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
699
FOR DATE OF 660919 THERE ARE
FOR DATE OP 660920 THERE ARE
FOR DATE OF 660922 THERE ARE
FOR DATE OF 661014 THERE ARE
FOR DATE OF 661025 THERE ARE
FOR DATE OF 661026 THERE ARE
FOR DATE OF 661027 THERE ARE
FOR DATE OF 661031 THERE ARE
FOR DATE OF 661101 THERE ARE
FOR DATE OF 661102 THERE ARE
FOR DATE OF 661105 THERE ARE
FOR DATE OF 661110 THERE ARE
FOR DATE OF 661120 THERE ARE
FOR DATE OF 661123 THERE ARE
FOR DATE OF 661124 THERE ARE
FOR DATE OF 661125 THERE ARE
FOR DATE OF 661128 THERE ARE
FOR DATE OF 661129 THERE ARE
FOR DATE OF 661130 THERE ARE
FOR DATE OF 661204 THERE ARE
FOR DATE OF 661205 THERE ARE
FOR DATE OF 661208 THERE ARE
FOR DATE OF 661210 THERE ARE
FOR DATE OF 661211 THERE ARE
FOR DATE OF 661216 THERE ARE
FOR DATE OF 661-223 THERE ARE
FOR DATE OF 661228 THERE ARE
FOR DATE OF 670103 THERE ARE
FOR DATE OF 670105 THERE ARE
FOR DATE OF 670106 THERE ARE
FOR DATE OF 670107 THERE ARE
FOR DATE OF 670108 THERE ARE
FOR DATE OF 670109 THERE ARE
FOR DATE OF 670110 THERE ARE
FOR DATE OF 670111 THERE ARE
FOR DATE OF 670112 THERE ARE
FOR DATE OF 670113 THERE ARE
FOR DATE OF 670114 THERE ARE
FOR DATE OF 670113 THERE ARE
RECORDS.
RECORDS.
RECORDS.
RECORDS.
2 RECORDS.
3 RECORDS.
3 RECORDS.
4 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
3 RECORDS.
7 RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
2 RECORDS.
2 RECORDS.
4 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
3 RECORDS.
2 RECORDS.
3 RECORDS.
8 RECORDS.
4 RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
4 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
2 RECORDS.
4 RECORDS.
3 RECORDS.
4 RECORDS.
10 RECORDS.
2 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
3 RECORDS.
1 RECORDS.
8 RECORDS.
2 RECORDS.
4 RECORDS .
5 RECORDS.
1 RECORDS.
UNCLASSIFIED
Page 63
�UNCLASSIFIED
FOR DATE OF 670121 THERE ARE
FOR DATE OF 570124 THERE ARE
FOR DATE OF 670123 THERE ARE
FOR DATE OF 670126 THERE ARE
FOR DATE OF 670127 THERE ARE
FOR DATE OF 670128 THERE ARE
FOR DATE OF 670129 THERE ARE
FOR DATE OF 670131 THERE ARE
FOR DATE OF 570203 THERE ARE
FOR DATE OF 670205 THERE ARE
FOR DATE OF 670206 THERE ARE
FOR DATE OF 670210 THERE ARE
FOR DATE OF 670211 THERE ARE
FOR DATE OF 670212 THERE ARE
FOR DATE OF 670213 THERE ARE
FOR DATE OF 670214 THERE ARE
FOR DATE OF 670216 THERE ARE
FOR DATE OF 670218 THERE ARE
FOR DATE OF 670219 THERE ARE
FOR DATE OF 670220 THERE ARE
FOR DATE OF 670222 THERE ARE
FOR DATE OF 670223 THERE ARE
FOR DATE OF 670224 THERE ARE
FOR DATE OF 670225 THERE ARE
FOR DATE OF 670301 THERE ARE
FOR DATE OF 670304 THERE ARE
FOR DATE OF 670306 THERE ARE
FOR DATE OF 670309 THERE ARE
FOR DATE OF 670312 THERE ARE
FOR DATE OF 670313 THERE ARE
FOR DATE OF 670314 THERE ARE
FOR DATE OF 67031S THERE ARE
FOR DATE OF 670316 THERE ARE
FOR DATE OF 670317 THERE ARE
FOR DATE OF 670318 THERE ARE
FOR DATE OF 670319 THERE ARE
FOR DATE OF 670320 THERE ARE
FOR DATE OF 670321 THERE ARE
' FOR DATE OF 670324 THERE ARE
FOR DATE OF 670328 THERE ARE
FOR DATE OF 670329 THERE ARE
FOR DATE OF 670331 THERE ARE
FOR DATE OF 670407 THERE ARE
FOR DATE OF 670408 THERE ARE
FOR DATE OF 670412 THERE ARE
FOR DATE OF 670414 THERE ARE
FOR DATE OF 670415 THERE ARE
FOR DATE OF 670416 THERE ARE
FOR DATE OF 670420 THERE ARE
FOR DATE OF 670421 THERE ARE
FOR DATE OF 670422 THERE ARE
FOR DATE OF 670423 THERE ARE
FOR DATE OF 670424 THERE ARE
FOR DATE OF 670428 THERE ARE
FOR DATE OF 670501 THERE ARE
FOR DATE OF 670504 THERE ARE
FOR DATE OF 670S05 THERE ARE
FOR DATE OF 670506 THERE ARE
FOR DATE OF 670511 THERE ARE
FOR DATE OF 670512 THERE ARE
FOR DATE OF 670513 THERE ARE
FOR DATE OF 670515 THERE ARE
FOR DATE OF 670516 THERE ARE
FOR DATE OF 670521 THERE ARE
FOR DATE OF 670522 THERE ARE
FOR DATE OF 670524 THERE ARE
9
4
7
3
5
4
2
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
2 RECORDS.
4 RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
2 RECORDS.
1 RECORDS.
12 RECORDS.
3 RECORDS.
2 RECORDS.
3 RECORDS.
3 RECORDS.
3 RECORDS.
7 RECORDS.
3 RECORDS.
3 RECORDS.
3 RECORDS.
7 RECORDS.
3 RECORDS.
3 RECORDS.
6 RECORDS.
1 RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
2 RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
3 RECORDS.
3 RECORDS.
5 RECORDS.
2 RECORDS.
2 RECORDS.
1 RECORDS.
5 RECORDS.
2 RECORDS.
3 RECORDS.
2 RECORDS.
1 RECORDS.
14 RECORDS.
1 RECORDS.
1 RECORDS.
6 RECORDS.
1 RECORDS.
UNCLASSIFIED
Page 64
�UNCLASSIFIED
FOR DATE OF 670525 THERE ARE
;
FOR DATE OF 670526 THERE ARE
: ARE
FOR DATE OF 670530 THERE ARE
I ARE
FOR DATE OF 670531 Ti
; ARE
FOR DATE OF 670601 THERE ARE
: ARE
FOR DATE OF 670602 THERE ARE
: ARE
FOR DATE OF 670603 THERE: ARE
FOR DATE OF 670604 THERE ARE
: ARE
FOR DATE OF 670605 THERE: ARE
FOR DATE OF 6 0 0 THERE ARE
766
FOR DATE OF 670607 THERE ARE
FOR DATE OF 6 0 0 THERE: ARE
768
FOR DATE OF 670609 THERE ARE
FOR DATE OF 670610 THERE ARE
FOR DATE OF 670611 THERE ARE
FOR DATE OF 670613 THERE ARE
FOR DATE OF 670615 THERE ARE
FOR DATE OF 670616 THERE ARE
FOR DATE OF 670617 THERE ARE
FOR DATE OF 670618 THERE ARE
FOR DATE OF 670619 THERE ARE
FOR DATE OF 670621 THERE ARE
FOR DATE OF 670622 THERE ARE
FOR DATE OF 670626 THERE ARE
FOR DATE OF 670627 THERE ARE
FOR DATE OF 670628 THERE ARE
FOR DATE OF 670629 THERE ARE
FOR DATE OF 670630 THERE ARE
FOR DATE OF 670701 THERE ARE
FOR DATE OF 670702 THERE ARE
FOR DATE OF 670703 THERE ARE
FOR DATE OF 670704 THERE ARE
FOR DATE OF 670705 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
776
FOR DATE OF 6 0 0 THERE ARE
777
FOR DATE OF 670711 THERE ARE
FOR DATE OF 670714 THERE ARE
FOR DATE OF 670715 THERE ARE
FOR DATE OF 670716 THERE ARE
FOR DATE OF 67Q717 THERE ARE
FOR DATE OF 670718 THERE ARE
FOR DATE OF 670719 THERE ARE
FOR DATE OF 670720 THERE ARE
FOR DATE OF 670721 THERE ARE
FOR DATE OF 670722 THERE ARE
FOR DATE OF 670723 THERE ARE
FOR DATE OF 670724 THERE ARE
FOR DATE OF 670725 THERE ARE
FOR DATE OF 670726 THERE ARE
FOR DATE OF 670727 THERE ARE
FOR DATE OF 670728 THERE ARE
FOR DATE OF 670729 THERE ARE
FOR DATE OF 670730 THERE ARE
FOR DATE OF 670801 THERE ARE
FOR DATE OF 670820 THERE ARE
FOR DATE OF 670821 THERE ARE
FOR DATE OF 670826 THERE ARE
FOR DATE OF 670830 THERE ARE
FOR DATE OF 670831 THERE ARE
FOR DATE OF 670905 THERE ARE
FOR DATE OF 670907 THERE ARE
FOR DATE OF 670908 THERE ARE
FOR DATE OF 670912 THERE ARE
FOR DATE OF 670913 THERE ARE
FOR DATE OF 670915 THERE ARE
FOR DATE OF 670922 THERE ARE
1 RECORDS.
9 RECORDS.
4 RECORDS.
1 RECORDS.
3 RECORDS.
7 RECORDS.
4 RECORDS.
2 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
1 RECORDS.
1 RECORDS.
8 RECORDS.
1 RECORDS.
2 RECORDS.
6 RECORDS.
1 RECORDS.
3 RECORDS.
1 RECORDS.
5 RECORDS.
2 RECORDS.
6 RECORDS.
5 RECORDS.
3 RECORDS.
3 RECORDS.
6 RECORDS.
8 RECORDS.
6 RECORDS.
3 RECORDS.
2 RECORDS.
3 RECORDS.
2 RECORDS.
1 RECORDS.
2 RECORDS.
7 RECORDS.
2 RECORDS.
2 RECORDS.
3 RECORDS.
3 RECORDS.
6 RECORDS.
3 RECORDS.
5 RECORDS.
5 RECORDS.
3 RECORDS.
3 RECORDS.
4 RECORDS.
3 RECORDS.
3 RECORDS.
3 RECORDS.
3 RECORDS.
3 RECORDS.
3 RECORDS.
6 RECORDS.
1 RECORDS.
2 RECORDS.
4 RECORDS.
2 RECORDS.
2 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
1 RECORDS.
2 RECORDS.
5 RECORDS.
UNCLASSIFIED
Page 65
�UNCLASSIFIED
FOR DATE OF 670925 THERE ARE
FOR DATE OF 670927 THERE ARE
FOR DATE OF 670928 THERE ARE
FOR DATE OF 67092S THERE ARE
FOR DATE OF 670930 THERE ARE
FOR DATE OF 671001 THERE ARE
FOR DATE OF 671003 THERE ARE
FOR DATE OF 671004 THERE ARE
FOR DATE OF 67100S THERE ARE
FOR DATE OF 671006 THERE ARE
FOR DATE OF 671007 THERE ARE
FOR DATE OF 671009 THERE ARE
FOR DATE OF 671010 THERE ARE
FOR DATE OF 671011 THERE ARE
FOR DATE OF 671012 THERE ARE
FOR DATE OF 671013 THERE ARE
FOR DATE OF 671014 THERE ARE
FOR DATE OF 671015 THERE ARE
FOR DATE OF 671020 THERE ARE
FOR DATE OF 671021 THERE ARE
FOR DATE OF 671023 THERE ARE
FOR DATE OF 671024 THERE ARE
FOR DATE OF 67102S THERE ARE
FOR DATE OF 671027 THERE ARE
FOR DATE OF 671029 THERE ARE
FOR DATE OF 671030 THERE ARE
FOR DATE OF 671103 THERE ARE
FOR DATE OF 6711O4 THERE ARE
FOR DATE OF 671106 THERE ARE
FOR DATE OF 671107 THERE ARE
FOR DATE OF 671108 THERE ARE
FOR DATE OF 671109 THERE ARE
FOR DATE OF 671111 THERE ARE
FQR DATE OF 671112 THERE ARE
FOR DATE OF 671113 THERE ARE
FOR DATE OF 671114 THERE ARE
FOR DATE OF 671115 THERE ARE
FOR DATE OF 671116 THERE ARE
FOR DATE OF 671117 THERE ARE
FOR DATE OF 671118 THERE ARE
FOR DATE OF 671119 THERE ARE
FOR DATE OF 671120 THERE ARE
FOR DATE OF 671121 THERE ARE
FOR DATE OF 671122 THERE ARE
FOR DATE OF 671124 THERE ARE
FOR DATE OF 671127 THERE ARE
FOR DATE OF 671130 THERE ARE
FOR DATE OF 671204 THERE ARE
FOR DATE OF 571210 THERE ARE
FOR DATE OF 671211 THERE ARE
FOR DATE OF 671213 THERE ARE
FOR DATE OF 671223 THERE ARE
FOR DATE OF 671226 THERE ARE
FOR DATE OF 671230 THERE ARE
FOR DATE OF 680101 THERE ARE
FOR DATE OF 680102 THERE ARE
FOR DATE OF 680103 THERE ARE
FOR DATE OF 680104 THERE ARE
FOR DATE OF 680106 THERE ARE
FOR DATE OF 680109 THERE ARE
FOR DATE OF 680111 THERE ARE
FOR DATE OF 680112 THERE ARE
FOR DATE OF 680114 THERE ARE
FOR DATE OF 680116 THERE ARE
FOR DATE OF 680124 THERE ARE
FOR DATE OF 680129 THERE ARE
3 RECORDS.
6 RECORDS.
1 RECORDS.
5 RECORDS.
5 RECORDS.
5 RECORDS.
6 RECORDS.
8 RECORDS.
3 RECORDS.
4 RECORDS.
9 RECORDS.
28 RECORDS.
12 RECORDS.
3 RECORDS.
4 RECORDS.
3 RECORDS.
3 RECORDS.
1 RECORDS.
3 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
5 RECORDS.
3 RECORDS.
1 RECORDS.
2 RECORDS.
4 RECORDS.
6 RECORDS.
9 RECORDS.
4 RECORDS.
2 RECORDS.
1 RECORDS.
9 RECORDS.
9 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
1 RECORDS.
1 RECORDS.
4 RECORDS.
1 RECORDS.
2 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
7 RECORDS.
10 RECORDS.
3 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
18 RECORDS.
1 RECORDS.
3 RECORDS.
1 RECORDS.
3 RECORDS.
2 RECORDS.
UNCLASSIFIED
Page 66
�UNCLASSIFIED
FOR DATE OF 680130 THERE ARE
FOR DATE OF 680201 THERE ARE
FOR DATE OF 680204 THERE ARE
FOR DATE OF 680208 THERE ARE
FOR DATE OF 680209 THERE ARE
FOR DATE OF 680216 THERE ARE
FOR DATE OF 680218 THERE ARE
FOR DATE OF 680222 THERE ARE
FOR DATE OF 680308 THERE ARE
FOR DATE OF 680320 THERE ARE
FOR DATE OF 680322 THERE ARE
FOR DATE OF 680327 THERE ARE
FOR DATE OF 680407 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
848
FOR DATE OF 680411 THERE ARE
FOR DATE OF 630413 THERE ARE
FOR DATE OF 680421 THERE ARE
FOR DATE OF 680422 THERE ARE
FOR DATE OF 680423 THERE ARE
FOR DATE OF 680424 THERE ARE
FOR DATE OF 680426 THERE ARE
FOR DATE OF 680S02 THERE ARE
FOR DATE OF 680505 THERE ARE
FOR DATE OF 680506 THERE ARE
FOR DATE OF 680508 THERE ARE
FOR DATE OF 680509 THERE ARE
FOR DATE OF 680511 THERE ARE
FOR DATE OF 680516 THERE ARE
FOR DATE OF 680519 THERE ARE
FOR DATE OF 680520 THERE ARE
FOR DATE OF 680521 THERE ARE
FOR DATE OF 680522 THERE ARE
FOR DATE OF 680523 THERE ARE
FOR DATE OF 680524 THERE ARE
FOR DATE OF 680526 THERE ARE
FOR DATE OF 680527 THERE ARE
FOR DATE OF 680528 THERE ARE
FOR DATE OF 680530 THERE ARE
FOR DATE OF 680531 THERE ARE
FOR DATE OF 680601 THERE ARE
FOR DATE OF 680602 THERE ARE
FOR DATE OF 680603 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
864
FOR DATE OF 680605 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
866
FOR DATE OF 680607 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
868
FOR DATE OF 6 0 0 THERE ARE
869
FOR DATE OF 680610 THERE ARE
FOR DATE OF 680611 THERE ARE
FOR DATE OF 680612 THERE ARE
FOR DATE OF 680613 THERE ARE
FOR DATE OF 680614 THERE ARE
FOR DATE OF 680615 THERE ARE
FOR DATE OF 680618 THERE ARE
FOR DATE OF 680619 THERE ARE
FOR DATE OF 680622 THERE ARE
FOR DATE OF 680623 THERE ARE
FOR DATE OF 680624 THERE ARE
FOR DATE OF 6B0625 THERE ARE
FOR DATE OF 680626 THERE ARE
FOR DATE OF 680627 THERE ARE
FOR DATE OF 680628 THERE ARE
FOR DATE OF 680629 THERE ARE
FOR DATE OF 680630 THERE ARE
FOR DATE OF 680701 THERE ARE
2
1
2
2
4
1
7
4
6
1
1
1
6
2
8
2
2
4
2
4
12
3
1
9
2
1
5
1
2
4
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
2'RECORDS.
2
3
9
12
8
3
3
8
6
2
6
1
3
7
5
11
2
6
6
1
2
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
UNCLASSIFIED
Page 67
�UNCLASSIFIED
FOR DATE OF 680702 THERE ARE
FOR DATE OF 680703 THERE ARE
FOR DATE OF 680704 THERE ARE
FOR DATE OF 680705 THERE ARE
FOR DATE OF 680706 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
879
FOR DATE OF 680710 THERE ARE
FOR DATE OF 680711 THERE ARE
FOR DATE OF 680712 THERE ARE
FOR DATg OF 680713 THERE ARE
FOR DATE OF 680714 THERE ARE
FOR DATE OF 680715 THERE ARE
FOR DATE OF 680716 THERE ARE
FOR DATE OF 680717 THERE ARE
FOR DATE OF 680718 THERE ARE
FOR DATE OF 680719 THERE ARE
FOR DATE OF 680720 THERE ARE
FOR DATE OF 680721 THERE ARE
FOR DATE OF 680722 THERE ARE
FOR DATE OF 680723 THERE ARE
FOR DATE OF 680724 THERE ARE
FOR DATE OF 680725 THERE ARE
FOR DATE OF 680726 THERE ARE
FOR DATE OF 680727 THERE ARE
FOR DATE OF 680728 THERE ARE
FOR DATE OF 680729 THERE ARE
FOR DATE OF 680730 THERE ARE
FOR DATE OF 680731 THERE ARE
FOR DATE OF 680801 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
882
FOR DATE OF 68O803 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
884
FOR DATE OF 680805 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
886
FOR DATE OF 680811 THERE ARE
FOR DATE OF 680812 THERE ARE
FOR DATE OF 680813 THERE ARE
FOR DATE OF 680814 THERE ARE
FOR DATE OF 680821 THERE ARE
FOR DATE OF 680823 THERE ARE
FOR DATE OF 680826 THERE ARE
FOR DATE OF 680828 THERE ARE
FOR DATE OF 680830 THERE ARE
FOR DATE OF 680831 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
894
FOR DATE OF 6 0 0 THERE ARE
895
FOR DATE OF 6 0 0 THERE ARE
896
FOR DATE OF 6 0 0 THERE ARE
897
FOR DATE OF 6 0 0 THERE ARE
898
FOR DATE OF 6 0 0 THERE ARE
899
FOR DATE OF 680910 THERE ARE
FOR DATE OF 680911 THERE ARE
FOR DATE OF 680913 THERE ARE
FOR DATE OF 680914 THERE ARE
FOR DATE OF 680915 THERE ARE
FOR DATE OF 680916 THERE ARE
FOR DATE OF 680917 THERE ARE
FOR DATE OF 680918 THERE ARE
FOR DATE OF 680919 THERE ARE
FOR DATE OF 680920 THERE ARE
FOR DATE OF 680921 THERE ARE
FOR DATE OF 68O922 THERE ARE
FOR DATE OF 680924 THERE ARE
FOR DATE OF 680925 THERE ARE
FOR DATE OF 6 0 2 THERE ARE
896
FOR DATE OF 680929 THERE ARE
5 RECORDS.
14 RECORDS.
8 RECORDS.
4 RECORDS,
7 RECORDS.
8 RECORDS.
13 RECORDS.
8 RECORDS.
7 RECORDS.
10 RECORDS.
11 RECORDS.
5 RECORDS.
4 RECORDS.
6 RECORDS.
8 RECORDS.
10 RECORDS.
6 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
1 RECORDS.
5 RECORDS.
11 RECORDS.
4 RECORDS.
6 RECORDS.
7 RECORDS.
4 RECORDS.
4 RECORDS.
11 RECORDS.
1 RECORDS.
3 RECORDS.
4 RECORDS.
9 RECORDS.
2 RECORDS.
3 RECORDS.
1 RECORDS.
7 RECORDS.
4 RECORDS.
4 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
3 RECORDS.
2 RECORDS.
6 RECORDS.
1 RECORDS.
7 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
1 RECORDS.
1 RECORDS.
5 RECORDS.
2 RECORDS.
4 RECORDS.
3 RECORDS.
3 RECORDS.
2 RECORDS.
1 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
3 RECORDS.
20 RECORDS.
3 RECORDS.
UNCLASSIFIED
Page 68
�UNCLASSIFIED
FOR DATE OF 680930 THERE ARE
: ARE
FOR DATE OF 661002 THEREi ARE
FOR DATE OF 681003 THERE ARE
: ARE
FOR DATE OF 681004 THERE: ARE
FOR DATE OF 681003 THERE ARE
FOR DATE OF 681006 Tl
: ARE
FOR DATE OF 681007 THERE ARE
FOR DATE OF 681014 THERE ARE
FOR DATE OF 681016 THERE: ARE
FOR DATE OF 681017 THERE ARE
FOR DATE OF 681018 THERE ARE
FOR DATE OF 681019 THERE ARE
FOR DATE OF 681021 THERE ARE
FOR DATE OF 681022 THERE ARE
FOR DATE OF 681023 THERE ARE
FOR DATE OF 681024 THERE ARE
FOR DATE OF 681025 THERE ARE
FOR DATE OF 681026 THERE ARE
FOR DATE OF 681027 THERE ARE
FOR DATE OF 681028 THERE ARE
FOR DATE OF 681029 THERE ARE
FOR DATE OF 681030 THERE ARE
FOR DATE OF 681031 THERE ARE
FOR DATE OF 681101 THERE ARE
FOR DATE OF 681103 THERE ARE
FOR DATE OF 681104 THERE ARE
FOR DATE OF 681106 THERE ARE
FOR DATE OF 681106 THERE ARE
FOR DATE OF 681107 THERE ARE
FOR DATE OF 681108 THERE ARE
FOR DATE OF 6811O9 THERE ARE
FOR DATE OF 681110 THERE ARE
FOR DATE OF 681111 THERE ARE
FOR DATE OF 681112 THERE ARE
FOR DATE OF 681113 THERE ARE
FOR DATE OF 681114 THERE ARE
FOR DATE OF 681115 THERE ARE
FOR DATE OF 681116 THERE ARE
FOR DATE OF 681117 THERE ARE
FOR DATE OF 681118 THERE ARE
FOR DATE OF 681119 THERE ARE
FOR DATE OF 681122 THERE ARE
FOR DATE OF 681126 THERE ARE
FOR DATE OF 681127 THERE ARE
FOR DATE OF 681128 THERE ARE
FOR DATE OF 681129 THERE ARE
FOR DATE OF 681130 THERE ARE
FOR DATE OF 681201 THERE ARE
FOR DATE OF 681202 THERE ARE
FOR DATE OF 681203 THERE ARE
FOR DATE OF 681204 THERE ARE
FOR DATE OF 681205 THERE ARE
FOR DATE OF 681207 THERE ARE
FOR DATE OF 681208 THERE ARE
FOR DATE OF 681209 THERE ARE
FOR DATE OF 681210 THERE ARE
FOR DATE OF 681211 THERE ARE
FOR DATE OF 681215 THERE ARE
FOR DATE OF 681217 THERE ARE
FOR DATE OF 681218 THERE ARE
FOR DATE OF 681219 THERE ARE
FOR DATE OF 681220 THERE ARE
FOR DATE OF 681223 THERE ARE
FOR DATE OF 681226 THERE ARE
FOR DATE OF 681227 THERE ARE
FOR DATE OF 681228 THERE ARE
2 RECORDS.
5 RECORDS.
2 RECORDS.
1 RECORDS.
2 RECORDS.
1 RECORDS.
4 RECORDS.
6 RECORDS.
4 RECORDS.
7 RECORDS.
1 RECORDS.
6 RECORDS.
12 RECORDS.
7 RECORDS.
8 RECORDS.
16 RECORDS.
10 RECORDS.
10 RECORDS.
6 RECORDS.
1 RECORDS.
8 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
1 RECORDS.
4 RECORDS.
7 RECORDS.
3 RECORDS.
5 RECORDS.
2 RECORDS.
2 RECORDS.
6 RECORDS.
2 RECORDS.
1 RECORDS.
5 RECORDS.
4 RECORDS.
5 RECORDS.
5 RECORDS.
3 RECORDS.
6 RECORDS.
1 RECORDS.
16 RECORDS.
17 RECORDS.
1 RECORDS.
5 RECORDS.
1 RECORDS.
3 RECORDS.
1 RECORDS.
4 RECORDS.
6 RECORDS.
1 RECORDS.
1 RECORDS.
15 RECORDS.
27 RECORDS.
15 RECORDS.
13 RECORDS.
1 RECORDS.
6 RECORDS.
15 RECORDS.
15 RECORDS.
3 RECORDS.
6 RECORDS.
3 RECORDS.
1 RECORDS.
5 RECORDS.
2 RECORDS.
UNCLASSIFIED
Page 69
�UNCLASSIFIED
FOR DATE OF 690103 THERE ARE
FOR DATE OF 690106 THERE ARE
FOR DATE OF 690107 THERE ARE
FOR DATE OF 690108 THERE ARE
FOR DATE OF 690109 THERE ARE
FOR DATE OF 690110 THERE ARE
FOR DATE OF 690111 THERE ARE
FOR DATE OF 690112 THERE ARE
FOR DATE OF 690114 THERE ARE
FOR DATE OF 690115 THERE ARE
FOR DATE OF 690116 THERE ARE
FOR DATE OF 690117 THERE ARE
FOR DATE OF 690118 THERE ARE
FOR DATE OF 690119 THERE ARE
FOR DATE OF 690120 THERE ARE
FOR DATE OF 690121 THERE ARE
FOR DATE OF 690122 THERE ARE
FOR DATE OF 690123 THERE ARE
FOR DATE OF 690124 THERE ARE
FOR DATE OF 690125 THERE ARE
FOR DATE OF 690126 THERE ARE
FOR DATE OF 690127 THERE ARE
FOR DATE OF 690128 THERE ARE
FOR DATE OF 690129 THERE ARE
FOR DATE OF 690131 THERE ARE
FOR DATE OF 690201 THERE ARE
FOR DATE OF 690202 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
926
FOR DATE OF 690207 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
928
FOR DATE OF 6 0 0 THERE ARE
929
FOR DATE OF 690210 THERE ARE
FOR DATE OF 690211 THERE ARE
FOR DATE OF 690212 THERE ARE
FOR DATE OF 690213 THERE ARE
FOR DATE OF 690214 THERE ARE
FOR DATE OF 690215 THERE ARE
FOR DATE OF 690216 THERE ARE
FOR DATE OF 690217 THERE ARE
FOR DATE OF 690218 THERE ARE
FOR DATE OF 690219 THERE ARE
FOR DATE OF 690220 THERE ARE
FOR DATE OF 690221 THERE ARE
FOR DATE OF 690222 THERE ARE
FOR DATE OF 690227 THERE ARE
FOR DATE OF 690302 THERE ARE
FOR DATE OF 690303 THERE ARE
FOR DATE OF 6903O4 THERE ARE
FOR DATE OF 690305 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
936
FOR DATE OF 690307 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
938
FOR DATE OF 6 0 0 THERE ARE
939
FOR DATE OF 690310 THERE ARE
FOR DATE OF 690312 THERE ARE
FOR DATE OF 690313 THERE ARE
FOR DATE OF 690314 THERE ARE
FOR DATE OF 690315 THERE ARE
FOR DATE OF 690316 THERE ARE
FOR DATE OF 690317 THERE ARE
FOR DATE OF 690318 THERE ARE
FOR DATE OF 690319 THERE ARE
FOR DATE OF 690320 THERE ARE
FOR DATE OF 690321 THERE ARE
FOR DATE OF 6 0 2 THERE ARE
932
FOR DATE OF 690323 THERE ARE
9 RECORDS.
23 RECORDS.
20 RECORDS.
18 RECORDS.
18 RECORDS.
18 RECORDS.
18 RECORDS.
1 RECORDS.
9 RECORDS.
1 RECORDS.
2 RECORDS.
25 RECORDS.
3 RECORDS.
1 RECORDS.
12 RECORDS.
15 RECORDS.
13 RECORDS.
16 RECORDS.
12 RECORDS.
12 RECORDS.
12 RECORDS.
6 RECORDS.
13 RECORDS.
12 RECORDS.
1 RECORDS.
2 RECORDS.
3 RECORDS.
1 RECORDS.
1 RECORDS.
22 RECORDS.
22 RECORDS.
15 RECORDS.
17 RECORDS.
30 RECORDS.
24 RECORDS.
31 RECORDS.
30 RECORDS.
8 RECORDS.
8 RECORDS.
9 RECORDS.
8 RECORDS.
8 RECORDS.
4 RECORDS.
1 RECORDS.
1 RECORDS.
3 RECORDS.
5 RECORDS.
6 RECORDS.
1 RECORDS.
3 RECORDS.
2 RECORDS.
2 RECORDS.
4 RECORDS.
6 RECORDS.
8 RECORDS.
14 RECORDS.
13 RECORDS.
17 RECORDS.
21 RECORDS.
1 RECORDS.
3 RECORDS.
2 RECORDS.
1 RECORDS.
2 RECORDS.
3 RECORDS.
5 RECORDS.
UNCLASSIFIED
Page 70
�UNCLASSIFIED
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR..DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
OF
690324 THERE ARE
• ARE
; ARE
690325 THERE ARE
690326 THERE ARE
• ARE
690327 THERE ARE
•
690328 THERE: ARE
690329 THERE! ARE
690331' THERE: ARE
ARE
690401 Tl
; ARE
690402 THERE ARE
; ARE
690403 THERE: ARE
690404 THERE: ARE
6 0 0 THERE: ARE
947
ARE
690408 THERE ARE
6 0 0 THERE ARE
949
690411 THERE ARE
690412 THERE ARE
690414 THERE ARE
690415 THERE ARE
690416 THERE ARE
690417 THERE ARE
690418 THERE ARE
690419 THERE ARE
690420 THERE ARE
690421 THERE ARE
690422 THERE ARE
690423 THERE ARE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR DATE
FOR'DATE
FOR DATE
OF
OF
OF
OF
OF
OF
OF
690424
690425
690426
690427
690428
590429
690430
THERE
THERE
THERE
THERE
THERE
THERE
THERE
ARE
ARE
ARE
ARE
ARE
ARE
ARE
ARE
DATE OF 690502 THERE ARE
DATE OF 690505 THERE ARE
DATE OF 690507 THERE ARE
DATE OF 6 0 0 THERE ARE
9S8
DATE OF 690510 THERE ARE
DATE OF 690511 THERE ARE
DATE OF 690512 THERE ARE
DATE OF 690513 THERE ARE
DATE OF 690514 THERE ARE
DATE OF 690515 THERE ARE
DATE Of 690516 THERE ARE
DATE OF 690517 THERE ARE
DATE OF 690519 THERE ARE
DATE OF 690520 THERE ARE
DATE OF 690521 TH
ARE
DATE OF 690522 THERE ARE
DATE OF 690523 THERE ARE
DATE OF 69O524 THERE ARE
DATE OF 690525 THERE ARE
DATE OF 690526 THERE ARE
DATE OF 690527 THERE ARE
DATE OF 690S28 THERE ARE
DATE OF 690529 THERE ARE
DATE OF 690530 THERE ARE
DATE OF 690531 THERE ARE
DATE OF 690602 THERE ARE
DATE OF 6 0 0 THERE ARE
963
DATE OF 6 0 0 THERE ARE
964
DATE OF 6 0 0 THERE ARE
965
DATE OF 6 0 0 THERE ARE
966
DATE OF 6 0 0 THERE ARE
967
DATE OF 6 0 0 THERE ARE
968
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR DATE OF 690610 THERE ARE
2 RECORDS.
2 RECORDS.
3 RECORDS.
7 RECORDS.
5 RECORDS.
1 RECORDS.
1 RECORDS.
3 RECORDS.
15 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
1 RECORDS.
1 RECORDS.
3 RECORDS.
3 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
5 RECORDS.
7 RECORDS.
9 RECORDS.
4 RECORDS.
6 RECORDS.
6 RECORDS.
11 RECORDS.
12 RECORDS.
12 RECORDS.
14 RECORDS.
5 RECORDS.
3 RECORDS.
3 RECORDS.
1 RECORDS.
4 RECORDS.
14 RECORDS.
9 RECORDS.
1 RECORDS.
3 RECORDS.
12 RECORDS.
6 RECORDS.
1 RECORDS.
3 RECORDS.
5 RECORDS.
3 RECORDS.
1 RECORDS.
11 RECORDS.
1 RECORDS.
4 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
4 RECORDS.
1 RECORDS.
6 RECORDS.
4 RECORDS.
1 RECORDS.
1 RECORDS.
13 RECORDS.
1
2
6
2
2
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
4 RECORDS.
4 RECORDS.
UNCLASSIFIED
Page 71
�UNCLASSIFIED
FOR DATE OF 690611 THERE ARE
FOR DATE OF 690612 THERE ARE
FOR DATE OF 690613 THERE ARE
. FOR DATE OF 690615 THERE ARE
FOR DATE OF 690616 THERE ARE
FOR DATE OF 690617 THERE ARE
FOR DATE OF 690618 THERE ARE
FOR DATE OF 690620 THERE ARE
FOR DATE OF 690621 THERE ARE
FOR DATE OF 690622 THERE ARE
FOR DATE OF 690623 THERE ARE
FOR DATE OF 690624 THERE ARE
FOR DATE OF 690625 THERE ARE
FOR DATE OF 690626 THERE ARE
FOR DATE OF 690627 THERE ARE
FOR DATE OF 690628 THERE ARE
FOR DATE OF 690629 THERE ARE
FOR DATE OF 690630 THERE ARE
FOR DATE OF 690701 THERE ARE
FOR DATE OF 690702 THERE ARE
FOR DATE OF 690703 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
974
FOR DATE OF 690705 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
976
FOR DATE OF 690707 THERE ARE
FOR DATE OF 690708 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
979
FOR DATE OF 690710 THERE ARE
FOR DATE OF 690712 THERE ARE
FOR DATE OF 690714 THERE ARE
FOR DATE OF 690717 THERE ARE
FOR DATE OF 690718 THERE ARE
FOR DATE OF 690719 THERE ARE
FOR DATE OF 690721 THERE ARE
FOR DATE OF 690722 THERE ARE
FOR DATE OF 690724 THERE ARE
FOR DATE OF 690729 THERE ARE
FOR DATE OF 690730 THERE ARE
FOR DATE OF 690731 THERE ARE
FOR DATE OF 690801 THERE ARE
FOR DATE OF 690802 THERE ARE
FOR DATE OF 690803 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
984
FOR DATE Of 690805 THERE ARE
FOR DATE OF 6 0 0 THERE ARE
986
FOR DATE OF 6 0 0 THERE ARE
987
FOR DATE OF 6 0 0 THERE ARE
988
FOR DATE OF 6 0 0 THERE ARE
989
FOR DATE OF 690810 THERE ARE
FOR DATE OF 690811 THERE ARE
FOR DATE OF 690812 THERE ARE
FOR DATE OF 690813 THERE ARE
FOR DATE OF 690815 THERE ARE
FOR DATE OF 690816 THERE ARE
FOR DATE OF 690817 THERE ARE
FOR DATE OF 690818 THERE ARE
FOR DATE OF 690820 THERE ARE
FOR DATE OF 690821 THERE ARE
FOR DATE OF 690822 THERE ARE
FOR DATE OF 690823 THERE ARE
FOR DATE OF 690825 THERE ARE
FOR DATE OF 6 0 2 THERE ARE
986
FOR DATE OF 690827 THERE ARE
FOR DATE OF 690828 THERE ARE
FOR DATE OF 690829 THERE ARE
FOR DATE OF 690830 THERE ARE
2 RECORDS.
1 RECORDS.
8 RECORDS.
12 RECORDS..
15 RECORDS.
5 RECORDS.
15 RECORDS.
1 RECORDS.
21 RECORDS.
16 RECORDS.
19 RECORDS.
19 RECORDS.
22 RECORDS.
17 RECORDS.
18 RECORDS.
20 RECORDS.
25 RECORDS.
16 RECORDS.
12 RECORDS.
8 RECORDS.
7 RECORDS.
1 RECORDS.
9 RECORDS.
6 RECORDS.
14 RECORDS.
6 RECORDS.
15 RECORDS.
6 RECORDS.
5 RECORDS.
4 RECORDS.
3 RECORDS.
10 RECORDS.
3 RECORDS.
7 RECORDS.
1 RECORDS.
3 RECORDS.
2 RECORDS.
2 RECORDS.
7 RECORDS.
23 RECORDS.
7 RECORDS.
9 RECORDS.
14 RECORDS.
17 RECORDS.
6 RECORDS.
7 RECORDS.
13 RECORDS.
1 RECORDS.
8 RECORDS.
1 RECORDS.
5 RECORDS.
5 RECORDS.
7 RECORDS.
4 RECORDS.
7 RECORDS.
7 RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
9 RECORDS.
4 RECORDS.
2 RECORDS.
1 RECORDS.
4 RECORDS.
6 RECORDS.
UNCLASSIFIED
Page 72
�UNCLASSIFIED
FOR DATE OF 590831 Tl
; ARE
FOR DATE OF 690901 Tl
: ARE
FOR DATE OF 690902 THERE ARE
: ARE
FOR DATE OF 690903 Tl
: ARE
FOR DATE OF 690904 THERE: ARE
ARE
FOR DATE OF 690905 THERE: ARE
ARE
FOR DATE OF 690906 THERE ARE
FOR DATE OF 690907 THERE ARE
FOR DATE OF 690908 THERE ARE
FOR DATE OF 690910 THERE ARE
FOR DATE OF 690912 THERE ARE
FOR DATE OF 690913 THERE ARE
FOR DATE OF 690915 THERE ARE
FOR DATE OF 690919 THERE ARE
FOR DATE OF 690920 THERE ARE
FOR DATE OF 690921 THERE ARE
FOR DATE OF 690922 THERE ARE
FOR DATE OF 6 0 2 THERE ARE
993
FOR DATE OF 690924 THERE ARE
FOR DATE OF 690925 THERE ARE
FOR DATE OF 690926 THERE ARE
FOR DATE OF 690927 THERE ARE
FOR DATE OF 690928 THERE ARE
FOR DATE OF 69O930 THERE ARE
FOR DATE OF 691001 THERE ARE
FOR DATE OF 691002 THERE ARE
FOR DATE OF 691003 THERE ARE
FOR DATE OF 691004 THERE ARE
FOR DATE OF 691006 THERE ARE
FOR DATE OF 691008 THERE ARE
FOR DATE OF 691009 THERE ARE
FOR DATE OF 691010 THERE ARE
FOR DATE OF 691011 THERE ARE
FOR DATE OF 691012 THERE ARE
FOR DATE OF 691013 THERE ARE
FOR DATE OF 691014 THERE ARE
FOR DATE OF 691015 THERE ARE
FOR DATE OF 691016 THERE ARE
FOR DATE OF 691017 THERE ARE
FOR DATE OF 691018 THERE ARE
FOR DATE OF 691019 THERE ARE
FOR DATE OF 691020 THERE ARE
FOR DATE OF 691021 THERE ARE
FOR DATE OF 691022 THERE ARE
FOR DATE OF 691023 THERE ARE
FOR DATE OF 691024 THERE ARE
FOR DATE OF 691025 THERE ARE
FOR DATE OF 691026 THERE ARE
FOR DATE OF 691027 THERE ARE
FOR DATE OF 691028 THERE ARE
FOR DATE OF 691029 THERE ARE
FOR DATE OF 691030 THERE ARE
FOR DATE OF 691031 THERE ARE
FOR DATE OF 691105 THERE ARE
FOR DATE OF 691107 THERE ARE
FOR DATE OF 691109 THERE ARE
FOR DATE OF 691110 THERE ARE
FOR DATE OF 691111 THERE ARE
FOR DATE OF 691112 THERE ARE
FOR DATE OF 691113 THERE ARE
FOR DATE OF 691114 THERE ARE
FOR DATE OF 691115 THERE ARE
FOR DATE OF 691116 THERE ARE
FOR DATE OF 691117 THERE ARE
FOR DATE OF 691119 THERE ARE
FOR DATE OF 691120 THERE ARE
6 RECORDS.
5 RECORDS.
7 RECORDS.
4 RECORDS.
8 RECORDS.
4 RECORDS.
14 RECORDS.'
5 RECORDS.
1 RECORDS.
1 RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
2 RECORDS.
2 RECORDS.
10 RECORDS.
4 RECORDS.
8 RECORDS.
2 RECORDS.
1 'RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
18 RECORDS.
8 RECORDS.
8 RECORDS.
34 RECORDS.
5 RECORDS.
11 RECORDS.
13 RECORDS.
4 RECORDS.
3 RECORDS.
2 RECORDS.
2 RECORDS.
9 RECORDS.
11 RECORDS.
10 RECORDS.
6 RECORDS.
12 RECORDS.
5 RECORDS.
7 RECORDS.
7 RECORDS.
7 RECORDS.
8 RECORDS.
7 RECORDS.
8 RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
11 RECORDS.
2 RECORDS.
2 RECORDS.
1 RECORDS.
2 RECORDS.
1 RECORDS.
7 RECORDS.
2 RECORDS.
9 RECORDS.
5 RECORDS.
3 RECORDS.
7 RECORDS.
6 RECORDS.
4 RECORDS.
4 RECORDS.
7 RECORDS.
2 RECORDS.
UNCLASSIFIED
Page 73
�UNCLASSIFIED
FOR DATE OF 691121 THERE• ARE
ARE
FOR DATE OF 691124 THERE• ARE
FOR DATE OF 69112S THERE• ARE
ARE
FOR DATE OF 691126 THERE: ARE
FOR DATE OF 691127 THEREI ARE
FOR DATE OF 691123 THERE: ARE
ARE
FOR DATE OF 691129 THERE: ARE
ARE
ARE
FOR DATE OF 691201 THERE: ARE
ARE
FOR DATE OF 691202 THERE: ARE
FOR DATE OF 691203 THERE: ARE
FOR DATE OF 691204 THERE; ARE
FOR DATE OF 691205 THERE ARE
FOR DATE OF 691206 THERE ARE
FOR DATE OF 691207 THERE ARE
FOR DATE OF 691208 THERE ARE
FOR DATE OF 691210 THERE ARE
ARE
FOR DATE OF 691211 THERE ARE
ARE
FOR DATE OF 691213 THERE ARE
, FOR DATE OF 691214 THERE ARE
FOR DATE OF 691219 THERE ARE
FOR DATE OF 691220 THERE ARE
ARE
FOR DATE OF 691221 THERE ARE
ARE
FOR DATE OF 691222 THERE ARE
FOR DATE OF 691223 THERE ARE
ARE
FOR DATE OF 691226 THERE ARE
FOR DATE OF 691227 THERE ARE
FOR DATE OF 691229 THERE ARE
FOR DATE OF 691230 THERE ARE
FOR DATE OF 691231 THERE ARE
FOR DATE OF 700102 THERE ARE
FOR DATE OF 700106 THERE ARE
FOR DATE OF 70016? THERE ARE
FOR DATE OF 700T08 THERE ARE
FOR DATE OF 700111 THERE ARE
FOR DATE OF 700112 THERE ARE
FOR DATE OF 700115 THERE ARE
FOR DATE OF 700116 THERE ARE
FOR DATE OF 700120 THERE ARE
FOR DATE OF 700122 THERE ARE
FOR DATE OF 700125 THERE ARE
FOR DATE OF 700131 THERE ARE
ARE
FOR DATE OF 700201 THERE ARE
FOR DATE OF 700202 THERE ARE
FOR DATE OF 700204 THERE ARE
FOR DATE OF 700205 THERE ARE
FOR DATE OF 700206 THERE ARE
FOR DATE OF 700209 THERE ARE
FOR DATE OF 70021O THERE ARE
FOR DATE OF 700212 THERE ARE
FOR DATE OF 700213 THERE ARE
FOR DATE OF 700215 THERE ARE
FOR DATE OF 700217 THERE ARE
FOR DATE OF 700220 THERE ARE
FOR DATE OF 700221 THERE ARE
FOR DATE OF 700222 THERE ARE
FOR DATE OF 700223 THERE ARE
FOR DATE OF 700224 THERE ARE
FOR DATE OF 700225 THERE ARE
ARE
FOR DATE OF 700226 THERE ARE
FOR DATE OF 700227 THERE ARE
FOR DATE OF 700228 THERE ARE
FOR DATE OF 700301 THERE ARE
FOR DATE OF 700302 THERE ARE
FOR DATE OF 700303 THERE ARE
FOR DATE OF 700305 THERE ARE
FOR DATE OF 700306 THERE ARE
2 RECORDS.
2 RECORDS.
4 RECORDS.
1 RECORDS.
1 RECORDS.
5 RECORDS.
3 RECORDS.
1 RECORDS.
2 RECORDS.
4 RECORDS.
4 RECORDS.
3 RECORDS.
9 RECORDS.
3 RECORDS.
10 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
3 RECORDS.
1 RECORDS.
4 RECORDS.
4 RECORDS.
2 RECORDS.
9 RECORDS.
4 RECORDS.
8 RECORDS.
5 RECORDS.
1 RECORDS.
2 RECORDS.
1 RECORDS.
7 RECORDS.
2 RECORDS.
4 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
8 RECORDS.
8 RECORDS.
12 RECORDS.
8 RECORDS.
1 RECORDS.
11 RECORDS.
1 RECORDS.
2 RECORDS.
5 RECORDS.
1 RECORDS.
4 RECORDS.
2 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
2 RECORDS.
2 RECORDS.
3 RECORDS.
1 RECORDS.
5 RECORDS.
18 RECORDS.
3 RECORDS.
1 RECORDS.
1 RECORDS.
4 RECORDS.
1 RECORDS.
3 RECORDS.
UNCLASSIFIED
Page 74
�UNCLASSIFIED
FOR DATE OF 700307 THERE ARE
FOR DATE OF 700308 THERE ARE
FOR DATE OF 7 0 0 THERE" ARE
039
FOR DATE OF 700310 THERE ARE
FOR DATE OF 700311 THERE ARE
FOR DATE OF 700312 THERE ARE
FOR DATE OF 700313 THERE ARE
FOR DATE OF 700314 THERE ARE
FOR DATE OF 700315 THERE ARE
FOR DATE OF 700316 THERE ARE
FOR DATE OF 700318 THERE ARE
FOR DATE OF 700319 THERE ARE
FOR DATE OF 700320 THERE ARE
FOR DATE OF 700321 THERE ARE
FOR DATE OF 700322 THERE ARE
FOR DATE OF 700323 THERE ARE
FOR DATE OF 700324 THERE ARE
FOR DATE OF 700325 THERE ARE
FOR DATE OF 700326 THERE ARE
FOR DATE OF 700327 THERE ARE
FOR DATE OF 700328 THERE ARE
FOR DATE OF 700329 THERE ARE
FOR DATE OF 700330 THERE ARE
FOR DATE OF 700331 THERE ARE
FOR DATE OF 700401 THERE ARE
FOR DATE OF 700402 THERE ARE
FOR DATE OF 7 0 0 THERE ARE
043
FOR DATE OF 7 0 0 THERE ARE
044
FOR DATE OF 7 0 0 THERE ARE
045
FOR DATE OF 7 0 0 THERE ARE
046
FOR DATE OF 7 0 0 THERE ARE
047
FOR DATE OF 7 0 0 THERE ARE
048
FOR DATE OF 7 0 0 THERE ARE
049
FOR DATE OF 700410 THERE ARE
FOR DATE OF 700412 THERE ARE
FOR DATE OF 700413 THERE ARE
FOR DATE OF 700414 THERE ARE
FOR DATE OF 700416 THERE ARE
FOR DATE OF 700417 THERE ARE
FOR DATE OF 700418 THERE ARE
FOR DATE OF 700419 THERE ARE
FOR DATE OF 700420 THERE ARE
FOR DATE OF 700421 THERE ARE
FOR DATE OF 700425 THERE ARE
FOR DATE OF 700426 THERE ARE
FOR DATE OF 700427 THERE ARE
FOR DATE OF 700428 THERE ARE
FOR DATE OF 700429 THERE ARE
FOR DATE OF 700430 THERE ARE
FOR DATE OF 700431 THERE ARE
FOR DATE OF 700501 THERE ARE
FOR DATE OF 700502 THERE ARE
FOR DATE OF 700503 THERE ARE
FOR DATE OF 700504 THERE ARE
FOR DATE OF 7 0 0 THERE ARE
057
FOR DATE OF 7 0 0 THERE ARE
058
FOR DATE OF 7 0 0 THERE ARE
059
FOR DATE OF 700510 THERE ARE
FOR DATE OF 700513 THERE ARE
FOR DATE OF 700514 THERE ARE
FOR DATE OF 700515 THERE ARE
FOR DATE OF 700517 THERE ARE
FOR DATE OF 700519 THERE ARE
FOR DATE OF 700521 THERE ARE
FOR DATE OF 700522 THERE ARE
FOR DATE OF 700523 THERE ARE
2 RECORDS.
1 RECORDS.
6 RECORDS.
1 RECORDS.
1 RECORDS.
7 RECORDS.
1 RECORDS.
1 RECORDS.
3 RECORDS.
8 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
6 RECORDS.
1 RECORDS.
1 RECORDS.
8 RECORDS.
9 RECORDS.
6 RECORDS.
1 RECORDS.
1 RECORDS.
3 RECORDS.
8 RECORDS.
5 RECORDS.
3 RECORDS.
1 RECORDS.
4 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
4 RECORDS.
6 RECORDS.
6 RECORDS.
1 RECORDS.
2 RECORDS.
1 RECORDS.
9 RECORDS.
7 RECORDS.
17 RECORDS.
1 RECORDS.
5 RECORDS.
1 RECORDS.
6 RECORDS.
7 RECORDS.
9 RECORDS.
6 RECORDS.
1 RECORDS.
1 RECORDS.
4 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
6 RECORDS.
5 RECORDS.
11 RECORDS.
4 RECORDS.
5 RECORDS.
4 RECORDS.
5 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
2 RECORDS.
UNCLASSIFIED
Page 75
�UNCLASSIFIED
FOR DATE OF 700524 THERE ARE
FOR DATS OF 700525 THERE ARE
FOR DATE OF 700529 THERE ARE
FOR DATE OF 700530 THERE ARE
FOR DATE OF 700601 THERE ARE
FOR DATE OF 700602 THERE ARE
FOR DATE OF 700603 THERE ARE
FOR DATE OF 7 0 0 THERE ARE
064
FOR DATE OF 700611 THERE ARE
FOR DATE OF 700612 THERE ARE
FOR DATE OF 700613 THERE ARE
FOR DATE OF 700615 THERE ARE
FOR DATE OF 700616 THERE ARE
FOR DATE OF 700618 THERE ARE
FOR DATE OF 700620 THERE ARE
FOR DATE OF 700621 THERE ARE
FOR DATE OF 700623 THERE ARE
FOR DATE OF 7 0 2 THERE ARE
064
FOR DATE OF 7 0 2 THERE ARE
068
FOR DATE OF 7 0 2 THERE ARE
069
FOR DATE OF 700630 THERE ARE
FOR DATE OF 700702 THERE ARE
FOR DATE OF 7 0 0 THERE ARE
078
FOR DATE OF 7 0 0 THERE ARE
079
FOR DATE OF 700710 THERE ARE
FOR DATE OF 700711 THERE ARE
FOR DATE OF 700714 THERE ARE
FOR DATE OF 700715 THERE ARE
FOR DATE OF 700801 THERE ARE
FOR DATE OF 7 0 0 THERE ARE
082
FOR DATE OF 7 0 0 THERE ARE
083
FOR DATE OF 7 0 0 THERE ARE
084
FOR DATE OF 7008Q5 THERE ARE
FOR DATE OF 7 0 0 THERE ARE
086
FOR DATE OF 7 0 0 THERE ARE
087
FOR DATE OF 7 0 0 THERE ARE
088
FOR DATE OF 7 0 0 THERE ARE
089
FOR DATE OF 700810 THERE ARE
FOR DATE OF 700812 THERE ARE
FOR DATE OF 700813 THERE ARE
FOR DATE OF 700814 THERE ARE
FOR DATE OF 700815 THERE ARE
FOR DATE OF 700816 THERE ARE
FOR DATE OF 700817 THERE ARE
FOR DATE OF 700818 THERE ARE
FOR DATE OF 700819 THERE ARE
FOR DATE OF 7 0 2 THERE ARE
080
FOR DATE OF 700821 THERE ARE
FOR DATE OF 700822 THERE ARE
FOR DATE OF 700823 THERE ARE
FOR DATE OF 700824 THERE ARE
FOR DATE OF 700827 THERE ARE
FOR DATE OF 7 0 2 THERE ARE
088
FOR DATE OF 7 0 2 THERE ARE
089
FOR DATE OF 7 0 3 THERE ARE
080
FOR DATE OF 700831 THERE ARE
FOR DATE OF 700901 THERE ARE
FOR DATE OF 7009O7 THERE ARE
FOR DATE OF 7 0 0 THERE ARE
098
FOR DATE OF 7 0 0 THERE ARE
099
FOR DATE OF 700911 THERE ARE
FOR DATE OF 700917 THERE ARE
FOR DATE OF 7 0 2 THERE ARE
090
FOR DATE OF 700921 THERE ARE
FOR DATE OF 700923 THERE ARE
FOR DATE OF 700925 THERE ARE
1
2
1
2
1
1
3
1
5
13
5
1
1
10
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
RECORDS.
4 RECORDS.
4 RECORDS.
4 RECORDS.
5 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
RECORDS.
RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
1 RECORDS.
8 RECORDS.
5 RECORDS.
12 RECORDS.
5 RECORDS.
4 RECORDS.
1 RECORDS.
10 RECORDS.
10 RECORDS.
20 RECORDS.
12 RECORDS.
7 RECORDS.
4 RECORDS.
6 RECORDS.
32 RECORDS.
29 RECORDS.
8 RECORDS.
33 RECORDS.
7 RECORDS.
2 RECORDS.
2 RECORDS.
7 RECORDS.
2 RECORDS.
4 RECORDS.
2 RECORDS.
3 RECORDS.
5 RECORDS.
5 RECORDS.
4 RECORDS.
UNCLASSIFIED
Page 76
�UNCLASSIFIED
FOR DATE OF 701001 THERE ARE
5 RECORDS.
FOR DATE OF 701007 THERE ARE
2 RECORDS.
FOR DATE OF 701009 THERE ARE
4 RECORDS.
FOR DATE OF 701010 THERE ARE
1 RECORDS.
FOR DATE OF 701013 THERE ARE
4 RECORDS.
FOR DATE OF 701014 THERE ARE
6 RECORDS.
FOR DATE OF 701015 THERE ARE
1 RECORDS.
FOR DATE OF 701018 THERE ARE
3 RECORDS.
FOR DATE OF 701019 THERE ARE
1 RECORDS.
FOR DATE OF 701031 THERE ARE
1 RECORDS.
FOR DATE OF 701102 THERE ARE
1 RECORDS.
FOR DATE OF 701201 THERE ARE
1 RECORDS.
FOR DATE OF 701202 THERE ARE
1 RECORDS.
FOR DATE OF 701229 THERE 'ARE
1 RECORDS.
FOR DATE OF 710114 THERE ARE
1 RECORDS.
1 RECORDS.
FOR DATE OF 710122. THERE ARE
FOR DATE OF 710319 THERE ARE
12 RECORDS.
9 RECORDS.
FOR DATE OF 710320 THERE ARE
FOR DATE OF 710321 THERE ARE
9 RECORDS.
FOR DATE OF 710322 THERE ARE
9 RECORDS.
FOR DATE OF 710323 THERE ARE
25 RECORDS.
FOR DATE OF 710425 THERE ARE
1 RECORDS.
FOR DATE OF 710504 THERE ARE
1 RECORDS.
FOR DATE OF 711124 THERE ARE
1 RECORDS.
FOR DATE OF 711128 THERE ARE
1 RECORDS.
FOR DATE OF 711129 THERE ARE
1 RECORDS.
1 RECORDS.
FOR DATE OF 711130 THERE ARE
FOR DATE OF 711214 THERE ARE
.1 RECORDS.
FOR DATE OF 711216 THERE ARE
"1 RECORDS.
FOR DATE OF 711217 THERE ARE
1 RECORDS.
FOR DATE OF 711219 THERE ARE
1 RECORDS.
THERE ARE A TOTAL OF 5737 RECORDS.
UNCLASSIFIED
Page 77
�UNCLASSIFIED
TOTAL NUMBER OF MISSIONS
TOTAL NUMBER OF MISSIONS: 2394
UNCLASSIFIED
Appendix C Page 78
�UNCLASSIFIED
TOTAL NUMBER OF MISSIONS BY YEAR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
1960
1961
1962
1963
1964
1965
1966
1967
1968
1969
1970
1971
THERE
THERE
THERE
THERE
THERE
THERE
THERE
THERE
THERE
THERE
THERE
THERE
WERE
WERE
WERE
WERE
WERE
WERE
WERE
WERE
WERE
WERE
WERE
WERE
1 MISSIONS.
4 MISSIONS.
46 MISSIONS.
31 MISSIONS.
49 MISSIONS.
79 MISSIONS.
271 MISSIONS.
334 MISSIONS.
457 MISSIONS.
760 MISSIONS.
342 MISSIONS.
20 MISSIONS.
UNCLASSIFIED
Page 79
�UNCLASSIFIED
TOTAL NUMBER OF GALLONS
TOTAL NUMBER OF GALLONS:
1593380
UNCLASSIFIED
Page SO
�UNCLASSIFIED
TOTAL NUMBER OF GALLONS BY YEAR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
1960 THERE
1961 THERE
1962 THERE
1963 THERE
1964 THERE
1965 THERE
1966 THERE
1967 THERE
1968 THERE
1969 THERE
1970 THERE
1971 THERE
WERE
WERE
WERE
WERE
WERE
WERE
WERE
WERE
WERE
WERE
WERE
WERE
0
0
3700
4885
14360
278730
470861
250336
267047
196210
93578
13463
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
USED.
USED.
USEtil
USEol
USED)
USED.
USED.
USED.
USED.
USED.
USED.
USED.
UNCLASSIFIED
Page 81
�UNCLASSIFIED
TOTAL NUMBER OF MISSIONS WITH HERBICIDE ORANGE
TOTAL NUMBER OF MISSIONS:
391
UNCLASSIFIED
�UNCLASSIFIED
TOTAL NUMBER OF MISSIONS WITH HERBICIDE ORANGE BY YEAR
FOR
FOR
FOR
FOR
FOR
FOR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
1965
1966
1967
1968
1969
1970
THERE
THERE
THERE
THERE
THERE
THERE
WERE
WERE
WERE
WERE
WERE
WERE
16
104
100
100
186
85
MISSIONS.
MISSIONS.
MISSIONS.
MISSIONS.
MISSIONS.
MISSIONS.
UNCLASSIFIED
Page 83
�UNCLASSIFIED
TOTAL NUMBER Of GALLONS OF HERBICIDE ORANGE
TOTAL NUMBER OF GALLONS:
627596
UNCLASSIFIED
Page 84
�UNCLASSIFIED
TOTAL NUMBER OF GALLONS OF HERBICIDE ORANGE BY YEAR
FOR
FOR
FOR
FOR
FOR
FOR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
1965
1966
1967
1968
1969
1970
THERE
THERE
THERE
THERE
THERE
THERE
WERE
WERE
WERE
WERE
WERE
WERE
34025
242800
1669S5
77259
78722
27805
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
USED.
USED.
USED.
USED.
USED.
USED.
UNCLASSIFIED
Page 85
�UNCLASSIFIED
TOTAL NUMBER OF MISSIONS WITH HERBICIDE WHITE
TOTAL NUMBER OF MISSIONS:
403
UNCLASSIFIED
Page 86
�UNCLASSIFIED
TOTAL NUMBER OF MISSIONS WITH HERBICIDE WHITE BY YEAR
FOR
FOR
FOR
FOR
FOR
YEAR
YEAR
YEAR
YEAR
YEAR
1966
1967
1968
1969
1970
THERE
THERE
THERE
THERE
THERE
WERE
WERE
WERE
WERE
WERE
20
26
99
181
77
MISSIONS.
MISSIONS.
MISSIONS.
MISSIONS.
MISSIONS.
UNCLASSIFIED
Page 87
�UNCLASSIFIED
TOTAL NUMBER OF GALLONS OF HERBICIDE WHITE
TOTAL NUMBER OF GALLONS:
207
090
UNCLASSIFIED
�UNCLASSIFIED
TOTAL NUMBER OF GALLONS OF HERBICIDE WHITE BY YEAR
FOR
FOR
FOR
FOR
FOR
YEAR
YEAR
YEAR
YEAR
YEAR
1966 THERE
1967 THERE
1966 THERE
1969 THERE
1970 THERE
WERE
WERE
WERE
WERE
WERE
45900
33835
79805
30775
10655
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
USED.
USED.
USED.
USED.
USED.
UNCLASSIFIED
�UNCLASSIFIED
TOTAL NUMBER OF MISSIONS WITH HERBICIDE BLUE
TOTAL NUMBER OF MISSIONS:
337
UNCLASSIFIED
Page 90
�UNCLASSIFIED
TOTAL NUMBER OF MISSIONS WITH HERBICIDE BLUE BY YEAR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
1962
1963
1967
1968
1969
1970
1971
THERE
THERE
THERE
THERE
THERE
THERE
THERE
WERE
WERE
WERE
WERE
WERE
WERE
WERE
1
3
34
91
67
129
12
MISSIONS.
MISSIONS.
MISSIONS.
MISSIONS.
MISSIONS.
MISSIONS.
MISSIONS.
331
UNCLASSIFIED
Page 91
�UNCLASSIFIED
TOTAL NUMBER OF GALLONS OF HERBICIDE BLUE
TOTAL NUMBER OF GALLONS:
118331
UNCLASSIFIED
�UNCLASSIFIED
TOTAL NUMBER OF GALLONS OF HERBICIDE BLUE BY YEAR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
YEAR. 1962 THERE
YEAR 1963 THERE
YEAR 1967 THERE
YEAR 1968 THERE
YEAR 1969 THERE
YEAR 1970 THERE
YEAR 1971 THERE
WERE
WERE
WERE
WERE
WERE
WERE
WERE
0
0
25401
37011
18253
26623
11063
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
USED.
USED.
USED.
USED.
USED.
USED.
USED.
UNCLASSIFIED
Page 93
�UNCLASSIFIED
TOTAL NUMBER Of MISSIONS WITH UNKNOWN HERBICIDE
TOTAL NUMBER OF MISSIONS:
972
UNCLASSIFIED
Page 94
�UNCLASSIFIED
TOTAL NUMBER OF MISSIONS WITH UNKNOWN HERBICIDE BY YEAR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
FOR YEAR
1960
1961
1962
1963
1964
1965
1966
1967
1968
1969
1970
1971
THERE
THERE
THERE
THERE
THERE
THERE
THERE
THERE
THERE
THERE
THERE
THERE
1 MISSIONS.
1 MISSIONS.
21 MISSIONS.
7 MISSIONS.
12 MISSIONS.
60 MISSIONS.
148 MISSIONS.
WERE-, 174 MISSIONS.
WERE 167 MISSIONS.
WERE 326 MISSIONS.
WERE
51 MISSIONS.
WERE
8 MISSIONS.
WERE
WERE
WERE
WERE
WERE
WERE
WERE
UNCLASSIFIED
Page 95
�UNCLASSIFIED
TOTAL NUMBER OF GALLONS OF UNKNOWN HERBICIDE
TOTAL NUMBER OF GALLONS:
61S393
UNCLASSIFIED
Page 96
�UNCLASSIFIED
Pag* 97
TOTAL NUMBER OF GALLONS OF UNKNOWN HERBICIDE BY YEAR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
FOR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
YEAR
1960 THERE WERE
1961 THERE WERE
1962 THERE WERE
1963 THERE WERE
1964 THERE WERE
1965 THERE WERE
1966 THERE WERE
1967 THERE WERE
1968 THERE WERE
1969 THERE WERE
1970 THERE WERE
1971 THERE WERE
••
0 GALLONS USED.
0 GALLONS USED.
0 GALLONS USED.
0 GALLONS USED.
6 0 GALLONS USED.
00
230800 GALLONS USED.
182161 GALLONS USED.
24103 GALLONS USED.
72972 GALLONS USED.
68460 GALLONS USED.
28495 GALLONS USED.
2400 GALLONS USED.
UNCLASSIFIED
�UNCLASSIFIED
TOTAL NUMBER OF MISSIONS WITH HERBICIDE
OTHER THAN ORANGE, WHITE, BLUE- OR- UNKNOWN
TOTAL NUMBER OF MISSIONS:
91
UNCLASSIFIED
Page 98
�UNCLASSIFIED
TOTAL NUMBER OF MISSIONS WITH HERBICIDE
OTHER THAN ORANGE, WHITE, BLUE OR UNKNOWN SY YEAR
FOR
FOR
FOR
FOR
FOR
YEAR
YEAR
YEAR
YEAR
YEAR
1961
1962
1963
1964
1965
THERE
THERE
THERE
THERE
THERE
WERE
WERE
WERE
WERE
WERE
4
25
21
38
3
MISSIONS.
MISSIONS.
MISSIONS.
MISSIONS.
MISSIONS.
UNCLASSIFIED
�UNCLASSIFIED
TOTAL NUMBER OF GALLONS OF HERBICIDE
OTHER THAN ORANGE, WHITE. BLUE OR UNKNOWN
TOTAL NUMBER OF GALLONS:
31070
UNCLASSIFIED
Page 100
�UNCLASSIFIED
TOTAL NUMBER OF GALLONS OF HERBICIDE
OTHER THAN ORANGE, WHITE, BLUE OR UNKNOWN BY YEAR
FOR
FOR
FOR
FOR
FOR
YEAR
YEAR
YEAR
YEAR
YEAR
1961 THERE
1962 THERE
1963 THERE
1964 THERE
1965 THERE
WERE
WERE
WERE
WERE
WERE
0
3700
4885
8360
13925
GALLONS
GALLONS
GALLONS
GALLONS
GALLONS
USED.
USED.
USED.
USED.
USED.
UNCLASSIFIED
Page 101
�UNCLASSIFIED
xxxxx
xxxxxxx
XX
XX
XXXXX
XXXXXXX
XX
X
XX
XXXXXX
XXXXXX
XX
XX
X
XXXXXXX
XXXXX
X
xxxxx
xxxxxx
X
XX
XX
xxxxxxx
xxxxx
XX
XX
XX
XX
XXXXXXXX
XXXXXX
XX
XX
XX
XX
XX
XX
XXXXXX
XXXXXXXX
XXXXX
XXXXXX
XXXXXX
xxxxxxx
xxxxxxx
XX
XX
XX
XX
XX
XXXXXX
XXXXXX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
xxxxxxx
xxxxxxx
XXXXXX
XXXXXX
XX
X
XXXXXX
XXXXXX
XX
XX
X
XX
XX
XX
XX
xxxxxxx
xxxxx
XX
XX
XX
XX
XX
XX
XX
XX
xxxxxxxx
xxxx
XXXXX
XXXXXXX
XX
X
XX
XX
XX
XX
XX
X
XXXXXXX
XXXXX
XXXXXX
xxxxxxx
XX
xxxxxxx
xxxxxxx
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX XX
XXXX
XX
xxxxxxx
XX
XX
XX
XX
XX
XX
XX
XX
XXXXXX
XXXXXXX
XX
XX
XX
XX
XXXXXXX
XXXXXXX
XX XX
XX XX
XX
XX
XX
XX
XX
XX
XX
xxxxxxx
XXXXXX
XX XX
XX XX
XX
XX
XX
XX
XX
XXX
XX
XXXXXX
XX XX
XX
XX XX
XX XX XX
XX XX XX
XX
XX XX
XX
XX XX
XX
XXXX
XX
XXX
XX
XX
XX
XX
XX
XX
XX XX
XXXXX
XXXXX
XX XX
XX
XX
XX
XX
XX
XX
XXX
XX
XXXX
XX
XX XX
XX
XX XX
XX
XX XX XX
XX XX XX
XX
XX XX
XX
XX XX
XX
XXXX
XX
XXX
XX
XX
XX
XX
XX
XX
XXXXXX
XXXXXXXX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XXXXXXXX
XXXXXX
UNCLASSIFIED
XXXXX
XXXXXXX
XX
X
XX
XXXXXX
XXXXXX
XX
XX
X
XXXXXXX
XXXXX
XX
XXXX
XX XX
XX
XX
XXXXXXXX
XXXXXXXX
XX
XX
XX
XX
XX
XX
XX
XX
XXXXX
XXXXXXX
XX
X
XX
XXXXXX
XXXXXX
XX
X
XX
XXXXXXX
XXXXX
XXXXXXXX
XXXXXXXX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
XX
xx
xx
XX XX XX
XX XX XX
XX XXXX XX
XX XXXX XX
xxxxxxxxxx
XXXXXXXX
XX
XXXX
XX XX
XX
XX
XXXXXXXX
XXXXXXXX
xx
XX
XX
XX
XX
XX
XX
XX
XXX
XX
XXXX
XX
XX XX
XX
XX XX
XX
XX XX XX
XX XX XX
XX
XX XX
XX
XX XX
XX
XXXX
XX
XXX
�UNCLASSIFIED
YYMMDD CTZ PRO
605198
610824
620110
620214
620215
620903
620903
600
294
620904
620905
620905
600
296
600
296
620907
620907
620920
620920
620S21
620921
620924
620924
620927 4
620927
620930
620930
621001
621001
621003
621003
621004
621004
621008
621008
621009
621009
621010
621010
621011
621011
621121 3
621122 3
621123 3
621214
621218
621224
630216 1
630218 1
630218
630218
630218
630219 1
600
366
600
367
600
368
600
369
630715
630716
630717
630718
630719
H
GAL
U
U
U
U
U
U
U
U
U
35
U
D
U
U
U
U
U
U
U
U
21
21
21
U
U
U
C
C
C
03
03
U
U
C
C
U
U
03
U
YYMMDD CTZ PRO
T
C
1A YC607815
1B XT790550
18 XT1 14019
18 YT 180835
18 YS765985 S
1A V0808980
1B VR970028
1A V 8 8 8
0090
1B VR970028
1A V0808980
18 VR970028
1A V0808980
18 VR970028
1A V0808980
18 VR970028
1A W0003690
18 W0034770
1A W0003690
18 W0034770
1A W0093715
18 W0064S05
1A XR7 18693 S
18 XR66S710
1A W0220720
1B W03 10760
1A W0220720
1B W03 10760
1A W0220720
1B W03 1 7 0
06
1A W0093715
1B WQ064805
1A VR844520
18 VR990386
1A VR844920
1B VR990386
1A VR844S20
1B VR990386
1A VR844520
1B VR990386
1A YT610880 S
1A YT520810 S
1A YT580810 S
18 C0270233
1B CR055090
18 CR05S090
1A YC569828 S
1A YC550980 S
1A YC620970 S
1A YC569830 S
1A YC570820 S
1A YC568852 S
18 V0985665
18 V0985665
18 WO 134605
18 W0 134605
18 YT135100
18 YT135100
1B YT135100
18 YT 194 127
1B YT257121
F
H
H
H
H
H
H
H
H
H
631026
631027
631029
631031
631113
631114
631116
631119
631208
631209
631223
631223
640131
640205
600
434
640304
600
434
640304
600
434
640304
600
434
640304
600
434
600
434
640419
602
440
640421
640422
602
442
640423
602
444
640425
603
440
602
456
640531
640624
640625
640626
600
478
600
478
600
478
600
478
600
478
600
478
600
478
600
478
600
478
640826
600
495
600
495
600
495
600
495
600
495
600
495
600
495
600
495
600
495
641003
6410O3
610
403
Pi.ge 1C.:
H
GAL
T
U
2
07
U
0
2
07
U
D
2
07
U
D
2
07
U
D
2
07
U
D
UNCLASSIFIED
U
LEG
COORD
18 BS0400S5
1B 8S0400S5
18 BS250218
18 BS270250
18 YT364485
1B BS204206
18 BS070115
1B BP950205
18 BN704635
18 BN707635
1A WR078218
1B VR989390
18 VR989390
18 VR790310
1A BR740664
18 BR727662
1A BR7226S2
18 BR7356S8
1A BR744649
18 BR725649
1A BR732673
18 BR734677
1A BR744673
18 BR746676
1B XS430637
18 XS430637
1B XS430637
1B W0 11 7889
1B XS430637
18 XS430637
1B XS430637
18 XS430637
18 W0370774
18 XS284596
18 YC522815
18 YD602060
18 YC923873
16 ZC0074OO
18 AN770990
1C ZS 2 3 5 0
00
10 AM030090
18 ZT220280
1C ZT160190
10 ZT260180
18 AN840480
1C AN740290
10 ANS40290
1A YC672254
18 ZT220280
1C ZT160190
1Q ZT260180
18 AM770990
1C Z5230500
10 AM030900
18 AN840480
1C AN740290
10 AN840290
2A YU580000
3A YT670930
4A YT670760
S I M
S
F
S
F
S
F
S
F
S
F
�UNCLASSIFIED
YYMMDD CT2 PRO
H
GAL
T
LEG
COORD
S I M
YYMMDO CT2 PRO
Page 104
H
GAL
T
LEG
COORD
S I M
* •
641003
641004
641004
641004
641004
641004
641005
641005
641005
641003
641006
641006
641006
641006
641011
641011
641011
641011
641013
641013
641022
641223
641223 1
641223
641224 1
650101 '1
650101
650111 3
650111
650112 3
650112
650113 3
650113
650113
650113 '
650113
650113
650118 3
650118
650118
650118
650119 3
650119
650122
650123 3
650123
650124 3
650124
650124
650124
650125 3
650125
650125
650125
650126 3
650126
650126
650126
650127 3
650127
U 000
40
U 000
20
U
03
U
f
02
06
U
P
U 0000
20
18
U 0000
30
27
U 000D
30
19
U 000D
30
19
U 000D
20
18
U 000D
20
23
U 000D
80
24
U 000D
70
*
24
24
24
t
U 000D
70
U 000D
70
U 000D
70
5A YT470760
1A YU4700QO
2B YU580000
3C YT670933
4D YT670760
5E YT470760
28 YU580000
3C YT670933
40 YT670760
3E YT470760
26 YU580000
3C YT67O933
4D YT670760
SE YT470760
2B YU580000
3C YT670933
40 YT670760
5E YT470760
1A YT630830
1A YT630830
1B ATS 10850
1B ATS 10850
1A YC923873 S
IB ZC 1205 15
1A YC4 15450 S
1A YB72050O S
18 YB700340
1A YS916757 S
18 YS980800
1A YS615830 S
18 YS630910
1A YT447332 S
18 YT475340
2A YT501344
28 YT555362
3A YT585390
38 YT6 18427
1A YS650076 S
18 Y580O970
2A YS908754
28 YS980800
1A YS884995 S
18 YT920050
1B XT545327
1A XT480430 S
1B XT545327
1A XT48O430 S
18 XT440410
2A XT545327
2B XT500314
1A XT48O430 S
18 XT44O410
2A XT545327
28 XT500314
1A XT480430 S
18 XT440410
2A XT545327
28 XT500314
1A XT480430 S
18 XT440410
F
F
F
F
F
F
f
F
F
F
F
F
F
650127
650127
650129 3
650129
650201 3
650201
650201
650201
650202 3
600
522
650202
650202
650203 3
650203
650203
650203
650204 3
650204
650204
650204
650205 3
650205
600
525
650205
600 3
526
650206
600
526
650206
650207
650215 3
650215
650215
650215
650216 3
650216
650216
650216
650217 3
650217
650217
650217
650218 3
650218
650218
650218
650301 3
650301
650302 3
650302
650303 3
650303
650304 3
600
534
650305 3
650305
650306 3
600
536
650312 3
650312
650318 3
18
U 02000 D
19
U 05500 D
19
U 05500 D
19
U 05500 D
19
U 05500 D
19
U 05500 D
19
U 05500 D
19
U 050OO D
19
U' 0 0 0 D
50
19
U 000D
50
19
U 000D
50
26
U 02800 D
26
U 02800 D
26
U 02800 D
26
U 02800 D
26
U 02300 D
26
U 02800 D
26
U 000D
20
26
U 000D
60
UNCLASSIFIED
2A XT545327
2B XT500314
1A YS884995 S
1B YT920050
1A XT540311 S
1B XT490310
1C XT440420
1D XT480430
1A XT540311 S
1B XT490310
1C XT440420
10 XT480430
1A XT540311 S
1B XT490310
1C XT 140420
10 XT480430
1A XT540311 S
1B XT490310
1C XT440420
10 XT480430
1A XT540311 S
1B XT490310
1C XT440420
1D XT480430
1A XT540311 S
1B XT490310
1C XT440420
1D XT480430
18 XT520310
1A XT465410 S
18 XT520310
1C XT490428
1D XT545320
1A XT465410 S
16 XT520310
1C XT49O428
1D XT545320
1A XT465410 S
1B XT520321
1C XT490428
10 XT545320
1A XT465410 S
1B XT520310
1C XT490428
10 XTS45320
1A YS125538 S
18 YS000752
1A YS125538 S
18 YS000752
U YS125538 S
18. YS000752
1A YS125538 S
18 YS000752
1A YS 125538 S
18 YS000752
1A YS125538 S
18 YS000752
1A YS125588 S
1B YS000752
1A YS 125588 S
F
F
F
F
"
F
F
F
F
F
F
F
F
F
F
F
F
F
F
�UNCLASSIFIED
YYMMDO CT2 PRO
H
GAL
T
LEG
COORD
S 1 M
YYMMDD CTZ PRO
Pige 103
H
GAL
T
LEG
COORD
S
I M
ff
650318
650329 2
650329
6S0329
650329
650330 2
650330
650330
630330
650401 2
650401
650401
650401
650401
630401
650401
650401
650402 2
650402
650402
630402
650402
650402
6002
54.
650402
650412 2
630412
6504 12
650412
650413 2
650413
650413
650413
630414 2
650414
650414
650414
650417 2
650417
650417
650417
650418 2
650418
63O4 1 8
650418
602
540
650420
650420
650420
650430 4
650430
630430
650430
650430
650430
603
540
65O430
650430
63043O
650430
07
'U 03000 C
07
U 03000 C
07
U 000C
30
07
07
07
U 000C
30
U 000C
30
U 0500
20
07
U 050D
20
07
U 000C
60
07
U 000C
50
U 000
20
41
U 000 0
60
18 YS000752
1A BS600230 S
1B BS600160
2A BSS50230
2B BS850160
1A BR680960 S
1B BS730040
2A BS730100
2B 8 6 0 5
S600
1A BS600230 S
1B 8S600160
2A BS8S0230
2B BS850160
3 A BS6 5 0 0
04
3B B5730100
4A BS74Q040
45 BR690960
1A BS600230 S
1B BS600160
2A BS850230
2B BS850160
3A BS650040
3B BS730100
4A BS740040
4B BR690960
1A BS600230 S
1B BS600160
2A BS850230
2B BS850160
1A BR6109OO S
1B BR730890
1C BR72028O
ID BR6S0800
1A BR6 1 9 0 S
00
1B BR730890
1C BR720280
1D BR650800
1A BR740780 S
1B
1C
10
1A
1B
1C
1D
1A
1B
2A
2B
1A
1B
1C
1D
1E
1F
1G
2A
2B
2C
2D
BR650800
BR690710
BR750720
BR740780 S
BR650800
BR690710
BR750720
XB945213
YB015221
YBO88276
YBO50235
XR272345 S
XR283340
XR300346
XR317367
XR3 10397
XR290377
XR272357
XR228416
XR260393
XR318430
XR30S455
F
f
F
F
F
F
F
F
F
F
650430
650430
650501 4
650501
650501
650501
650301
650501
650501
650501
630501
650507 4
650507
650507
650507
650507
650507
650525 4
650525
650525
650525
650525
650525
650525
650525
650525
650721 3
650721
650721
650721
650721
650722 2
650722
650724 3
650724
650724
650724
650725 3
650725
650726 3
650726
65O726
650726
650727 3
650727
650728 3
650728
650729 3
650729
650901 4
651101 2
65 1 203
65 1 203
651203
651203
651203
651203
651203
651204
651204
43
U 03000 D
35
U 000D
30
43
U 000D
40
26
U 000D
40
07
U
26
U 000D
60
26
U 000D
60
26
U 000D
60
26
U 000D
60
26
U 000D
50
26
U 000D
40
36
08
U
U
UNCLASSIFIED
D
P
P
2E XR260410
2F XR238424
1A W0458960 S
1B WR436026
1C WR400022
1D WR405060
1E WR480057
1F WR660160
1G WR920250
1H WR920220
11 WR573090
1A XR543598 S
1B XR556600
1C XR550570
1D XR547553
1E XR535553
1F XR538577
1A W0458960 S
1B WR436026
1C WR400220
1D WR406060
1E WR480057
1F WR660160
1G WR920250
1H WR920022
11 WR 5 7 5090
1A YT065110 S
1B YT 100-1 10
1C YT 130095
10 YT 120070
1E YT095050
• 1A BR389447 S
1B BR35S453
1A YT060110 S
18 YT 100050
2A YT 1001 10
2B YT 120070
1A YT090110 S
1B YT 120070
1A YT0851 10 S
1B YT 11 1070
2 A YT068110
2B YT 103057
1A YT075110 S
1B YT 105060
1A YT1O0110 S
1B YT 127088
1A YT075110 S
1B YT 105060
1A XSO40330 S
1A YA842500 S
1B YB8 12809
1C YB848780
10 YB852790
2A YB800871
2B YB855894
3A YB810910
38 YB8 17890
18 YD122015
1C YC 120995
s,
F
F
F
F
F
F
F
F
F
F
F
G
H
�UNCLASSIFIED
YYMMOD CT2 PRO
H
GAL
T
LEG
COORD
S I M
YYMMDD CT2 PRO
Page 106
H
GAL
T
LEG
COORD
S I M
a •
63 1204
65 1 204
651204
651204
651204
651204
651204
651204
651204
651205
651205
651205
651205
651205
651205
651205
651205
651208 4
651208 3
651208
651209
651209
651209
651209
651209
651209
651209
651209
651209
651210
651210
651210
651210
651211
651211
651211
651213
651213
651213
651214
651214
651214
651214
651214
651214
651215
651215
651215
65 1220
651220
651220
651220
651220
651221
651222
651222
651222
651222
651222
651222
33
26
U 03000 D
U 000D
30
U 000D
30
U 000 D
20
10 YC 105995
2A YC 11 3975
26 YC 100958
2C YC 11 8 4
90
20 YC 130963
3A Y 0 0 9
C990
3B YC 130965
4A Y0090015
4B YD.,1 30025
1B YC3S0747
1C YC240872
10 YC282909
1E YOO49109
1F YD025065
16 YD005049
1H Y0025049
11 Y0045030
1A XS700270 S
1A YS800230 S
1B YC068967
1B XD97S132
1C XD969070
10 X 9 9 8
0607
1E XD988070
1F X0988087
2A YC193975
2B YC201949
2C YC220935
20 YC231920
1A YB6109O5 S
1B YB6 10890
1C YB630890
10 YB6309OO
1B YC201949
1C YC220935
10 YC231920
1B YC1 18788
1C YC147795
10 YC173818
1A YC1 10835 S
1B YC 139859
1C YC178885
2A YC202780
2B YC225800
2C YC249818
18 YC274634
1C YC250605
10 YC2596O4
1B YB58S650
2A YB635565
2B YB644535
3A YB675505
3B YB648472
1B YB650675
1B YC620080
2A YC749058
28 YC593047
3A YC707668
3B YC697705
4A YC685690
F
F
F
F
651222
651223
651223
651223
651223
651224
651224
651224
651224
651224
651224
651224
651224
651224
651227
651228
651228
651229
651230
651231
660101
660101
660101 1
660101
660101
660101
600
612
660102
660102
660102
660102
660102
660103
660103
660103
660103
660103
660104
660104
600 3
615
660105
660105
660105
660105
660105
660106
660106
660106
660106
660106
660106
660106
600
616
660106
660106
660106
600
616
660106
660106
660107
U 000D
20
U 01000 0
06
U 01600 D
U 000D
20
U 0000
20
U 000 0
20
26
UNCLASSIFIED
U 000D
40
U 000D
40
4B YC662645
1B YC475675
2A YC490690
26 YC530690
2C YC560620
1B YC330490
2A YC27S380
2B YC280465
3A YC325555
3S YC295520
4A YC325595
4B YC345575
5A YC370200
5B YC375165
1A YB708727 S
1A YB699432 S
1B YB782451
1B Y8690390
1B YB700340
1B YB7 10405
18 YB700340
1C YB720500
1A YB590700 S
1B YB588610
2A YB725670
2B YB708730
1A YB708727 S
1B YB720696
1C YB726665
2A YB584647
2B YB586670
2C YB588698
1A YB732709 S
1B YB720756
2A YB645713
2B YB644663
1B WR720145
1A YB7 15798 S
16 YB735697
1A YS 130585 S
1B YS040650
1C YS030750
1B YB655654
2A YB679711
2B YB651659
1B YC3487S5
2A YC283840
26 YC320841
3A YC276820
36 YC255809
4A YC293785
4B YC294751
5A YC045968
SB YC068967
6 A YD 180026
6B Y0090015
7 A YD 1 4 4
600
78 YD 140027
1B YS 150650
1A YC450822 S
F
F
F
F
F
F
F
F
�UNCLASSIFIED
YYMMOD CTZ PRO
H
GAL
T
LEG
COORD
S 1 M
YYMMOD CTZ PRO
Page 107
H
GAL
T
LEG
COORD
S I M
• m
660107
660107
660107
660107
660107
660107
660107
660107
660107
660107
660107
660107
66010?
660108
660108
600
618
660108
660108
660108
660108
660108
600
618
660109
660109
660109
660109
660109
600
619
660109
660109
6601 10
6601 10
660110
660111
660112
660112
660112
6601 12
660112
660112 1
660112
660112
660112
660112
660112
6601 13
660113
660113
660113
660113
660113
660113
660113
660113
660113
660113
660114
660115 1
660115
660115 1
U 000D
40
01
U 016OO D
U 020OO D
03
U 000D
20
03
U 018SO D
1B YC472769
2A YC045969
28 YC068967
3A YC125957
3B YD097038
4A XC873615
48 XC392540
1B YS033675
2A YS035675
28 Y 0 0 4
S070
1B XT4SOSSO
18 YS03S340
18 YS050610
1A XC871616 S
18 XC905522
2A YB213913
28 YB22597S
3A YB21097S
38 YB220960
18 YS025640
2A YS02S640
28 Y 0 0 6
S070
18 XC793978
2A XC864618
28 XC88S540
3A YC 143690
38 YC 103690
18 WR640113
2A WR80218S
. 8 WR63S117
2
1B XDS90192
2A X058820S
2B X0550302
18 XC901523
18 XD55629S
2A X05 18370
28 XDS2839S
3A X0086210
36 XD090210
1A XDS 18370 S
1B XD528395
2A X0086210
2B X0690210
3A XD086215
38 XD090215
1A XD775020 S
18 XC793981
2A YC065954
2B YC069977
3A YC054956
38 YC658981
4A YC 153943
48 YC 114920
4C YC0679S3
SA YC048947
SB YC059989
18 XDS28395
1A YC067846
18 YD090016
1A YC786960 S
F
F
F
F
660115
660115
660115
660115
660115
660116
660116
660117
660118
660119
660119
660119
660119 1
660119
660120
660120
660120
660124
660124
660124
660124
660125
660125
660 123
660125
660125
660125
660123
660125
660123
660125 1
660125
660125
660125
660125
660125
660125
660125
660125 1
660125
660125
660125
660126
660126 1
660126
660126
660126
660126
660127
660127
660127
660127 1
660127
660127
660127
660128
660128
660128
660128
660128
U 01900
01
U 01800 D
U 000
20
U 000
20
06
U 01600 D
06
U 080D
05
03
U 000 0
20
UNCLASSIFIED
U 000 0
20
18 YC 148966
2A YC 153494
2B YC 148966
3A YC0569S6
36 YC047156
1A XCS686O9
1B XC901524
1B XC901524
18 YC325885
18 XD600136
2A XOS48303
2B XDS87210
1A XD60013S S
1B X0622870
18 YB441321
2A YB439319
28 YB439321
1A XD5S9239
18 XD548304
1A X0600135
1B XD585190
18 YB704661
2A YB667644
2B YB687689
3A YB2 13973
3B YB225975
4A YB2 10975
48 YB 2 0 6
290
5A YB708920
SB YB709970
1A YB220850 S
1B YB222850
1C YB22085S
10 YB222855
2A YB705656
28 YB695728
3A YB686700
38 YB662640
1A YB 189987 S
18 YB227960
2A YB200980
28 YB256976
18 YC06S967
1A YC154943 S
18 YC066950
1C YC060890
10 YC060926
1E YC036927
1B .XD587210
2A XD527395
2B XDS 18370
1A XD600135 S
18 XDS85190
2A X0589239
28 XD548304
18 XD090210
2A YDOS01 10
28 YD036065
3A YD0501 10
38 YD081035
F
F
F
F
F
�on iL-t-s
YYMMDD CTZ P'RO
660128 1
660128
660128
660129
660129
660129
660130
660130
660130
660131
660131
660131
660201
660201
660202
600
622
660202
660202
660202
660203
660203
660203
660203
660205
660205
660206
660206
660206
660207
660208
660208
600
628
600
628
600
629
660210
660210
660210
6602 1 1
6602 1 1
660211
660212
660213
660214
660215
660216
660218
660219
602
620
602
624
660225
602
626
660227
602
628
660228 1
660228
660228
602
628
660228
602
628
660301
01
H
GAL
T
U 01000 D
U 000D
20
U 000D
20
U. 0 0 0 0
20
U 000D
30
U
LEG
COORD
S I M
1A YD050110 S
1B YD02S046
1C YD081035
1B YB731708
2A YB708727
2B YB726665
1B YB658429
2A YB604413
2B YB695335
1A YB854804 S
1B YB841774
1C YB807813
1A XD775020 S
1B XD7 12021
1B XD675O40
1C XD620175
10 XD590180
2A XC795990
26 XC8 14705
1B XC959515
1C XC891S09
2A XC965425
2B YC040244
1A YB225975 S
1B YB366966
1B XC926964
2A XC905975
2B YC020980
1B YC040230
1B YC074135
1C YC082150
10 YB230975
1E YB270960
1B YC072135
1B YB230975
2A YB364964
2B YB360973
1B YB225975
2A YB2 12973
2B YC 180250
1B YC 125065
1B XD295555
1B YC070970
18 X0770020
18 YCO70970
1B YC 120095
1B XC886S24
1B XC830680
18 YB587313
18 YC030355
1B YC095233
1B YC161039
18 XC792770
1A XC794980 S
18 XCS14814
1A XG563813
18 XG528833
1C XG491899
10 XQ478842
18 Y0078031
F
F
F
F
F
YYMMDD CTZ PRO
660301
660301
660301
660301
660301
600
632
660302 1
600
632
660304
600
634
660304
600
635
660305
600
635
660305
660305
600
636
660306
660307
660308
600
639
660310
660311 1
6603 1 1
660311
660311
660311
6603 1 1
660312
660313
660313
660313
660313
660313
660315
660316
660316
660318
660318
6603 1 8
602
635
660325
660325
660325
602
639
660329
603
630
660330
660331
660331
600
641
660401
600 2
644
600
645
600
646
600
646
600
646
6O0
646
600
646
600
646
06
Page 108
H
GAL
T
U 03000 D
U
03
U 01150 D
U 000D
20
U 000D
30
U 020OO D
•
10
UNCLASSIFIED
U 000D
20
U
0
U 000D
20
LEG
COORD
5 I M
2A YC021983
2B YC055968
1B YC055968
2A YD080085
28 YD078031
18 YB500327
1A YB657327
1B YB533320
1B YB498324
2A YB492263
2B YB467321
18 YB485270
2A YB5 10267
2B YB300508
3A YB494254
3B YB508302
1B XC845668
1A YT 150290
18 YB356467
18 YE356467
1B XC820697
1B XD633156
1A YCO 13963 S
2A YC032966
28 YC041002
3A YC070981
3B YC080987
3C YC067947
1B XD632158
2A XC885506
2B XC897438
3A XC79779538 XC808784
3C XC806712
2A XD088672
1A XE2S8107 S
18 XE278108
1B XD160410
1C XD 160360
10 XD 170344
1A YD192384 S
1B YD 194395
1C YD125413
10 YD 134400
1A YB222955 S
1B YB228743
1B XD162343
18 YB390563
1A XD190414 S
1B XD162343
1B YB3875S3
1C YB366635
1A C0105S30 S 2
1B XE230013
1A XD030853 S
1B XD045865
1C XD080880
2A XE150010
2B XE170018
2C XE225003
F
F
F
F
F
�UNCLASSIFIED
YYMMDD CT2 PRO
H
GAL
T
LEG
COORD
S I M
Pace 109
YYMMDD CTZ PRO
H
GAL
T
LEG
COORD
SI M
« a
€60406
660406
600 1
648
600
648
600 1
648
600
648
600
648
600
648
660410
660410
660410
660410
6 0 11 4
64
660412
660412
660412
660412
660412
660412
660412
660412
660415
660415
660415
660413
660415
660415
660416
660416
660416
660416
660418
660418 4
66O418 4
660418 4
66O418 2
660418
660419
660419 4
602
640
660420 2
660420
66O420
660420
660420
66O423
602
643
660423
660423
660423
660423
660425
660425
660427
660429
660430 4
660501 4
660501
660502 4
660502
01
U 01000 D
02
U 01000 D
U 000
20
33
U 00110 P
U 000
20
U 000D
20
34
36
37
07
U
U
U
U
00015
00108
000
07
000
20
P
P
P
D
36
U 00108 P
07
U 000D
20
U 00108
U 000D
20
U
34
36
36
U 00015 P
U 007F
00
U 007 F
00
20 XE230013
2E XE2 17024
1A YD205384 S
1B YD250415
1A YD190400 S
18 YD115417
1C YD200400
10 YD243430
1A XD590300
1B X0590268
1C XD581300
10 X0581268
1A XS481468 S
1A YS456557
1B YS481518
1C YS490531
10 YS458568
1E YS455574
1F YS437558
1G Y3436564
1H YS45057S
1B XE230020
1C XE210045
10 XE26OO93
1E XE26O098
1F XE265101
16 XE259106
IB XE278108
1A XE281135 S
1B XE272177
1C XE283178
16 YB425300
1A XS53S334 S
1A WS986239 S
1A WS443568 S
1A BR425627
1B BP480590
1B Y8218278
1A WS9S6239 S
1B X8915215
1A XB94S213 S
1B YB015221
1C YB088276
1D'YB050235
1A WS986239
1A XD1 18925 S
18 XD 11 5 0
90
1C X0090878
10 XDOS5880
1E XD020855
1F XD040850
1A XB635315 S
1B XB780230
1B XD453278
1B YB071283
1A XS490377 S
1A XS122190 S
18 XS123199
1A XS 122 190 S
1B XS123199
F
F
G
Q
G
G
G
F
F
F
G
G
G
660503
660503 4 36
660503
660504
660304
660504 4 36
66O504
660505 4 30
660505 4 36
660505
660906 1
05
600
656
660506
6 0 0 4 36
656
660506
660506
66O506
660507 4 36
660507
6 0 0 4 36
658
660508
660509 4
36
660509
660510
660510
660510 4 30
660510 4 36
660S10
660511
66Q511
6605 1 1
660511 4 36
6605 1 1
660512 4 36
660512
660513
660513
660513 4
36
660513
660514
660514
660514 4 34
660514
660514
660514
660514 4
36
66O514
660515
660515
66O515 4 36
660515
660517
660517
660519
66O519
660519
660520 4 30
660525 4 34
660525 4
30
660525 4 40
UNCLASSIFIED
U 007 F
00
U 000D
20
U 007F
00
U 000P
02
U 007F
00
U 000D
20
U 007F
00
U 000
20
U 007 F
00
U 007F
00
U 007F
00
U 000D
20
U 000P
02
U 007 F
00
U ,00 F
007
U 007F
00
U 02OOO D
U 007 F
00
U 000D
20
U 060F
08
U 007 F
00
U 000D
20
U 007 F
00
U 000D
20
U
U
U
U
OOO40
00051
000
03
00016
P
P
P
P
1B XB855188
1A XS122190 S
1B XS123199
1A XO 300344 S
1B XD425276
1A XS122190 S
1B XS123199
1A X5762364 S
1A XS122190 S
1B XS123199
1A BS756070 S
16 BR843891 S
1B YB415310
1A XS122190 S
1B XS123199
1A XB852191
1B XB940201
1A XS122190 S
1B XS123199
1A XS122190 S
1B XS123199
1A XS122190 S
1B XS123199
1A XD 133958 S
1B XD021855
1A XS763366 S
1A XS122190 S
18 XS123199
1B YB480285
2A XB934201
2B YB058240
1A XS122190 S
1B XS123199
1A XS122190 S
1B XS123199
1A XD300345 S
18 XD220465
1A XSI22190 S
18 XS 123 199
1A XD131963 S
18 XE22S029
1A XS621267 S
1B XS640270
1C XS637253
10 XS620253
1A XS122190 S
1B XS123199
1A YB418296 S
1B YB125289
1A XS122190 S
18 XS123199
1A XB700147 S
18 XB935235
18 YB608399
2A XB682125
28 XB780162
1A XS711382 S
1A XS500361 S
1A XS696378 S
1A WS724150 S
Q
H
G
G
G
F
f
G
G
G
G
F
G
G
G
G
F
G
F
G
G
F
G
F
G
G
\.'J
G
�UNCLASSIFIED
YYMMDD CTZ PRC
H
GAL
T
LEG
COORD
S I M
YYMMDD CTZ PRO
Page 110
H
GAL
T
m a
66052S
660526 4
660527 4
660530
660531
66053 1
660531
660601 4
600 4
662
600
663
600
663
660603
600
663
600
663
66O603 4
660603 4
600
663
600
664
660604
660605 4
600 4
666
660607
600
667
66O607 4
600
668
6O0
668
600 4
668
600 4
668
600
669
6O0
669
600 4
669
6 0 11
66
660611
6606^3 4
660613
660614
660614
660614 4
660616 4
66O617
660617
660617 4
660617
6606 1 8
660618
660618 4
660618 4
660618 4
660620
602 4
660
66O620 4
660624 4
660625
660625
660626
602
666
660627 4
602 4
667
660627
603 4
660
34
40
U
U
U
U
U
01650
000P
04
OO016 P
02000 0
40
4
0
U 00016 P
U 00016 P
U 000 0
40
40
40
U 000P
02
U OO028 F
U 000D
20
30
40
U 006 P
04
U 00016 P
U 000D
20
36
U OOOS4 P
U 000D
20
36
40
U 004 P
05
U 00016 P
U 000D
20
40
43
U 00016 P
U 000D
20
U 000F
02
U 000D
20
30
34
34
U 000P
04
U 006 P
03
U 0000
20
U 007 P
02
U
U 000D
20
34
34
34
U 000P
04
U 005 P
03
U 007 P
02
30
43
34
U
U
U
U
004
02
005
00
000
30
000
20
P
P
D
0
U 000D
20
43
43
U 005 P
00
U 005 F
02
36
U 01243 P
1A BR478447
1A XS528305 S
1A WS721141 S
1A YC608810
1A YB445340 S
1B YB460365
1C YB365460
1A WS716130 S
1A WS714123 S
1A XB8S0190
1B YB000270
2A YC441278
28 YC482274
2C YC333167
1A WS789047 S
1A WS783038 S
1B WS788045
1A XD470260 S
1B XD590180
1A XS725432 S
1A WS713111 S
1A XDO 18864 S
1B WD994905
1A WS910164 S
1A XD 133950 S
1B XD1S1995
1A WS910164 S
1A WS718071 S
1A X05O0246 S
1B XD4 18280
1A WS713150 S
1A XB915225 S
18 YB097284
U WR583228 S
18 WR603233
1A WD991903 S
1B WD951933
1A XS693447 S
1A XS338364 S
1A WE892005 5
1B W0945935
1A X3386369 S
1A YC565822
1A YB377620 S
18 YB380579
1A XS264362 S
1A XS305348 S
1A XS295373 S
16 BT256217
1A XS676455 S
1A WR565224 S
1A XR845595 S
1A YB353462 S
1B YB440340
1A YB370473 S
18 YB430340
1A WR505207 S
1A WRS05207 S
18 WR330149
1A X504033O 5
G
G
F
G
G
F
G
G
F*
G
G
F
G
F
G
G
F
G
F
G
F
G
G
F
G
F
G
G
G
G
G
F
F
F
G
G
G
LEG
COORD
SI M
• •
660706
660706
660707
660707
660707
660713
660713
660713
660713
660714
660714
660714
660714
66O715 1
660715
660715
660715
660716
660716
660717
660717
660720
660720
602
672
660724
602
674
660730
603
670
660730 3
660801 1
660801
600 1
682
660802
600
682
600
684
600
684
660805
600
685
600
685
600
686
600
686
66O809
6 0 11
68
660813
6 0 15
68
660815
660816
660816
660819
660819
660819
660819
660819
660819
660820
66O820
660822
602
682
660824 2
602
684
U 000 D
20
U 000D
20
02
U 000D
20
U 03000
U 000 D
30
U 020OO D
31
01
U
U 000D
20
03
U 000D
20
U 000D
20
U 000D
20
U 000 0
20
U 000D
20
06
UNCLASSIFIED
U 000D
20
F
1A WE891010 S
1B WE870060
F
1A XCS80620 S
1B XC900050
1C XC930052
1B YB590185
1C YB6201S5
2A YB590190
2B YB630210
1B XD027764
1C WD994770
10 WD980820
1E XD025830
F
1A 2D 140946 S
F
18 2D 170035 S
F
1C ZD 165065 S
F
1D ZD250060 S
F
1A XD340340 S
18 X04 15350
18 YC490288
1C YC590120
F
1A YB500250 S
18 YB615150
1B XD420285
18 YC4 90290
1C YC590120
f
1A XD290350 S
1B XD4 10290
1A XS285870 S R F
F
1A YD700023 S
F
1B YC430950 S
F
1A ZC072932 S
F
1B ZC062960 S
F
1C ZC072967 S
18 XD000900
1C XD000860
1B XD540250
2 A XD5 10240
28 XD540240
F
1A XD380430 S
1B XD560380
18 XD1O0657
18 XD430270
18 WD930910
F
1A W0953952 S
18 WD930910
1B WE562082
1C WE560040
1A XD360634 S . F
1B XD392631
2A- XD621671
28 XD564674
18 XD760870
1C XC835865
F
1A WD940690 S
1B XD060627
18 XC81S990
1C XC997930
F
1A YA860600 S
18 Y A 7 0 4
950
�UNCLASSIFIED
YYMMDD CT2 PRO
660825
660825
660826
660826
660829
660829 3
660829
660831
600
692
600
693
600
694
6609O9
600
699
660919
660919
602
690
660922
660922
661014
661014
661014
661014
661014
661014
661025
661025
661025
661025
661026
661026
661026
661026
661027
661027
661101
661102
661102
661105
661105
661110
661120
661123
661123
661124
661124
661125
661125
661128
661128
661128
661129
661129
661130
661204
661204
661204
661205
661205
661208
661208
H
GAL
T
U 000 D
20
U 000 D
20
31
U
U 01800 D
U 000 0
30
U 01000
U 000 0
20
U 000
20
U 000 D
20
U 000 D
20
U 020OO D
U 000 D
20
U 000 D
20
YYMMDD CTZ PRO
1A ZC070970 S
1B ZC050930
1A XD5 10240 S
F
1B XD577225
1B XD005935
1A XS345809 S R F
1B XS335810
1B YB385274
1B XB920230
1B XB085270
1B XT660390
1A YC175990 S
F
1B YC095893
1B XC760870
1C XC835865
1B XC9S0962
1B XC8 15990
1C XC997930
1B YDO03040
2A XD9S0040
2B YC002S50
1B YC07O930
2A YD085045
2B YC075980
1A XB930214 S
F
1B YB271270
1A YB500230
1B YB350275
1A YB2S0720 S
F
1B YB360S20
1A YB370S20
1B YB420420
1A XB690125 S
F
1B XB925238
1B WD9504SO
1B BR160140
1B WD920570
1A WE850100 S
F
1B WE780240
1B WE83010O
1B XE230018
1A WD870870 S
F
16 WD890870
1A XD0307SO S
F
18 XD070770
1A XD 125930 S
F
1B XDO40864
1B XD 140980
2A XD 130980
2B XD 140960
16 XD 120870
1C WD990860
1B XD 100880
1B YS359810 S
F
1C YS375810 S
F
1D YS375850 S
F
1B WD974820 S
F
1C XD023760 S
F
1B WES20120
2A WE900960
661208
661210
661210
661210
661210
661210
661210
661210
661211
661216
661216
661216
661223
661223
661223
661228
661228
. 661228
670105
670106
670107
670108
670109
670109
670110
670111
670111
670111 3
670111
670111
670111
670112
670112
670113
670113*
670113
670114
670114
670114
670115
670121
670121
670121
670121
670121
670121
670124
670124
670125
670125
670125
670125
670125
670126
670126
670127
670127
670127
670127 2
670128
Ptige 11
H
GAL
U
U
U
U
U
U
23
U
U
U
U
U
U
U
U
U
10
UNCLASSIFIED
U 01300 P
T
LEG
COORD
S I
2B WE870960
1B XD020860
1B WE830130
2A WE850070
2B WE870090
1B XD730630
2A XD750630
2B XD750610
1B XD1 18910
1B WD800840
2A WD880710
2B WD840720
1B YT340480
2A YT4 10480
2B YT410410
1B XT520840
2A XT590840
2B XT590770
1A AR760480
1A AR760480
1A AR760480
1A AR760480
1B W064098O
. 1A AR760480
1A AR760480
1B WD990230
1B WD785895
1A XT5 10590 S 2 F
1B XT530620
1A AR760480
1A BR475486
1A BR475486
1A AR760480
1B WE330380
1A BR475486
1A AR760480
1B WD720920
1B WD800760
1A AR760480
1A AR805540
1B YS770692
1C YS923758
1B YA677547
1C YA655555
1B YA677547
1C YA655555
16 YC060970
1B YC060970
18 XD738008
2A YC020980
1B YT 178020
1C YT200200
10 YT 178004
1B YS300790
1C YS340730
1B YD090010
2A YD120010
2B YC080980
1A C0152478 S
1B YD090010
�UNCLASSIFIED
YYMMDD CT2 PRO
670128
670128
670129
670203
670205
600
726
600
726
670206
670210
670211
670212
670213
670213
670214
670216
670218
670219
670219
670219
670220
670220 2
670220
670222
670223
670223
670223
670223
670224
670224
670224
670225
670304
600
734
600
734
6703O4
670304
670304
670304
600
734
600
734
600
734
600
734
670304
600
736
600
736
600
739
600
739
670312
670312
670312
670313
670313
670313
670314
670314
670314
670315
670315
670315
670315
H
GAL
T
U
U
U
U
U
07
U 01300 P
U
U
U
U
U
U
U
LEG
COORD
S I M
2 A YD 160030
2B YD 190030
18 XT620550
18 YB940660
18 YB220800
1B YT956438
2A YT904489
2B YT863434
1A AR80S3SO
1A AR8053SO
1A AR8053SO
18 YS827832
1A AR8053SO
1A AR805350
1B XC940160
18 ZA040430
1B XT909436
1C XT904443
1D XT907443
1B XDO 10450
1A BR465467 S
1A BR472444
18 WD8 17768
18 B0901535
2A 80865534
28 B0890526
18 YT6S1707
1B XT550640
2A XT480S70
28 XT505625
18 YT200600
1A BR726666
18 BR74Q668
2A BR74O664
2B BR727662
3A BR722652
3B BR7356S8
4A BR744649
4B BR725649
5A BR732673
58 BR734677
6A BR744673
68 BR746676
1B XT727300
1C XT768204
1A ZA209946
1B ZA206953
1A YA6 1 6 0
00
1B YA757386
1C YA732504
1A YA6 1 6 0
00
1B YA757386
1C YA732504
1A YA610600
1B YA757386
1C YA732504
18 XR518S48
1A YA6 1 6 0
00
18 YA7S7386
1C YA732504
Page 112
YYMMOD CTZ PRO
670316
670316
670316
670317
670317
670317
670318
670318
670318
670319
670319
670319
670319
670319
670319
670320
670320
670320
670321
670321
670321
670324
670324
670324
670324
670328
670329
670331
670331
670331
600
747
600
748
600
748
670412 1
670412
670414
670415
602
740
670421
602
742
670422
670423
670423
670424
670424
670424
670424
670428
670501
670505
670505
600
7S5
600
756
670511
670511
670512 2
670513
670515
670515
670515
H
GAL
U
U
U
U
U
U
U
U
U
U
03
U 01000
U
U
U
U
U
U
U
07
UNCLASSIFIED
U 02500 P
U 000
30
T
LEG
COORD
S I M
1A YA610600
1B YA757386
1C YA732504
1A YA6 10600
1B YA757386
1C YA732504
1A YA610600
1B YA757386
1C YA7325O4
1B XT700580
1C XT70O590
1D XT620550
1A YA6 1 6 0
00
1B YA757386
1C YA732504
1A YA6 10600
1B YA757386
1C YA732504
1A YA6 10600
1B 7A757386
1C YA732504
1B BQ 790920
1C 80750850
1D B 8 0 0
0090
1B 8 7 0 4
0700
1A BR4754S6
1A 8R475486
1B AT960886
2A AT942864
28 AT947920
1A YA770230
18 YT 130532
1A YA770230
1A BT080700 S Z F
18 BT070740
1A BN750870
1A BN750870
1A AR805350
1A AR805350
1B YA857527
1A AR805350
1B YD640260
1A AR805350
16 BQ790920
1C B0750850
10 B080O900
1A AR805350
18 BR600700
1B Y8560160
1B YT650420
1B AR803353
1C AR8 10356
18 YT294485
1B AR803353
1C AR8 10356
1A BR927755
U BR478486
18 AS995370
2A AT9 1 0 9
00
2B AS930933
�UNCLASSIFIED
YYMMOD CTZ PRO H
GAL
T
LEG
COORD
S I M
YYMMDD CTZ PRO
Page 11.3
H
SAL
T
LEG
COORD
S I M
*
670515
670515
6705 13
6705 15
6705 15
670515
670515
670521
670522
670522
670522
670524
670525
670526
670526
670526
670526
670526
670526
670526
670530
670530
670531
670601
670601
670602
670602
670602
670602
600
762 .
670603
670603
600
763
600
764
600
764
67O605
670605
670605
600 3
766
24
600
766
600
766
600
766
600
767
670607
670607
670608
600
769
23
670610 3
24
670610 3
670610
670610
670610
670610
670610
670611
670613
670615
670615
670615
670615
U
U
U
U
U
U
U 002
00
U
U 002
00
U
U 002
00
U
U 002
00
U
U
U 002
00
U
P
U
U
U
U
U
U
U
U
P
P
1B BS603523
2A BS640369
2B BS543393
1B XT657640
1C XT705657
1D XT657637
18 YA800470
1A XT895065
1B YT470550
1B YT470530
1B YT470550
1A XT895065
1A XT89S065
1B BR950994
1B BS7SS005
1C BR280800
10 BR290670
1E BR780700
1F BR770SOO
1A XT895065
1B BS740050
1A XT895065
1A BT550015
1B BS780980
1A XT650160
1B BS780980
1B AR803353
1C AR8 10356
1A XT895065
1A XT650160
18 BS790980
1A XT895065
1A XT6S0160
U XT895065
1A XT650160
U XT230570
1A BT550015
1A XT650160
1A XT158514 S
1B XT161519
1C XT165515
10 XT 168520
1B YC488840 S
2A YC458909 S
2B YC429944 S
1A XT905058
1A XT905058
1A XT605155 S
1A XT158514 S
18 XT161519
1C XT165515
10 XT168520
1A XT630130
1A XT905058
1A XT905058
1B YT060614
18 YA753383
18 AR803353
1C AR8 10356
1A XT905058
670616
670617
670617
670618
670619
670619
670619
670621
67062 1
670622
. 670622
670622
670622
670622
670626
670626
670626
670626
670627
670627
670627
670628
670628
670628
67O629
670629
670629
602
769
670629
670630
670630
670630
670630
6706 3O
670630
670701
670701
670701
670701
670701
670702
670702
670702
670703
670703
670704
600
774
600
774
670705
670705
670711
670711
6707 1 1
6707 1 1
670711
6707 1 1
670714 2
670714
670715
670716
U
U
U
23
U 01000 D
U 002
00
U 00121
U 00121
U 002
00
U 00121
U 00121
U 002
00
U 00121
U 00121
U
U 002
00
U 00121
U 00121
U 002
00
U 00121
U 00121
U 00121
U 00121
U
U 00121
U 00121
U 00121
U 00121
U
U 00121
U 00121
U 00121
U 00121
08
UNCLASSIFIED
U 0000
30
1A
18
1A
1A
1B
16
1C
1A
1B
1B
1C
10
1E
1F
1B
1A
XT905058
V0890420
XT905058
XT905058
BP9 10020
AR803353
AR8 10356
YT057460 S
YT0574S6
YD030290
YD060350
YD160310
YD060350
YD 100290
YA760385
XT650160
XT650160
1A XT650160
1A XT650160
XT650160
1A XT6S0160
1A XT650160
XT650160
1A XT650160
1B YCS40970
1A XT230S70
1A XT650160
XT650160
1A XT650160
1B YD160100
1C YD125148
1B C 0 0 0
0690
1A XT650160
XT650160
1A XT650160
1B BN993248
2A BR690880
2B BR700820
XT650160
1A XT650160
1A BR4 15400
XT650160
1A XT650160
XT650160
1A XT650160
1A XT230500
XT6S0160
1A XT6S0160
XT650160
U XT650160
1B XT940470
1C XT960160
10 XT980150
1E YT010150
1F YT020140
1G YT010130
1A YA640710 S
18 YA630540
18 BR750820
18 AR803353
*
�UNCLASSIFIED
YYMMDO CTZ PRO
H
GAL
T
LEG
COORD
S I M
YYMMOD CTZ PRO
Page 114
H
GAL
T
LEG
COORD
S I M
a •
670716
670717
670717
670718
670718
670718
670718
670719
670719
670720
670720
670720
670721
670721
670721
670721
670722
670722
670723
670723
670724
670724
670725
670725
602
776
670726
670727
670727
670728
670728
670729 2
670729
670729
670730
670730
670801 2
670801 2
670801
670801
670801
670820 1
670821
670821
670826 2
670826
670826
670826
603 3
780
670831
670912
670913 3
670915
670915 3
670922
670922
670922
670922
670922
670925
670927
13
08
U
U 000
30
U
07
08
U
U
P
P
05
U
U
D
10
U
21
U
P
23
03
23
03
U
U
U
LI
P
P
P
P
U
1C AR8 10356
1B AR803353
1C AR8 10356
1B AR803353
1C AR8 10356
18 BR330600
1C BR4 10600
16 AR8033S3
1C AR8 10356
1B AR803353
1C AR8 10356
1A XT895065
1A YT057486 S
16 YT057640
1B AR803353
1C AR810356
1B AR803353
1C AR8 10356
16 AR803353
1C AR8103S6
1B AR803353
1C AR8 10356
1B AR803353
1C AR8 10356
1B AR803353
1C AR8 10356
1B AR803353
1C AR8 10356
18 AR803353
1C AR8 10356
1A AR792246.S
1B AR803353
1C AR810356
1B AR803353
1C AR8 10356
1A BR465465 S
1A AR805350 S
1B BN523847
2A BN486889
2B BN5 15891
1A BS493045 S
1A BR685430
18 BR620640
1A B0873078 S
18 B0947077
1C B0936056
1D 609 12042
1A YT076759 S
1B B0900130
1B BR 160270
1A XT495473 S
1A BT550015
1A XT895065 S
1A BT467068
1B BT468068
1C BT465073
1D BT467074
1A BS497066
1B XS675021 S
1B YU47S325
F
G
H
H
G
F
670927
670927
670927
670927
67092S
670929
670929
670929
603
790
670930
670930
670930
671001
671001
671001
671001
671003
671003
671003
671003
671003
671004 3
6710O4
6710O4
671004
671004
671004
671004 3
671005
671005
671006
671006 2
671006
671007
671007
671007
671007
671007
671007
671007 2
671007
671009
671009
671009
671009
671009
6710O9
671009
671009
671009
671009
671009
671009
671009
671009
671009
671009
671009
6710O9
671009
U
U
23
U
P
23
U
P
07
U 0000
20
07
U 000 D
30
UNCLASSIFIED
2A YU538368
2B YU455297
3A YU520380
3B YU473290
1A XT895065
1B BR170310
1C BR 170270
1D BR 11 0270
1B BR170310
1C BR 170370
1D BR 110270
1A YTQ78757
1B BR 150230
1C BR 160220
10 BR 160230
1E BR 160240
1B BR 130240
1C BR 130250
1D BR 140250
1E BR 140240
1F BR 140230
1A XT7Q0140 S
1B BR 160250
1C BR 160260 .
10 BR 170240
1E BR 170250
1F BR 170260
1A XT700140 S
1B BR 140270
1C BR 150270
1B YT069388
1A BR163473 S
1B BR1 10260 S
1B BR 130300
1C BR130310
1D BR14O290
1E BR 140300
1F BR 1403 10
1G BR 150300
1A BR 145460 S
1B BR 123290 S
1B BR 180370
1C BR 190380
1D BR 190390
1E BR 1 0 0
940
1B BR200330
1C BR2 10320
10 BR230370
1E 8R240370
1F BR240380
1G- BR240390
1H BR240400
11 BR250410
1B BR180370
1C BR 190380
10 BR 190390
1E BR 1 0 0
940
1F BR200320
1G BR200330
1H BR2 10320
G
H
H
H
F
�UNCLASSIFIED
YYMMDD CTZ PRO
H
GAL
T
LEG
COORD
S I M
Pc.ge 115
YYMMOD CTZ PRO
H
GAL
T
LEG
COORD
S I
a a
671009
671009
671009
671009
671009
671009
671010 3
671010
671010
671010
671010
671010
671010
671010
671010
671011 3
671011 3
671011
671012 3
671012 3
671012
671012
671013 3
671013 3
671013
671014 3
671014 3
671014 3
671015
671020
671020
671020
671023
671024
671025
671027 3
671027 3
671030
671103
671104 3
671104
671104
671106 3
671108
671109 3
671109 3
671109
671109
67 1 1 1 1
671111
67 1 1 1 1
671111
671112
671112
671112
671112 2
671112
671112
671113 3
671113
23
p
U
U
23
23
23
23
23
23
24
24
24
U
U
U
U
U
U
U
U
U
U
U
U
U
U
U
p
p
p
p
p
p
p
p
p
U
U
U
23
23
U
U
p
p
U
23
23
29
23
23
U
U
U
U
U
p
p
p
p
p
U
07
29
U
U
p
p
11 BR230370
U BR240370
1K BR240380
1L BR240390
1M BR240400
1N BR250410
1A XT630130
1B BR2 10340
1C BR220330
10 BR240320
1B BR2 10340
1C BR220330
1D BR240320
1E BR240330
1A BR845945
1A XT593218 S
1A XT700140
1A BR845945
1A XT605155 S
1A XT630130 S
1A BR845945
1A XT700140
1A XT605155 S
1A XT630130 S
1A XT700140
1A XT390240 S
1A XT391245 S
1A XT390240 S
1A BR845945
1A YT897992
1B YT849994
1C YT898985
1A BR845945
1A BR84S945
1A BR845945
1A XT605155 S
1A XT630130 S
1A XT968490
1B BRO 10020
1A XT603155 S
16 YB880270
1C YB890270
1A XT630130 S
1A XT905058 S
1A XT760380 S
1A XT770380 S
1B XT764380
1C XT730385
1B XT700420
1C XT660420
10 XT660380
1A BR478447
1B XT700420
1C XT660420
10 XT66O380
1A BR870960 S
1B BR871955
1C BR655855
1A XT920060 S
1B XT938063
G
G
H
G
G
G
G
H
671113
671114
671116 3
671116
671116
671 116
671116
671116
671116
671117 3
671117
671117
671117
671117 2
671117
671118 3
671118
671119 3
671119
671120 3
671 120
671121
671122
671124
671124
671124
671124
671127 2
671130 2
671210 1
671211 3
671213 3
671223 3
671226
671230
680101 3
680101
680101
680101
680101
680102 3
680102
680102
680102
680102
680102
680103
680103
680103
680104 3
680109 3
680111
680111
680111
680111
680111
680111
680111
680111
680111
23
U
U
U
C
23
U
U
C
11
23
29
23
U OO055 D
U
U
C
U
U
U
P
U
P
U
U
U
U
U
U
U
U 00055 W
U 005 D
05
U
10
11
03
29
23
23
U
U
U
P
P
P
23
U
P
23
U
U
P
U
U
U
23
23
UNCLASSIFIED
U 080P
08
U 090P
09
U
1A XT895065
1A XT840150
H
1A XT660420 S
H
1A XT760370 S
1B XT770380
1B XT700420
1C XT660420
10 XT660380
1A AR805460
C
1A XT660380 S
1B XT700420
1C XT660420
1D XT660380
H
1A B0813154 S
1A AR805460
H
1A XT700380 S
1A AR805460
1A XT895065 S
1A AR805460
1A XT760370
1A AR805460
1A CR080240
1A BR845945
1A XT770380
1A XT760370
1A XT760370
1A XT760370
H
1A BQ870260 S
H
1A B0870260 S
1A BT 133690 S Z F
1A XT895065 S
1A XT760370 S
H
1A XT630130 S
16 YB875203
1B YB880190
1A XT605155 S
1B Y0307412
1B YA739898
1C YA723880
1A XT650160
1A XT605155 S
1B YA726905
1C YA709882
1B YA635815
2A YA6 13730
2B YA635815
1A XT854160
1A XT854160
1A XT854160
H
1A XT630130 S
H
1A XT630130 S
2B XT662175
3C XT665166
40 XT685158
5E XT685153
6F XT637178
1A XT634177
2B XT662175
3C XT665166
40 XT68S1S8
�Oil It. \J
YYMMDD CTZ PRO
H
GAL
T
LEG
COORD
S I M
YYMMDD CTZ PRO
Page 116
H
GAL
T
LEG
COORD
S I M
9 •
680111
680111
680111
680111
680111
680111
680111
680111
680114
680114
680116 3
680129
680130
600
824
680208
600
829
680209
680216 2
680218 2
680218
680218
680218
680218
680222 3
680222
680222
680222
680308
680308
600
838
602 1
830
680322 3
680327 3
680407 1
680407
600 2
847
600
847
60O 2
847
600
847
600
848
6 0 21
84
680421
680421
680421
680423
680424
680426
602
846
680426
680426
602
846
680426
600
852
680505
680506 1
600
856
680506 3
600
856
680508 3
680508
U
23
U 090P
00
07
11
U
P
U 00110 C
23
U 02420 P
U
U
U
02
26
24
02
U
U
U
U
0
P
P
06
U 000D
20
12
U 0800
20
U
O6
U 03000 D
24
U 0000
60
27
U 000D
30
5E XT685153
6F XT637178
1A XT634177
2B XT662175
3C XT665166
4D XT685158
5E XT685153
6F XT637178
1B YA940010
1C YA850070
1A XT630130 S
1B BR466467
1B BR466467
18 XT3378S6
1B YT08O640
1B XT425760
1B XT425760
1A BR465465 S
1A B08O0640 S
1B B0800680
1C BOS 10840
10 BOS 10680
1E B 7 0 9
0960
1A XT953516 S
1A XT280680
1A XT280680
1A XT280680
1B YS 120786 S
1B YS603593 S
1B B0373100 S
1A YD757138 S
1A YT340502 S
1A Y 0 0 8
0045
1A YD409193 S
1B YD501178
1A YA724842 S
1B YA654723
1A BP877980 S
1B CP008031
1B XT707350
1B ZC200319
1C ZC 156252
1D 2C2 13325
1B XT6 18877
1A BR930930
1B YS966739
1B XT770379
1C XT770380
10 XT773372
1E XT777373
1F XT779384
1G XT777373
1B YA750880
1B YA75088O
1A YB740043 S
1B YA705860
1A XT437815 S
18 XT300920
1A YS673620 S
1B YS603593
H
H
H
H
F
F
F
F
F
F
F
F
F
€80509
680509
6805 1 1
680511
680511
680511
680511
6S0511
680511
680511
680511
6805 1 1
680511
680511
680516
680516
680519 1
680520 2
680520
680520
680520
680520
602
850
680520
680520
680521
680523 4
680523
680523
680523
602
853
680524
602
856
680527
680527
603
850
680531
68O601
680601
680601
680601
680601
680601
68O602
600
862
680602
68O602
600
862
600
862
680602
600
862
680603 3
600
863
680603 3
600
863
680603
680603
60O
864
600
864
600 3
865
U
U
U
02
06
U
F
U 000D
30
U
U
U
U
U
U
42
U
U
U
U
U
U
U
U
U 020
00
U
•
U 020
00
U
26
U
21
U 000D
30
26
U 020
00
U
U 020
00
U 00055
U
D
UNCLASSIFIED
0
1B YA650710
' 1B XT168952
1A WR830950
1B WR822946
2A WR845920
2B WR839917
1A WR830950
1B WR822946
2A WR845920
2B WR839917
1A WR830950
1B WR822946
2A WR845920
2B WR839917
1B YS163997
1C YS318667
H
1A YD706102 S
F
1A YA917890 S
1B YA9 12020
1A XT151009
1A BT533094
1A XT 15 1009
1A BT533094
1A XT151009
1A BT533094
1B YS632837
1A W0055487 S E F
1A YT151009
U BT533094
1A YT151009
1A YT1S1009
1A BT533094
1A BT533094
1B AS888880 5
1A BT533094
16 XT910233
1B XT911233
1B XT933253
1C XT923227
10 XT913233
1B YT070692
1A WS815135
1A YD620095
2A XT900230
3A XT9 10220
4A XT910230
1B YS020780
1C YS090780
1B XT099770
1A WS815135
tA BT533094
H
1A XT9 10260 S
1B XT9302SO
F
1A YT133634 S
1B YT 105688
1A WS815135
1A BT533094
1A WS815135
1A BT533094
H
1A XT890280 5
�UNCLASSIFIED
YYMMDD CTZ PRO
680605
680605
630606 1
680606
680606
680606
600
866
600
866
600
866
680606
680607
600
867
680607
680608
680609 3
600
869
600
869
680610
680611
680612
680614
680615
680618 1
680618
680618 3
680618
680618
680618
680618
680619
680619
680619
680624 1
680624
680625
680625
680623
680625
680626
680626
680626
602
866
680626 3
680626
680626
680626
680628
680628
680628
680628
680629
680701
680702
600
872
680702
680703
680703
680703
680703
680703
02
26
H
GAL
T
U 020
00
U
U
D
U
U 020
00
U
U 020
00
U 020
00
U
0
U 020
00
U 020
00
U
U
02
U
D
27
U 000 0
50
U
02
U
F
U 00715
27
U 000 0
30
LEG
COORD
S I M
1A WS315135
1A BT533094
1A YD620095 S
1A Y0878128
1A WS815135
1A BTS33094
1B
657895
1C
645889
10
637897
2A
707884
1B Y0713106
2A Y0803160
1A WS815135
1A WS815135
1A XT931234 S
1B YS605859
1A WSS15135
1A WS815135
1A YD704101
1A XT860150
1B YV880850
1B YD6S0150
1A Y0650130 S
1B YD640170
1A YS282687 S
1B YS282774
1C YS278687
10 YS278774
1A YD808162
1B YD753065
1C YD762061
10 YD761055
1A YD704101 S
1B YSS68800
1A WR830950
2B WR823945
3C WR838917
40 WR845920
1B YC750048
1C YC761055
1D YC715015
1B YC779123
1A YS863979 S
1B YS883977
1C YS968931
10 YS000035
1B YC740065
1C YC712018
10 YC764055
1B YS632808
1B ZB820320
1B YD675002
1B YC620960
1C YC620970
10 YC620980
2A XT877107
3A XT8901CO
4A XT880094
5A XT890105
6A XT880100
H
H
H
F
H
F
YYMMDD CTZ PRO
680703
680703
680703
680703
680704
680704
600
874
600
874
680705
680705
680705
600
376
680706
600
876
600
876
680706
680706
680709
680709
600
879
600
879
600
879
6807 10
680710
680710
680710
680710
680710
680710
680710
680710 2
680710
6807 1 1
6807 1 1
680711
6807 1 1
6807 1 1
6807 1 1
680712
680712
680712
680713
680713
680713
680713
680713
680713
680713 3
680713
680714
680714
680714
680714
680714
680714
680715
680715
680715
680716
680716
Page 117
H
GAL
T
LEG
COORD
1B
1C
1D
1B
18
2A
3A
4A
2A
3A
4A
2A
3A
4A
5A
6A
7A
2A
3A
4A
5A
6A
2A
3A
•4A
5A
6A
7A
S I *
YC620960
YC620970
YC620980
BR 130260
BR812176
XT900105
XT890098
XT900098
XT880093
XT877072
XT880072
XT880072
XT877068
XT880068
XT880080
XT885080
XT880075
XT885076
XT885075
XTSS7072
XT880068
XT886068
XT892077
XT898078
XT898079
XT899080
XT899081
XT894080
8A XT894079
07
UNCLASSIFIED
U 040D
30
1B
1A
1B
2A
3A
YC6689S2
BR932895 S
BR929970
XT884077
XT890079
F
4A XT887078
U
U 000D
50
5A XT890084
6A XT885077
1B BR090240
2A XT890078
3A XT890070
1A Y08O8162
2A XT890074
3A XT895073
4A XT900074
5A XT902071
6A XT895068
7 A XT901069
1A YS171695 S
1B YS058771
2A XT890074
3A XT902074
4A XT902075
1B XS720700
1C XS7 10660
1D XS660680
2A XT890077
3A XT895074
4A XT895077
2A XT895077
3A XT902075
F
�UNCLASSIFIED
YYMMDD CTZ PRO
680716
680717
680717
680717
680717
680717
680718
680718
680718
680718
680718
680719
680719
680719
680719
680719
680719
680719
680720
680720
680720
680720
602
870
680721
680721
680721
680722
680722
680722
680723 1
680723
680723
680723
680724 3
680725
680725
S8072S
680725 3
68O726
680726
680726
680726
602
876
680726
680726
680726
680726 3
680727 3
680727
680728
680728 3
680729
680729
680729
602 2
879
680729
680729
680730
603
870
680730
H
GAL
T
U
10
U 000 0
30
29
U
U
U
0
29
U
D
29
29
U
U
D
0
23
U
P
07
U 000D
20
LEG
COORD
S I M
4A XT902077
2A XT895084
3A XT895074
4A XT902O80
5A XT902077
6A XT890077
2A XT890087
3A XT896079
4A XT89SO79
5A XT895083
6A XT896O87
2A XT903085
3A XT903080
4A XT896079
1B YT200200
1C YT223200
10 YT223276
1A Y0623302
2A XT914100
3A XT9 15097
4A XT9 13093
5 A XT913O92
6A XT908O95
2 A XT903110
3 A XT904103
4A XT900104
2A XT903110
3A XT915100
4 A XT900101
1A B0763920 S
18 B0845730
1A XT953726
1A XT9151S5
1A XT9800SO S
2A XT915117
3A XT912110
4 A XT908110
1A XT980050 S
18 BS657026
1C BS680OOO
10 BS680026
2A XT908113
3 A XT908103
4 A XT9O5104
5 A XT903110
6A XT900110
1A XT980030 S
1A XT980050 S
18 YD70510O
18 YD705100
1A XT980O50 S
2A XT907119
3 A XT9001 13
4A XT907113
1A 8 8 0 3 S
0230
18 80820160
1C 80790160
2A XT915118
3 A XT907118
4A XT914117
F
G
G
G
G
G
F
YYMMDO CTZ PRO
680731
680731
680801
680801
680801
680801
680801
680801
680801
680801
680801
680801
600
883
600
883
600
884
600
884
600
884
600
886
600
885
680805
680805
600
885
600
885
680805
600
885
600
886
680813
680813
680813
680813
680813
680813
680814
680814
680814
680821
680821
680826
680830
680831
680831
600
894
600
895
600
895
600
895
600
895
6809O5
600
896
600
897
600
897
600
897
600
897
600
897
600
897
600
898
600
899
680910
680911
680914
680914
1
02
Page 118
H
GAL
T
U 000 0
30
U
U
U
3
25
U
0
1
05
U
U
U
U
U
P
2
12
U
U
U 00100
1
03
UNCLASSIFIED
U
U
U
U
U
U
U
P
LEG
COORD
S I M
1B AR780340
1C AR780350
2A XT915118
3A XT915120
4A XT911120
5A XT911123
6A XT907124
1A YC761999 S
f
18 Y0734094
1A XT151009
1A XT953726
1A XT953726
1B BR937890
1C BR935970
2A XT907126
3A XT907124
4A XT900124
2A XT911128
3A XT913129
4A XT918129
5A XT917123
6A XT912123
7A XT912120
8A XT911120
9A XT911123
28
713894
1A XT940320 S
2A XT940290
3A XT000320
4A XT000290
1A BS578730 S
G
1A Y0737133
1A BT 199389
1A YD623302
1A BT 199389
1B BP200890
1C BP 100840
1A BP635995 S Z F
18 WS843098
1A 8T533094
1A Y0598256
1B WS713122
1A BT549016 S
18 WS714113
2A WS713111
1A XT895065
1A XT798543
1A XT773615
1B WS812012'
1C WS809003
10 WS795962
1E WR808998
1F WR803982
1G WR802983
1A XT895065
1A XT895065
18 YC549980
1A XT895065
2A XT923133
3A XT913136
�UIMV*rL./*lO ointL-f
YYMMDD CTZ PRO
680914
680914
680915
680916 1
03
680916
680916 1
03
680917
680917 1
03
680918
680918 1
03
680921
68092 1
68092 1
680922
680922
680922
68O924
680924
680924
680925
680926
602
896
680926
680926
680926
602
896
680926
680926
680926
680926
6S0926
680926
680926
680926
680929 3
31
680929 3
21
680929
680930 3
19
681002
681002
681002
681002 1
03
681003 1
03
681004 1
03
681005 1
03
681007
681007
681007
681007
681014 3
29
681014
681014
681014
681014
681016
681017
681017
681017
681018 3
26
681019 3
29
H
GAL
T
U
P
U
P
U
P
U
P
U
U
U
U
U
U
U
U
U
P
P
P
P
P
U 00220 0
U
U 00385 0
U 005 W
05
LEG
COORD
S I M
4A XT912130
SA XT907129
1B YD549940
1A BTS49016 S
1B Y0549940
1A BT533094 S
G
1B XT89O090
1A BT528110 S
G
18 YOS4994Q
1A BT528110 S
G
2A XT904131
3A XT907131
4A XT908142
2A XT912132
3A XT912127
4A XT908123
1B 8 9 0 0 S
0496
2A B0928875 S
2B 80916868 S
18 XT900120
1B XT60515S
1C XT63S291
1D XT639151
1E XT6421S7
1F XT6S0168
1G XT6S3163
1H XT653164
11 XT6S5130
10 XT6S5151
1K XT657161
1L XT6601SO
1M XT662155
1N XT666156
10 XT698151
1A XS408800 S Z F
1A YT440930 S Z F
1A XT89S06S
1A YT280101 S
H
2A XT90B150
3 A XT908160
4 A XT905160
1A BT537004 S
G
1A BT537004 S
G
1A BT51104O S
G
1A BT5 11040 S
G
1A WS797158
18 WS810147
2A WS777129
28 WS769141
1A XS976952 S
G
18 XS971959
2A XT770237
3A XT770220
4A XT780220
1A XT895065
18 X8941243
2A XT098733
3A XT280685
1A XT895065 S
H
1A XS947952 S
H
YYMMOD CTZ PRO
681019
681019 3
681019
681019
681019
681021 3
681021
.681021 3
681021
681021
681021
681021
681021
681021
681021
681021
681021
681022 3
681022
681022
681022
681022
681022 3
681022
681023 3
681023
681023 3
681023
681023 2
681023
681023
681023
681024 3
681024
681024
681024
681024 3
681024
681024
681024
681024
681024
681024 2
681024
681024
681024
681025
681025
681025
681025
681025
681025
681025
681026
681026
681026
681026
681026
681026
681029
Pa.ge
H
GAL
T
18
U 00220
29
U 00082 0
26
U 00110 D
U
U
18
U 00330 0
29
U 00330 0
26
U 00275 0
29
U
13
U 000D
20
26
U 040D
04
31
U 00330 D
11
U 000D
30
UNCLASSIFIED
0
LEG
COORD
119
S I M
16 XS948947
1A YT900170 S
18 YT930170
2A YT900140
28 YT930140
1A YS034962 S
1B YS022963
1A XT907168 S
1A WS724151
18 WS722143
1C WS718136
10 WS713122
1E WS712148
1A WS842094
18 WS844096
2A WSS51086
28 WS354087
1A YT9O8147 S
2A YT912145
3A YT917147
4A YT914161
5A YT909161
1A XS997924 S
18 YS002933
1A XT912166 S
2A XT922156
1A XS971960 S
1B X5976952
1A ZT270273 S
18 ZT233257
1C ZT207208
10 ZT260147
1A XT885192 S
18 XT890182
1C XT888194
10 XT893183
1A XS025950 S
18 XS040945
1C XS045938
10 XS040920
1E XS034920
1F XS027930
1A 80316045 S
18 B0280050
1C B0290080
10 80316045
1B XS958964
1B XS325953
2A XS530930
28 XS488965
16 X5525953 S
2A XS530930 S
28 XS48S965 S
2A XT895192
3A XT893183
4A XT897185
1B XS525953
2A X5530930
28 XS488965
1B XS976982
H
G
G
H
H
G
H
F
H
H
F
F
F
F
�UNCLASSIFIED
YYMMDD CT2 PRO
681029
681029
681029
681030
681030
681030
681030
681031 3
681031
681031
681031
681101
681101
681101
681104 3
681104
681104
681104
681105
681105
681105
681105
681105 3
681105
681106
681106
681107
681107
681107
68.1108
681109
681110
681110
681110
68111.0
68 1 1 10
68 1 1 1 1
681112
681113
681113
681113
681113
681114
681114
H
26
U 00165
26
YYMMDO CT2 PRO
T
U
U 040
04
1B
18
1B
1A
18
2A
2B
1A
2A
3A
4A
1B
1C
1D
1A
1B
2A
2B
XS977994
XS955967
XS989972
WS754Q32
WS785028
WR726998
WR730996
XT932169 S
XT936173
XT936175
XT930171
YS056967
YS050944
YS032962
YS056956 S
YS046968
YS016917
YS042907
G
H
1B YS043934
19
U 000D
60
U
U
U
U
U
681114
681115
681115
681115
681115
681116
681116
681116
681116
681117
681117
681118
681118
681118
681118
681113
GAL
U
U
U
U
U
1C YS049954
1D YS013916
1E YS006906
1A YT660303 S
1B YT524227
1B YS041920
1A BT533094
1B YT080230
18 YT540630
1A BT533094
1B YS019921
1B YS024937
1B XS997922
1C YS053944
10 .YS055946
1E YS020976
1F YS011965
1A BTS 33094
1A BT533094
1B YS022963
2A Y SO 19962
2B YS025937
1A BT533094
18 XT678194
2A XT665170
2B XT683183
18 XT682183
2A XT692203
28 XT697194
1A BT533094
1B XT697194
2A XT705210
28 XT711210
1A BT533094
1B YS020920
1A BT533094
1B YA640780
1C YA630820
1D YA700870
1A XT700330
1A BT533O94
F
681122
681122
681122
681122
681122
681122
681122
681122
681122
681122
681122
681122
681122
681126
681126
681126
681126
681 126
681126
681126
681126
681126
681126
681126
681126
681126
681126
681126
681126
681128
681128
681128
681130
681130
681202 3
681202
68 1 202
681203
681203
68 1 203
681203
681207
681207
681207
681207
681207
681207
681207
681207
681207
68 1 207
681207
681207
681207
681207
681208
681208
681208
681208
681208
Page 120
H
GAL
T
LEG
1B
1C
1D
1E
1F
1B
1C
10
1E
1B
2A
2B
3A
COORD
S I M
XS499459
XS505459
XSS05455
XS500450
XS505455
YB820210
YB850240
YB870240
Y8900270
XT664172
XT697194
XT711210
XT709210
1B BR457494
1C BR46O457
1D BR460470
1E BR460490
1F BR466467
1G BR473435
1H BR473470
11 BR475455
1d BR476476
1K BR476487
U 00100
25
UNCLASSIFIED
U
U
U
U
U
U
U
000
02
000
02
000
02
000
03
0
000
03
1L
1M
1A
18
1C
1D
1B
1A
1A
1A
1A
1A
1A
1A
1B
1C
10
1B
18
1C
10
1E
1F
1G
1H
2A
2B
2C
BR478434
BR480450
WS842094
WS844096
WS851086
WS8S6087
YD842143
WS724151
WS722143
WS718136
WS713122
XT950240 S
W5812168
YD623302
XT962780
XT963880
X5529928
YT59O946
YT130108
YT1 16105
YT 103095
YT 110080
YT093062
YT093050
YT 130050
YT060110
YT09Q112
YT090108
2D YT070107
2E YT066098
2F YT049099
2G YT060110
18 XT605155
1C XT63S291
10 XT639151
1E XT642157
1F XT65O168
�UNCLASSIFIED
YYMMDO CTZ PRO
681208
681208
681208
681208
681208
681208
681208
681208
681208
681208
681208
681208
681208
-681208
681208
681208
681208
681208
681208
681208
681209
681209
681209
681209
681209
681209
681209
681209
681209
681209
681209
681209
681209
681209
681210
681210
681210
681210
681210
681210
681210
681210
681210
681210
681210
681210
681211
681215 3
681215
681215
681217
681217
681217
681217
681217
681217
681217
681217
681217
681217
H
GAL
T
LEG
COORD
1G
1H
11
1d
1K
1L
1M
1N
1B
1C
10
1E
1F
1G
1H
11
10
1K
S I M
XT653163
XT653164
XT655150
XT6S51S1
XT6S7161
XT650150
XT662155
XT666136
BR457494
BR460457
BR460470
BR460490
BR466467
BR47343S
BR473470
BR475455
BR476476
BR476487
1L BR478434
1M BR480450
1B YT130108
1C YT116105
10 YT 103095
_1E YT 11 0 8
00
IF YT093062
16 YT093050
1H YT 130030
2 A YT06O110
28 YT090112
2C YT09O108
20 YT070107
2E YT066098
2F YT049099
2G YT06O110
1B 8R437494
1C BR460457
10 BR460470
1E BR460490
1F BR466467
1G BR473435
1H BR473470
11 BR475455
10 BR476476
1K BR476487
1L BR478434
24
U
U
U
D
1M
1A
1A
1B
1A
1B
1C
10
1E
1F
1G
1H
2A
2B
2C
BR4804SO
BS599919
XT2S8557 S
BR3084S7
XT895065
YT130108
YT116103
YT 103095
YT 110080
YT093062
YT093030
YT 130050
YT060110
YT090112
YT090108
G
YYMMDO CTZ PRO
681217
681217
681217
681217
681218
681218
681218
681218
681218
681218
681218
681218
681218
681218
681218
681218
681218
681218
681219
681219
681220 3
681220
681220
681220 2
681220
681220
681223 3
681223
681227
681227
681227
681228
690103 1
690103 1
690103
690103
690103
690103
690103
690103
690106
690106
690106
690106
690106
69O106
690106
690106
690106
6 0 1O6
9
690106
690106
690106
690106
690106
690106
690106
690106
690106
690106
UNCLASSIFIED
121
H
GAL
T
LEG
COORD
2D
2E
2F
2G
1B
1C
1D
1E
1F
1G
1H
2A
2B
2C
20
2E
S I M
YT070107
YT066098
YT049099
YT060110
YT130108
YT116105
YT 103095
YT 110080
YT093062
YT093050
YT 130050
YT060110
YT090112
YT09O108
YT070107
YT066098
2F YT049099
29
U
07
U 03000 D
23
U
P
03
03
U
U
0
U
U
U
U
U
D
2G YT060110
1B XS86O980
1C XS870960
1A XS860970 S
1B XS860980
1C XS870960
1A CR091440 S
1B CR087498
1C BR990590
1A XT605155 S
1B XT664165
18 BS883055
1C BS875008
10 BS856068
1B XT784139
1A BT452039 S
1A BT292229 S
2A AT86S681
1A BT421048
BT421048
BT452039
1A BT421048
1A BT452039
1B
18
1C
10
1E
VS564638
XT553352
XT362348
XTS55350
XT563353
1F XTS65354
1G
1H
11
10
1K
XT597325
XTS66325
XT5 13350
XT5433S7
XT545352
1L XT544363
1M
1N
10
1P
2A
28
1B
XT337369
XT53736S
XT515376
XT526364
XT5 12405
XTS20394
YA643760
1C YA642640
�UNCLASSIFIED
YYMMDD CTZ PRO
690107
690107
690107
690107
690107
690107
690107
690107
690107
690107
690107
690107
690107
690107
690107
690107
690107
690107
690108
690108
690108
690108
690108
690108
690108
690108
690108
690108
690108
690108
€90108
690108
690108
690108
690108
690109
690109
690109
690109
690109
600
919
690109
690109
690109
690109
690109
690109
690109
690109
690109
690109
690109
690110
690110
690110
690110
690110
690110
690110
690110
H
GAL
T
LEG
COORD
1B VS564638
1B XTS53352
1C XTS62348
1D XT55S350
1E XT5633S3
1F XT365354
1G XT59732S
1H XT566325
11 XT5 13350
10 XT543357
1K XTS4S352
1L XT544363
1M XTS37369
1N XT537365
10 XTS 15376
1P XT526364
2A XTS 12405
2B XT520394
1B XT553352
1C XT562348
1D XT355350
1E XT563353
1F XT5653S4
1G XT597325
1H XT566325
11 XTS 13350
1d XT543357
1K XT54S352
1L XT544363
1M XTS37369
1N XT537365
10 XTS 15376
1P XT526364
2A XTS 12405
2B XT520394
1B XT553352
1C XTS62348
10 XT5553SO
1E XTS63353
1F XT565354
16 XTS97325
1H XT566325
11 XTS 13350
10 XT543357
1K XT545352
1L XT544363
1M XT537369
1N XTS37365
10 XTS 15376
1P XT526364
2A XTS 12405
2B XT520394
1B XT553352
1C XT562348
10 XT5S5350
1E XT563353
1F XT565354
1G XT597325
1H XT566325
11 XTS 13350
YYMMDD CTZ PRO
690110
690110
690110
690110
690110
690110
690110
690110
690110
690111
690111
690111
690111
690111
690111
690111
690111
690111
690111
690111
690111
690111
690111
690111
690111
690111
690112 1
690114 3
690114
690114
690114
690114
690114
690114
69011*4
690114
690115
690116
690117
690117
690117
690117
690117
690117
690117
690117
690117
690117
690117
690117
690117
690117
690117
690117
690117
690117
690117
690117
690117
690117
01
28
UNCLASSIFIED
Page 122
H
U
U
U
U
U
U
U
GAL
T
P
W
LEG
COORD
S I M
U XT543357
1K XT545352
1L XT544363
1M XT537369
1N XT537365
10 XTS15376
1P XT526364
2A XTS12405
2B XT520394
1B XT553352
1C XT562348
10 XTS55350
1E XTS63353
1F XT565354
1G XT59732S
1H XT566325
11 XTS13350
U XTS43357
1K XT545352
1L XT544363
1M XT537369
1N XTS37365
10 XT515376
1P XT526364
2A XTS12405
2B XT520394
1A YD706102 S
1A XS665955 S
18 XT712070
1A BT533094
1A WS845116
1B WS851110
2A WS829103
2B WS829110
3A WS832117
3B WS836100
1A BT535039
1A BT535039
1A BTS35039
1B WS768056
1C WS778043
1D WS7S5046
1E WS784050
1F WS780048
1G WS775055
1H WS777063
1B WS768056
1C WS778043
10 WS785046
1E WS784050
1F. WS780048
1G WS775055
1H WS777063
1B WS768056
1C WS778043
1D WS785046
1E WS784050
1F W5780048
1G WS77505S
1H WS777063
H
�v*i wk»ri<i»jWli
YYMMDD CT2 PRO
690118
690118
690119
690120
690120
690120
690120
690120
690120
690120
690120
690120
690120
690121
690121
690121
690121
690121
690121
690121
690121
690121
690121
690121
690121
690122 1
690122
690122
690122
690122
690122
690122
690122
690122
690122
690122
690123 1
690123
690123 1
690123
690123
690123
690123
690123
690123
690123
690123
69O123
690123
690123
690124
690124
690124
690124
69O124
690124
690124
690124
690124
690124
H
GAL
T
U
U
U
03
U
?
23
U 000 D
70
03
U
U
P
LEG
COORD
S I M
16 X0080450
1A BTS33094
1A BT53S039
1B WS783020
1C WS778017
1D WS782013
1E WS788018
1F WS790026
1B WS783020
1C WS778017
1D WS782013
1E WS788018
1F WS790026
1B XT664165
1A BTS3S039
1B WS783020
1C WS778017
10 WS782013
16 WS788018
1F WS 7 9 0 0
02
1B WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
1A BT5 11040 S
1B WS783020
1C WS77S017
10 WS782013
1E WS788018
1F WS790020
18 WS783020
1C WS778017
10 W5782013
1E WS788018
1F WS790026
1A YT06648S S
1B YT950360
1A BTS 11040 S
1A BT53S039
18 WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
18 WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
18 WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
18 WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
F
•kl'
.*
YYMMOO CTZ PRO
690125
•• 690125
690125
69012S
690125
690125
690125
690125
690125
690125
690126
690126
690126
690126
690126
690126
690126
690126
690126
690126
690127
690127
690127
690127
690127
690128
690128
690128
690128
690128
690128
690128
690128
690128
690128
690129
690129
690129
690129
690129
690129
690129
690129
690129
690129
690201
600
928
600
928
600
928
600
928
600
928
600
928
600
928
600
928
600
928
600
928
600
928
690208
600
928
600
928
UNCLASSIFIED
Page 123
H
GAL
U 00150
T
LEG
COORD
WS783020
1C WS778017
1D WS782013
1E WS788018
1F WS790026
1B WS783020
1C WS778017
10 WS782013
1E WS7S8018
1F WS790026
18 WS 783020
1C WS778017
1D WS782013
18 WS788018
1F WS790026
18 WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
18 WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
18 WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
18 WS783020
1C WS778017
1D WS782013
1E WS788018
1F WS790026
18 WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
18 WS783020
1C WS778017
10 WS782013
1E WS788018
1F WS790026
1A C0934864
18 XT590328
2A XTS90328
28 XT595330
3A XT595330
38 XT566324
4A XTS66327
48 XT5603SO
5A XT560350
58 XT543351
6A XT543351
68 XT5 17384
7A XT5 17384
78 XT520395
8A XT520395
S I M
�UNCLASSIFIED
YYMMDD CTZ PRO
690208
690208
690208
690208
690208
600
928
600
929
600
929
600.
929
690209
690209
'929
600
690209
600
929
600
929
600
929
600
929
600
929
690209
600
929
690209
600
929
600
929
600
929
600
929
600
929
600
929
690210
690210
690210
690210
690210
690210
690210
690210
690210
690210
690210
690210
690210
690211
690211
690211
690211
690211
690211
690211
690211
690211
690211
690211
690211
690211
690211
690211
690212
690212
690212
690212
690212
H
U
GAL
T
LEG
COORD
8B XT514912
9A XT514412
9B XT510412
10A XT510412
10B XT479436
11B XS624887
16 XT590328
2A XTS90328
2B XTS95330
3A XTS9S330
3B XT566324
4A XT566327
48 XT560350
5A XTS60350
SB XT543351
6A XT5433S1
6B XT5 17384
7A XT5 17384
7B XT320395
8A XTS20395
88 XT514912
9A XT514412
98 XT51O412
10A XTS10412
10B XT479436
11A XT479436
118 XT493450
18 XT590328
2A XTS90328
28 XT595330
3A XT595330
38 XT566324
4A XT566327
4B XT560350
SA XT5603SO
5B XTS433S1
6A XT543351
68 XT5 17384
7A XT479436
7B XT493450
18 BN765915
1C BN784888
18 XT590328
2A XT590328
28 XT595330
3A XT595330
38 XT566324
4A XT566327
48 XT560350
SA XT360350
58 XT5433S1
6A XT543351
6B XT5 17384
7A XTS17384
1A BT533094
18 BN765915
1C BN784888
1B XT590328
2A XTS90328
28 XT595330
S I M
YYMMDD CTZ PRO
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690212
690213
690213
690213
690213
690213
690213
690213
690213
690213
690213
690213
690213
690213
690213
690213
690213
690213
690213
690213
690213
690213
690213 1
690214 2
690214
690214
690214
690214
690214
690214
690214
690214
690214
690214
690214
690214
690214
690214
690214
690214
690214
690214
Page 124
H
GAL
T
U
02
10
UNCLASSIFIED
U 020 D
00
U
D
LEG
COORD
S I M
3A XTS95330
3B XT566-324
4A XTS66327
4B XT5603SO
SA XT5603SO
SB XT543351
6A XT543351
68 XTS 17384
7A XT517384
78 XT520395
8A XTS20395
SB XT514912
9A XTS14412
9B XT510412
10A XTS 104 12
108 XT479436
11A XT479436
116 XT493450
1A BT533094
1B XT590328
2A XT590328
28 XT595330
3A XT595330
3B XT566324
4A XT566327
48 XT560350
SA XT560350
SB XT5433S1
6A XTS43351
68 XTS 17384
7A XTS17384
7B XT520395
8A XTS20395
. 8 XT514912
8
9A XT514412
98 XTS 104 12
10A XTS 104 12
10B XT479436
11A XT479436
118 XT493450
1A YD490198 S
1A CR094085 S
18 XT590328
2A XT590328
28 XT595330
3A XT595330
3B XT566324
4A XT566327
48 XT560350
5A XT560350
SB XT5433S1
6A XT543351
6B XTS 17384
7A XTS 17384
7B XT520395
8A XTS20395
SB XTS 149 12
9A XTS 144 12
98 XT510412
10A XTS 104 12
H
F
�UNCLASSIFIED
YYMMDD CTZ PRO
690214
690214
690214
690214
690214
690214
690214
690214
690214
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
6902^15
6902*15
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690215
690216
690216
690216
690216
690216
690216
690217
690217
69O217
690217
690217
690217
690218 2
690218
690218
690218
690218
690218
690218
690219
690219
690219
690219
690219
H
GAL
T
LEG
COORD
S I M
10B XT479436
1 1 A XT479436
10
U
0
11B XT493450
1B WS708104
1C WS694105
10 WS695098
1B WS708104
1C WS694105
10 WS695098
1B XT590328
2A XT590328
28 XT595330
3A XTS9S330
3B XTS66324
4A XT566327
4B XT560350
5A XTS60350
5B XT5433S1
6A XT543351
6B XT5 17384
7A XT5 17384
7B XT520395
8A XT520395
SB XT514912
9A XT514412
9B XTS10412
10A XT510412
10B XT479436
11 A XT479436
118 XT493450
1B WS708104
1-C WS694105
10 WS695098
1B WS7Q8104
1C WS694105
10 WS695098
1B WS708104
1C WS694105
10 WS695098
WS708104
WS694105
WS695098
WS708104
WS694105
WS695098
WS 708 104
WS694105
WS695098
1A CR021011 S
WS708104
WS694105
WS695098
WS708104
WS694105
WS695098
WS708104
WS69410S
WS695098
WS708104
1C WS694105
f
YYMMDD CT2 PRO
690219
690220
690220
690220
690220
690220
690220
690221
69022 1
690221
690222 1
690227
600
932
690302
690303
690303
690303
600
934
690304
690305
690306
690306
690307
690308
600
938
690309 2
690309
690309
• 690310
690310
690310
690310
690312
690312
690312
690312
690312
690312 3
690312
690313
690313
690313
690313
690313
690313
690313
69O313
690313
690313
690313
690313
690314
690314
690314
690314
690314
690314
690314
690314
690314
03
Page 125
H
U
U
GAL
T
P
U
U
07
U
U
U
U
U
f
U
U
23
UNCLASSIFIED
U
U
U
P
LEG
COORD
S I M
10 WS695098
1B WS708104
1C WS694105
1D WS695098
1B WS708104
1C WS694105
10 WS695098
16 XT410180
1C XT420180
1D XT420160
1A BT5 11040 S
1A XT582034
16 YA647630
1C YA647550
1B YB809410
1C YB8 10290
1B YA630730
1B XT665155
1A BT533094
1A BT533094
1B YC983574
1A BT533094
1A BT533094
1A BT533094
1A XT963490
1A BR840040 S
1B BR980880
1A YD808162
18 YA662635
1C YA6625SO
16 YA620710
1A BT533094
18 XT640145
1C XT6351S5
10 XT650170
1E XT670160
1F XT620177
1A XT639151 S
U BT533094
1A BT533094
1B XS640925
1C XS587900
1D XS596907
1E XS640900
1F XS635907
1G XS603850
1H XS625865
11 XS660865
1d XS605810
1K XS640810
1C XS653835
18 XS640925
1C XSS87900
1D XS596907
1E XS640900
1F XS635907
1G XS603850
1H X5625865
11 XS66086S
1d XS605810
F
G
�911 IL.LS
UNCLASSIFIED
YYMMDD CTZ PRO
690314
690314
690314
690315
690315
690315
690315
690315
690315
690315
690315
690315
690315
690315
690315
690315
690315
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690316
690317
690318
690318
690319
690320 1
690321
690322
690322
690323
690323
690323
690323
690324
690325
690326
690327
690327
690327
690327
690327
690328
690328 1
690328
602
939
H
U
U
U
U
03
U
U
U
U
U
U
01
U
U
U
GAL
T
LEG
COORD
S I M
1K XS640810
1L XS653835
1A BTS33094
1B XS745870
1A BT533094
1A XT582034
18 XS640925
1C XS587900
10 XS596907
1E XS640900
1F XS635907
1G XS603850
1H XS625865
1! XS660865
U XS605810
1K XS640810
1L XS653835
16 XS570940
1C XSS70943
1D XS575950
1E XS575960
1F XS567960
1G XS367955
1H XS550955
11 XS550940
18 XS640925
1C XS587900
1D XS596907
1E XS6409OO
1F XS635907
1G
603850
1H
625865
1I
660865
1d
605810
1K
64O810
1L
653835
1A BT533094
18 XT670160
1A BT533094
1A BT533094
1A BTS49016 S
1A BT533094
18 XT627168
1A BT533094
18 XT653163
1C XT655150
1D XT657161
1E XT653164
1B BR570445
1A BT533094
1B XT215430
18 AT970600
1C AT980600
10 AT9836OO
1E BTO12560
1F AT970570
18 XT04SS43
1A Y089S1SO S Z F
1A 8T533094
1A BT533094
YYMMDO CTZ PRO
690331
690401 1
690401
690401
690402
690402
690402
690402
690402
690402
600
942
690402
600
942
69O402
600 3
942
600
942
690402
69O403
690404
690407
600
948
600
949
690411
690412
690414
690415
690416
690417
69O4 1 7
690417
690418
690418
69O418
690418
69O418
690419
690419 2
690419
69O419
690421 3
690421
602 1
942
690422
690423 3
690423
690423
69O423
690423
690423
690423
690424
690424
690424
690424
690424
690424
690424
690424
69O425
602
945
03
21
Page 1 26
H
GAL
T
U
U
U
U
U 02OOO D
U
U
U
U
U
U
U
U
U
U
U
U
U
06
23
03
23
UNCLASSIFIED
U 000D
30
U
U
D
U
U
U
U 000D
20
LEG
COORD
S 1[ M
1A BT533094
1A BTS49016 S
1A BT533094
1A BT421048
1B BS809374 .
1C BS828374
10 BS828390
1E BS814390
1F BS814398
18 BS809374
1C BS828374
1D BS828390
1E BS8 14390
1F BS8 14398
1A YT020585 S
1B YT070586
1A BT533094
1A BT533094
1A BT533094
1A BTS33094
1A BT533094
1A BT533094
1B YC457998
1A BT533094
1A BT533094
1A BT533094
1A BT533094
18 BR135249
1A 8T533094
1A XT653153
18 XS522996
1C XS5 18990
10 XS511999
1E XT516012
. 1A BT533094
1B YD550035
1A Y8911780 S
1B YB888620
1A BT533094
1A XT674378 S
1A BT533094
1A BT480230 S R
1A BR533094
1A YT017580 S
18 YTO 17480
1B BS917239 S
1C BS914246 S
1D 85916256 S
1E BS9 12259 S
1F BS9012S9 S
18 8S917239 S
1C BS914246 S
10 BS916259 S
1E BS9 12259 S
1F BS901259 S
18 XT 4 0 9 3
94
1C XT500490
10 XT500475
18 XT490493
1C XT50O490
F
F
G
F
F
H
H
H
H
H
H
H
H
H
H
�UIVVSL./1O oini-L*'
YYMMDO CTZ PRO
690425
690425
690425
690425
690425
690425
690426
690426
690426
690426
602
946
690426
690426
690426
690426
690427
690427
690427
690430
600
952
690502
690502
690505
690505
600
955
690505
6905O5
69050S .
690505
690505
690505
690505
690505
690505
690507
690507
690507
690507
6905O7
690507
690507
690510 2
690510
690510
690511
6905 1 1
690511
690511
690511
6905 1 1
6905 1 1
6905 1 1
690511
6905 1 1
690512
690512
690512
690512
690512
690514
H
GAL
T
U
U
08
U
U
U
U
U
U
U
P
LEG
COORD
S I M
1D XT500475
1B BS9 17239
1C BS914246
10 85916256
1E BS9122S9
1F BS901259
1B XT490493
1C XT500490
10 XT500475
1B AT957891
16 BS917239
1C BS914246
10 BS916259
1E BS9 12259 S
1F BS901259 S
1B XT490493
1C XT500490
10 XT500475
1A XT776066
1B XT276615
2A XT276615
'2B XT287640
1B 8S809374
1C BS828374
10 BS828390
1E 85814390
1F BS8 14398
1B BS809374
1C BS828374
10 BS828390
1E BS814390
1F BS814398
18 XT8 13077
1A BT555035
18 XT253340
2A XT253340
28 XT347330
3A XT350296
38 XT373263
18 Xt276615
1C XT287640
1A YA936931 S
18 ZA030930
1A BT533094
1B BS809374
1C 8S828374
10 BS828390
1E BS8 14390
1F B5814398
1B BS809374
1C BS828374
10 BS828390
1E BS8 14390
1F B5814398
1A BT533094
1A XT629663
1A XT962497
1A XT481715
1A XT538806
1B XT463400
H
H
YYMMDO CT2 PRO
690515
690515
690515
690516
690516
690519
690519
690519
690519
690519
690519
690519
690519
690519
690519
690521
690521
69052 1
690522
690523
690524
690S25
690526
690526
602
956
690527
690528
690528
690528
690528
690529 1
690529
690529
690529
690530
690531
690602 3
690602
600
962
690602
690602
690602
600
962
600
962
690603
690604
6906O5
690605
600
965
690605
690605
600
966
600
967
600
968
600
968
690610
690610
690610
690610
6906 1 1
Page 127
H
GAL
T
U
-
U
U
U
U
U
U
U
OS
U
U
U
U
U
U
26
UNCLASSIFIED
U 0000
20
U
U
U
U
U
U
U
U
U
U
U
U
U
LEG
COORD
S I' M
18 XT308014
1C XT513018
10 XT5 11009
1A BT533094
1B ZA008964
1B XT458390 S
1C XT4644OO S
10 XT482410 S
1E XT484418 S
1F XT498385 S
1G XT538344 S
1H XT520345 S
11 XT5 10327 S
10 XT492317 S
U BT533094
1B XT101712
1C XT197891
1A BT533094
1A BT533094
1A BT534036
1A BT533094
1A BT533094
18 8R800970
1C BR850050
10 BR860970
1A BT533094
18 XS970900
18 WS805135
2A WS819130
2B WS817126
1A BS538824 S
1A XT527588
1A BR929756
1A X7481715
1A BT534036
1A 8T533094
1A YT020585 S
18 YT070586
1A BT533094
1A XT9 14584
1B YT020585
1C YT070586
1A YT020585
1B YT070586
1A 8T533094
1A BT533094
18 8S6843OO
1C BS746507
2A BS675532
28 BS672400
1A BT533094
1A BT533094
1A BT533094
18 ZV174148
1C ZV098222
1A XT955490
1A XT483553
1A YT678256
1A BT533094
1A BT533094
H
F
�wi nvsfc-J—kv.IWII
YYMMDD CTZ PRO
690613
6906 1 3
690613
690613
690613
690613
690615
690615
690615 3
690615
690615
690615
690615
690615
690615
690615
690616 3
690616
690616
690616
690616 3
69O616
690616
690616 3
690616
690616
690616
690616
690616
690616
690616
690617 3
690618 3
690618
'690618
690618
690618
690618
690618
69O618
690618
690618
690618
690618
690618
690621
69O621
690621
69062 1
690621
690621
690621
690621
690621
69062 1
690621
690621
690621
690621
690621
H
GAL
T
24
U
P
23
U
U
24
U
0
24
U
P
24
24
U
U
P
P
LEG
COORD
S I M
1B WR856885
2A WR860886
2B WR864886
1B WR956885
2A WR8809SO
2B WR865918
1B XT779065
1B XT779065
1A XT764380 S
18 XT770379
1C XT770380
10 XT773372
1E XT777372
1F XT779384
1G XT783388
1H XT784379
1A XT774066 S
1B XT774067
1C XT776067
10 XT774066
1A XT430870 S
18 XT4 10800
1C XT330750
1A XT764380 S
1B XT770379
1C XT770380
1D XT773372
1E XT777372
1F XT779384
1G XT783388
1H XT784379
U XT370630 S1A XT764380 S
18 XT770379
1C XT770380
1D XT773372
1E XT777372
1F XT779384
1G XT783388
1H XT784379
18 XT150S10
1C XT158513
1D XT165S15
1E XT 142523
16 XT660130
1B XT085598
1C XT086595
1D XTOS5592
1B XT653164
1C XT655150
1D XT655151
1E XT6S7161
18 BT760168
1C BT792153
2A BT727166
2B BT760166
2C BT788152
3A BT726163
3B BT766163
3C BT78S152
G
G
F
G
G
IL_l«r
Page
YYMMDD CTZ "PRO
690622
690622
690622
690622
690622
690622
690622
690622
690622
690623
690623
' 690623
690623
690623
690623
690623
690623
690623
690623
690623
690623
690623
690623
690623
690624 3
690624
690624
690624
690624 1
690624
690624
690624
690624
690624
690624
690624
690624
690624
690624
690625 3
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690625
690626 3
602
966
690626
H
GAL
T
23
U
U
03
U
U
D
24
U
P
23
U
U
U
UNCLASSIFIED
LEG
COORD
128
S ! M
1B WS706030
2A WS7 11025
2B WS720036
1B WS775036
2A WS766030
2B WS775030
1B WS874010
2A WS865005
2B WS873003
18 XT490480
1C XT491473
1D XT492472
1E XT495473
1F XT495479
1G XT496477
1B WS706030
2A WS7 11025
2B WS720036
18 WS775036
2A WS766030
28 WS775030
18 WS874010
2A WS865005
2B WS873003
1A XT774066 S
1B XT774067
1C XT776067
10 XT774066
1A AT865681 S
1A BT421048
1B WS706030
2A WS7 11025
28 WS720036
1B WS775036
2A WS766030
26 WS775030
1B WS874010
2A WS8650O5
28 WS873003
1A XT764380 S
1B XT770379
1C XT770380
10 XT773372
1E XT777372
1F XT779384
1G XT783388
1H XT784379
18 WS874010
2A WS865005
2B WS873003
18 WS7O6030
2A WS7 11025
26 WS720036
1B WS775036
2A WS766030
28 WS775030
1A XT387624
1A XT774066 S
1B XT774067
1C XT776067
G
G
G
G
�711 IL.LS
UNCLASSIFIED
YYMMDD CT2 PRO
602
966
690626
690626
690626
690626
690626
690626
690626
602
966
602
966
690627 1
690627
69O627
690627
690627
690627
690627
690627
690627
690627
69O627
690627
602
968
69O628
690628
690628
690628
69O628
690628
690628
690628
690628
690628
€90628
690628
690628
69O629
690629
69O629
602
969
690629
690629
602
969
690629
690629
602
969
690629
602
969
602
969
602
969
602
969
690629
690629
690629
690629
690629
602
969
690630
690630
690630
02
H
GAL
T
U 00110 P
LEG
COORD
S I M
1D XT774066
1B WS874010
2A WS865005
2B WS873003
1B WS706030
2A WS711025
2B WS720036
1B WS775036
2A WS766030
2B WS775030
1A YD797109 S
1B WS813000
1B XT598263
1B WS874010
2A WS865005
2B WS873003
1B WS706030
2A WS711025
2B WS720036
1B WS775036
2A WS766030
28 WS775030
1B CR850950
1B WS8130OO
18 WS874010
2A WS865005
2B WS873003
18 WS706030
2A WS711025
28 WS720036
18 WS775036
2A WS766030
2B WS775030
1B WS730083
2A WS741088
2B WS730083
18 WS813000
18 XT605300
1C XT636307
1D XT636305
1E XT605296
1F XT595280
1G XT623283
1H XT638268
11 XT6B0269
10 XT650253
1K XT638254
18 WS874010
2A WS865005
28 WS873003
1A WS717039
18 WS706030
2A WS711025
2B WS720036
1B WS775036
2A WS766030
2B WS775030
18 WS813000
18 WS874010
2A WS865005
Page 129
YYMMDD CT2 PRO
603
960
690630
690630
6 0 3
9 6 0
690630
690630
690630
690701
690701
690701
690701
6907O1
690701
690701
690701
690701
690702
690702
690703 3
690703
690703
600
973
69070S 3
600
97S
690705
600
97S '
600
975
690705
690705
600
975
600 1
976
600
976
600
976
600
976
S90706 1
600
976
600 1
977
690707
600
977
600
977
600 1
977
600
977
600
977
690707
600
977
690707
600
977
600
977
600
977
600 1
978
600
978
600
978
600
978
69O708 3
600 1
978
600 1
979
600
979
600
979
600
979
600 3
979
H
GAL
T
26
U 000 D
40
24
U
P
03
U
D
03
D
03
U
U
U
03
U
03
U
24
03
03
U 00055 P
U
D
U
D
24
U
UNCLASSIFIED
0
D
P
LEG
COORD
S I M
2B WS873003
1B WS706030
2A WS7 11025
2B WS720036
1B WS775036
2A WS766030
28 WS775030
1B WS706030
2A WS7 11025
2B WS720036
1B WS775036
2A WS766030
2B WS775030
1B WS874010
2A WS865005
2B WS873003
1B BR793050
1B AP890648
1A YT070256 S
1B YT984304
1C YT070258
1D XT985308
1A XT490470 S
1B XT490480
1C XT491473
10 XT492472
1E XT495473
1F XT495479
1G XT496477
1B XT093780
1A ST507036 S
18 6T514505
1C BT515051
2A BT345064 .
1A BT549016 S
1A ES601920
1A BT507036 S
1B BT5 14505
1C BT5 15051
2A BT545064
1A BT549016 S
18 XT640227
1C XT654228
10 XT665240
1E XT696210
2A XT680178
2B XT693185
2C XT688176
2D XT 80173
1A BT507036 S
1B- BT514505
1C BT515051
2A BT545064
1A XT388627 S
1A BT549016 S
1A BT507036 S
1B BT5 14505
1C BT5 15051
2 A BT 54 5 6
04
1A XT490470 S
-
F
H
H
H
H
H
G
G
H
H
�UNCLASSIFIED
YYMMDD CT2 PRO
H
GAL
^
LEG
COORD
S I M
Page 130
YYMMDD CTZ PRO
H
GAL
T
LEG
COORD
S I M
•*
690709
690709
690709
600
979
690709
690709
690709
690709
690709
690710
690710
690710 2
690710
690712
690712
690712
690712
690714
69O714
690714
690714
690717 2
690717
690717
690718
690718
690718
690718
690718
690718 2
690718
690718
690719 2
690719
690719
690721 3
690721
690721
690721
690721
690721
690721
690724 2
690724
690724
690729 1
690729 2
690730 1
690730 2
690731
6 0 31
97
690731 1
690731 2
690801 1
690801
690801
690801
690801
690801
690801
11
07
U
U
U
U
U
U
D
07
U
D
07
U
D
24
U
P
07
U
D
03
08
03
08
U
U
U
U
D
D
D
D
03
08
03
U
U
U
0
D
D
1B XT490480
1C XT491473
1D XT492472
1E XT495473
1F XT49S479
1G XT496477
1B XT 130040
1C XT 110050
1D XT 130050
2A XT055635
3A XT093635
1A ZV180110 S Z F
16 ZV173133
1B XT656175
1C XT684156
1D XT6831S3
1E XT640168
1A XT95S908
1A YU036067
1A XU905022
1A XT955490
1A BS920207 S
H
16 BS9 19202
1C BS9 16208
18 XT660167
1C XT66S160
1D XT663150
1E XT6S0140
1F XT646140
1A BS92O207 S
H
1B BS9 19202
1C BS916208
1A BS920207 S
H
1B BS919202
1C BS9 16208
1A XT490470 S
H
1B XT490480
1C XT491473
1D XT492472
1E XT495473
1F XT495479
1G XT496477
1A BS920207 S
H
1B BS919202
1C BS9 16208
1A BT510040 S
H
1A ZA230S30 S
1A BTS 10040 S
H
1A ZA230530 S
2A XT056593
3A XT503377
1A BTS10040 S
H
1A ZA230S30 S
1A BT507036 S
H
1B BTS 14505
1C BTS 15051
2A BT54S064
1B YT 142002
1C YT 150010
10 YT154015
690801
690801
690801
690801
690801
690801
690801
690801
690801
690801
690801
690801
690801
690801 2
690802 1
690802
690802
690802
690802
690803 4
600
983
600
983
600 4
983
690803
690803 4
600
983
600
983
600
983
600 4
984
600
984
600
984
600 4
984
600
984
600 4
984
600
984
600 4
984
600
984
600 4
984
600
984
600
984
600
984
690804 3
690805 4
690805
600
985
690805 4
690805
600 4
985
600
985
600 4
985
600
985
690805
690805
690805 1
690805
690805
690805
600 4
986
600
986
600 4
986
•
08
03
U
U
D
D
40
U
F
40
U OOO55 F
40
U
F
40
U
F
40
U 005 F
05
4O
U 005 F
05
40
U 00055 F
40
U
F
29
U
P
40
U
F
40
U OOO55 F
40
U 00055 F
40
U
F
03
U
D
40
U 005 F
05
40
U
UNCLASSIFIED
F
1E YT15S01S
1F YT 160005
1G YT160010
1H YT161006
11 YT162998
2A YT 165000
2B YT 16 5004
2C YT 165005
. 20 YT 166002
2E YT 167007
3A YS14S982
3B YS 167994
3C YS318667
1A ZA230530 S
1A BT507036 S
1B XS576857
18 XS581856
1C XS608876
10 XS624860
1A WS791080 S
1B WS300080
1C WS791084
1A WS820075 S
1B WS827073
1A WS793077 S
1B WS798073
1C WS802080
10 WS801084
1A WS791080 S
1B WS800080
1C WS791084
U WS700030 S
1B WS7 12032
1A WS7 12024 S
1B WS7 14033
1A WS820075 S
1B WS827073
1A WS793077 S
18 WS798O73
1C WS802080
10 W5801084
1A XS752937 S
1A WS791080 S
1B WS800O80
1C WS791084
1A WS700030 S
1B WS7 12032
1A WS7 12024 S
1B WS7 14033
1A WS793077 S
1B WS798073
1C WS802080
1D WS801084
1A BT507036 S
1B BT51450S
1C BT515051
2A BT545064
1A WS700030 S
1B WS7 12032
1A WS793077 S
H
G
G
G
G
G
G
G
G
G
G
G
G
G
H
G
G
�UNCLASSIFIED
YYMMDD CTZ PRO
H
GAL
T
690806
690806
690806
600 1
987
03
U
P
690807
690807
690807
690807
600
988
690808
690808
690808 1
03
U
P
690808
690808
690808
690808
690808 3
24
U
P
.690810
690810
690810
690810
690810
690810
690817 1
03
U
P
690812
6908 1 2
690812
690813 1
03
U
P
690813
690813
690813
690815 1
03
U
P
690815
690815
690815
690815
690816 1
03
U
P
690816
690816
690816
690817 3
21
U
C
690817
690817 3
21
U
C
690817
690817 1
03
U O600O D
6908 1 7
690817
690818 1
03
U
P
690818
690818
690818
690818 1
03
U 000D
40
690818
690818
690820
U
690822
U
690823
U
690825 4
40
U 000F
05
690825
690825
LEG
COORD
S I M
18 WS798073
1C WS802080
10 WS801084
1A BT507036 S
H
1B BTS 14505
1C BTS 15051
2A BT545064
1B XT650167
1B XT645165
1C XT645162
10 XT637154
1A BT50703G S
H
1B BTS 14505
1C 8T5150S1
2A BT545064
18 XS660928
1A XT482715 S
G
18 BP573230
2A BP60O254
28 BP582200
2C BP575240
18 2U088819
1C 2U067832
1A BT507036 S
H
18 BTS 14505
1C BTS 15051
2A BT545064
1A BTS07036 S
H
18 BTS 14505
1C BTS 15051
2A BT545064
1A BT507036 S
H
18 BT5 14505
1C BT515051
2A BT545064
18 YS266834
1A BTS07036 S
H
1B 8T514S05
1C BT515051
2A 8T545064
1A YU241070 S
H
18 YU233066
1A YU270090 S
H
18 YU278086
1A ZC060930 S
F
18 ZC06O860
1C 2C1 10848
1A BTS07036 S
H
18 BTS14S05
1C BTS 15051
2A BT54S064
1A ZC053927 S
F
18 2C053867
1C ZC 110852
1A XT9SS490
1A XT16SS15
1A XT925442
1A WS716131 S
G
18 WS713124
18 XT093627
P^ge 131
YYMMDD CTZ PRO
69082S
690825
690825 1
03
690825
690826 4
40
690826
690826 1
02
690827 4
40
690827
690829 1
03
690829
690829
602
989
690830 1
03
690830
690830
690830
69O830
690831 4
40
690831
690831 1
03
690831
69083 1
690831
690901 4
40
690901
690901 4
40
6909O1
600 4
992
40
69O902
600 1
992
03
600
992
600
992
600
992
690902 3
25
600 4
993
40
690903
690903 1
03
690903
69O904 4
40
600
994
69O904 1
03
600
994
69O904
600
994
600
994
69O905
600
995
690905
690905
600 1
996
03
600
996
600
996
600
996
600
996
600
996
600
996
600
996
6909O6
600
996
UNCLASSIFIED
H
GAL
T
U 03000 D
U 000F
05
U
D
U 00050 F
U
P
U
P
U 00045 F
U
P
U 00045 F
U
F
U
F
U
P
U
U
C
F
U
P
U
F
U
P
U
U .
P
U
P
U
U
LEG
COORD
S I M
1C XT176697
1D XT493333
1A ZC155224 S
1B 2C213162
1A WS716131 S
1B WS713124
1A YD706102 S
1A WS716131 S
18 WS713124
1A BT507036 S
1B BTS 14505
1C BTS15051
2A BT545064
1A BT507036 S
1B BTS14S05
1C BTS150S1
2A BT345064
2A YC7S78S4 S
1A WS699075 S
1B WS705074
1A 8T507036 S
18 BTS 14505
1C BTS15051
2A BT545064
1A WS699075 S
18 WS705074
1A W5694049 S
18 WS708046
1A WS694049 S
18 WS708046
1A BT507036 S
18 BTS 14505
1C BTS 15051
2A BT545064
1A XT863S92 S
1A WS694049 S
1B WS708046
1A BTS07036 S
18 BS5659S7
1A WS694O49 S
18 WS708046
1A BTS07036 S
18 BT514505
1C BT515051
2A 8T545064
1A XT955490
1A BT507036 S
18 BTS 14505
1C BTS15051
2A BT545064
1A BT507036 S
18 BTS 14505
1C BTS 15051
2A BT545064
1A TF830650
18 UH022660
2 A TF 8406 10
28 TF830650
1A UF300820
18 UF350830
F
G
H
G
H
H
H
G
H
G
G
G
H
H
G
H
G
H
H
H
�VHP* *WI»iS-*W Wll IL_IW
YYMMDD CTZ PRO
690906
690906
600
996
600
996
690907
600
997
690907
600
997
600
997
690910 3
690912 1
690912
690912
690912
690913 1
690913
690913
690913
690915 1
690915
690915
690915
690919 3
690920 4
602
990
690921 4
690921
690921 4
690921
690921 3
690921
690921
690921
690921
690921
690922 4
690922
690922 4
690922
69O923 4
€90923
690923
690923
690923
602 3
993
690924
690924
602 1
995
690927 4
690927
690928
690928
603 3
990
690930
690930
690930
690930 3
690930
603
990
603
990
H
T
GAL
U
25
03
U
U
C
P
03
U
P
03
U
P
26
40
U
P
U 000 F
04
40
U 000f
04
40,
U OO040 F
47
U 00160 D
U
U
40
U 00160
U 000F
04
40
U 000F
04
40
U 000F
04
24
U 00110 P
U
03
40
U
P
U 000 F
04
21
U 020
02
U 00110
U 003 C
02
21
U 000C
03
LEG
COORD
S I M
2A UF340790
2B UF240770
3A UF240800
3B UF 3 0 20
08
1A TF730610
1B TF800620
2A TF800635
2B TF725640
3A TF730610
1A XT863593 S
1A BTS07036 S
16 BT5 14505
1C BT5 15051
2A BT545064
1A BT507036 S
1B BT5 14505
1C BT5 15051
2A BT545064
1A BT507036 S
1B BT514505
1C BTS 15051
2A BT545064
1A YT069120 S
1A WS605100 S
1B WS590066
1A WS605100 S
1B WS590066
U WR556993 S
1B WS556004
1A XT967449 S
1A XT098763
1B XT098550
1A XT098763
1A XT098558
1B XT967490
1A WS605100 3
18 WSS9O066
1A WR556993 S
1B WS5 5 0 4
60
1A WR556993 S
IB WS556004
1B XT545245
1C XT5 16224
1D XT511210
1A XT482715 S
1A XT098763
1B XT0983S8
1A BT529088 S
1A WR734937 S
1B WR773956
1A XT955490
1A AT945405
1A YU236187 S
1B YU235188
1C YU243193
10 YU243190
1A YU264107 S
1B YU267108
1C YU274097
10 YU268094
H
H
H
H
G
G
G
G
H
G
G
G
H
H
G
H
H
Page 132
YYMMDD CTZ PRO
690930 3
690930
690930
690930
603
990
690930
690930
690930
690930
691001 3
691001
691001
691001
691001
691001
691001 .
691001
691002 3
691002
691002
691002
691002
691002
691002
691002
691003
691003
691003
691003
691003
691003
691003
691003
691003
691003
691003
691003
691003
691003
691003
691003 3
691003
691003
691003
610
903
691003
691003
691003
691003
691003
691003
691003
691003
691003
691006 3
691006
691006
691006
691006
691006
H
GAL
T
21
U 005 C
05
24
U
P
24
U
P
24
U
P
U
U 00110
U
U
24
UNCLASSIFIED
U
P
LES
COORD
S I M
1A YU254168 S
1B YU260169
1C YU269167
1D YU364167
1E YU264160
1F YU272140
1G YU260144
1H YU267143
11 YU254168
1A XT764380 S
1B XT770379
1C XT770380
10 XT773372
1E XT777373
1F XT779384
1G XT783388
1H XT784379
1A XT764380 S
1B XT770379
1C XT770380
10 XT773372
1E XT777372
1F XT779384
1G XT783388
1H XT784379
1B YT258981
1C YT27798S
1D YT25S984
1B YT254986
1C YT256988
10 YT248988
1B YT250988
1C YT254989
1D YT252990
1B YT250988'
1C YT254989
10 YT25O990
1B YT247988
1C YT246990
10 YT244990
1A XT764380 S
1B XT770379
1C XT770380
10 XT773372
1E XT777372
1F XT779384
1G XT783388
1H XT784379
1A XT905058
1A YU 140070
1A XT098763
1B XT098550
1A XT098763
1B XT098558
1A XT764380 S
1B XT770379
1C XT770380
1D XT773372
1E XT777372
1F XT779384
H
H
„
H
H
H
�WIHVSL.J"*w «JII IL.LX
YYMMDO CTZ PRO
691006
691006
691006 1
691006
691008
691008 3
691008
691008 3
691008 3
691008 3
§91008 3
691008 3
691008 3
691008 3
691008 3
691009
691009
691010 1
691010
691011
691012
691013
691013
691013
691013
691013
691013
691013 2
691014
691014
691014
691014 3
691014
691014
691014
691014
691015
691015
691015
691015 3
691015 3
691015 3
691015 3
691016
691016
691016
691016 3
691017
691017
691017
691017
691017 3
691017 3
691017
691017
691017
691018
691018
691018
691019
H
GAL
T
LEG
COORD
S I M
1G XT783388
1H XT784379
02
U 000 D
60
21
U
C
21
21
21
21
21
21
21
21
U
U
U
U
U
U
U
U
C
C
C
C
C
C
C
C
03
U
P
U 00110
21
19
U 00110 P
U 03000 D
1A
1B
16
1A
1B
1A
YC490839 S
YC368998
XT6661S3
XU996155 S
XU992146
XU99314S S
1A XU977149 S
1A XU987147 S
1A XU994140 S
1A XU999148 S
1A XU991435 S
1A XU990145 S
1A XU9891S5 S
1B XT640164
1B ZU1001S5
1A BT173077 S
1A XT629652
1B YD620095
1B YD706102
16 XT171526
2A XT 1605 13
2B XT 1645 13
1B XT161519
1C XT165515
10 XT 168520
1A YU036067 S
1B XT171526
2 A XT1605'13
2B XT164S13
1A YT 199543 S
1B YT262488
1C YT263400
F
H
H
H
H
H
H
H
H
H
F
F
1D YT248378
21
21
21
21
U
U
U
U
OOO40
000
04
000
03
00220
D
D
D
D
21
U OOO65 D
21
19
U 00220 D
U 000 D
60
1B YD620095
1B XT171526
2A XT160513
2B XT164S13
1A XU960030
1A YT020990
1A YT080950
1A YU250090
1S XT171526
2A XT160513
2B XT164513
1A YT 130990
1B XT171526
2A XT 1605 13
2B XT164513
1B XT655168
1A YT070950
1A YT418563
1B YT364515
1C YT363437
10 YT380410
1B XT171S26
2A XT160513
2B XT164513
16 XT171526
S
S
S
S
H
H
HH
S
H
S
S
H
f
Page
YYMMDO CTZ PRO
691019
691019
691019 3
691019
691020
691020
691020
691020 1
691020
691021
691021
691021
691021 3
691021 2
691022
691022
691022
691022 3
691022 3
691023
691023
691023
691023 3
691023 1
691024
691024
691024
691024 3
691024
691025 1
691026 1
691027 1
691028
691028 3
691028
691028
691028
691028
691028
691028
691028
691029
691030
6911O5
6911O9 3
691109
6911O9
691109
691109
691109
691109
691110 3
691110
691111 3
6911 11
691111
69 1 1 1 1
691111
691111
691111
H
GAL
T
LEG
COORD
133
S I M
2A XT160513
2B XT 1645 13
21
U 00110 0
U
03
U
P
U 00075
21
21
U 00110 0
U 00110 P
21
21
U 00110 D
U 00110 D
21
05
U 00220 D
U
P
24
P
05
05
05
U 020
02
U
U
U
U
24
U
P
D
D
D
H
1A XU980140 S
1A XT629652
1B XT171526
2A XT160513
2B XT164513
1A BTS49016 S
G
1A XT0598S8
1B XT171526
2A XT160513
2B XT164513
H
1A YU000150 S
1A YU036067 S
F
1B XT171526
2A XT160513
26 XT164513
H
1A YU 190230 S
H
1A YU210180 S
1B XT171526
2A XT160513
2B XT164513
H
1A YU270100 S
1A BS630855 S
G
1B XT171526
•
2A XT160513
2B XT164513
H
1A XT33090O S
fA BT533094
H
1A BS510750 S
H
1A BSS 10750 S
H
1A BSS 10750 S
16 YT280970
H
1A XT764380 S
1B XT770379
1C XT770380
10 XT773372
1E XT777372
1F XT779384
1G XT783388
24
U 00110
U
U
U
P
1H XT784379
1A YU254149
1A XT895065
1A XT780380
1A XT490470 S
1B XT490480
1C
10
1E
1F
16
24
UNCLASSIFIED
U
XT491473
XT492472
XT495473
XT495479
1G. XT496477
1A YT548771 S
U 000
30
P
18 YT570730
1A XT490470 S
1B XT490480
1C
1D
1E
1F
1G
H
XT491473
XT492472
XT495473
XT495479
XT496477
F
H
�UNCLASSIFIED
YYMMDD CT2 PRO
691 111
691112
691 112
691112
691112
691114 3
691 114
691 114
691114
691 114
691 114
691 114
691113 3
691 115
691115
691 115
691116
691 116 3
691 116
24
H
GAL
U
U
U
T
P
1B
1B
1C
1A
1A
1A
18
1C
1D
1E
COORD
S I M
YD890990
YT510970
YT980980
XT522588
XT495473
XT490470 S
XT490480
XT491473
XT492472
XT495473
H
1F XT495479
21
21
U 00100 P
U 00110
U 00220 P
U 00220
691 117
691117
691119
691119
691125 3
691 125 3
691125 3
691125
691126
691127
691128
691128
691128
691129
691129
691202
691203 3
691203
691203
691204
691205 2
691206
691206
691206
691206
691206
691207 1
691208
6912O8
691208
69 1 208
69 1 208
691208
691219 3
691219
691219
691220
691221 3
691221
691221
691221
LEG
21
21
21
U '04 D
000
U OCO40 0
U 000D
03
U
U
U
U
21
U 00110 D
17
U
0
05
U
21
U 000D
30
24
P
U OO040
U
D
U
U 000
04
1G XT496477
1A YT265998 S
F
1A BR499489
1B XT577272
1C XT575240
18 YD706102
1A YT268988 S
F
1A BR499489
18 XT577272
1C XTS75240
18 XT577272
1C XT575240
1A YU225030 5 . H
1A YU105O40 S
H
1A YT188990 S
H
1A BSS 10750
1A BSS 10750
1A BSS 10750
2A XT575275
3A XT540240
1A XT770380
2A XT575275
3A XT540240
1B XT685162
1A YU260170 S
H
18 YU2601SO
1C YU270170
18 XT690150
1A BN020590 S
F
18 BS809374
1C BS828374
1D BS828390
1E BS8 14390
1F BSS 14398
1A BS630855 S
G
1B BS880339
1C BS880315
10 BS86431S
1B 8S927219
1C BS931219
1D BS931222
1A YU702533 S
F
1B YU671450
1C YU671400
1A YD638274
1A XT045609 S
F
18 XT045552
1A BT533094
1A YD638274
Page 134
YYMMDD CTZ PRO
691222
691222
691222
691222
691223
691223
691226
691226
691226
691226
691226
691229
691229
691229
691229
691229
691229
691230
700102
700102
700106
700107
700107
700107
700107
700107
700107
700111
700111
700111
700111
700112
700116
700120
700125
700125
700125
700125
700125
70O125
700131
700131
700131
700131
700131
700131
70O131
700201
700201
700201
700201
700201
70O201
700
022
700202
700202
700202
700
022
700202
700202
1
1
1
1
1
02
02
02
03
03
1
H
03
GAL
U
U
U
U
U
U 000
04
U
T
LEG
D
D
D
P
P
1A
1A
1A
1A
1A
1A
1A
18
1C
1D
1A
1B
1C
2B
1A
1B
1C
1A
1A
P
U
3
1
3
23
U 000D
90
05
21
U 000
06
U
U
U
P
U 05000 D
U 00110
U 00110
1
1
UNCLASSIFIED
05
05
U
U
U
P
P
COORD
ZD058031 S
YD689274 S
ZD117014 S
BT549014 S
BT549014 S
ZD058031
BT549016 S
BS927219
BS931219
BS931222
X5618748
BT5 14505
BT5150S1
BT545064
XT749230 S
XT689268
XT680299
YD638274
YD492279
G
G
G
G
G
G
F
1A BT533094
1A BS571963 S
1A YT376954 S
1B YT409793
18 XT692164
1C XT701212
10 XT668243
1E XT6O4224
1A YT28993918 YT298950
1A YT130781
18 YT170819
1A BS571963 S
1A BS571961 S
1A ZD058031
1B BT171077
1C BT 173075
1D BT 175077
1B BT901233
1C BT906233
10 BT903231
2A YC516814
3A YC505815
4A YC606809
5A YC644860
6A YC706882
7A
8A
18
1C
1D
1E
1F
1G
U
S I M
YC624940
YC631941
BT542022
BT548018
BT556008
BT551006
8T548006
BT541014
1A AT987249
18
1C
10
18
1C
1D
AT991252
AT991250
AT987248
BT178081
BT 178075
BT170081
F
H
�UNCLASSIFIED
YYMMDO CTZ PRO
H
GAL
T
LEG
COORD
S I M
YYMMDD CTZ PRO
H
GAL
T
*•
700205
700205
700205
700205
700205
700205
700205
700205
700209
700210 2
700210 2
700210
700210
700210
7002 1 3
700213
7002 1 3
700213
700215
700224
700226 3
7O0226 3
700226
700226
700227
700227
700227
700227
700227
700227
700227
700227
700227
700227
700227
700227
700227
700227
700227
702
027
700303 2
700303
700303
700303
700306 3
700307
700
039
700309
700
039
700312 2
700312
700312
700312
700312
700312
700315 2
700316 2
700316
700316
700316
15
11
U
U
U 000 0
30
U
U
U
26
23
06
U
U
U
U
U
P
P
U 000D
30
1B XT692164
1C XT701212
10 XT668243
1E XT604224
1B XT692164
1C XT701212
10 XT668243
1E XT604224
1A YS212935
1A YU590020 S R F
1A A0890730 S
F
1B A0800730
2A A0890727
2B A0800727
1A XS598964
1A XS470970
1A B03S0620
1B BQ390490
1B BR4 70760
1A C0250210
1A YT1S5015 S
1A XT741330 S
G
1A YS 160990
1A XT741330
1A BR538988
1B BR508988
1C BR508958
10 BR530987
1E BR5 10965
1F BR924979
1G BR535985
1H BR542986
11 BRS51959
U BR5539S3
1K BR561941
1L BR565979
1M BR496002
1N BS505023
10 BS499004
1P BS467003
1A Y8773110 S
F
1B YB74S032
23
U
U
U
P
27
U 000D
30
07
11
U 000C
20
U 000 C
30
1C YA740920
1A XT582034
1A XT605155 S
1A XT495475
18
1C
10
1A
18
1C
10
1E
1F
1A
1A
18
1C
10
BT 163234
BT167236
BT 168203
B04S0270 S
B0800170
B0860120
80860240
B0920330
80890380
BQ700980 S
BP030820 S
BP090830
BP 140835
BP 170850
H
F
F
700316
700316
700316
700316
70032 1
70032 1
700321
700321
700324
700324
700324
700324
700324
700325
700325
700325
700325
700325
700325
702 3
036
700326 2
700326
700326
700326
700329
700329
703
030
700330
700330
700330
700330
700330
700331 2
700331
700331
70033 1
700401 2
700401
700
043
700
048
70O408
700
049
700
049
70O40S
700
049
70O410 3
70O410
700413 3
700416
700416
700416
700416
700416
700416
700416
21
33
U
C
U 03000 D
11
U 000 C
30
07
U
P
1E BP 180880
1F BP200890
1G BP2008SO
1H BP 130840
1B BS8 16392
1C BS825387
10 BS823379
1E SS812378
1B BT 134457
1C BT 134449
10 BT 137446
1E BT 130445
1F BT 130449
1B BT 180030
1C BT 180040
10 BT 170040
1E BT 170050
1F BT 160050
1G BT 160030
1A YU000150 S
1A ZU 100240 S
18 ZU 1802 40
1C ZU 180340
10 ZU 100340
1B YB747018
1C YB747920
18 BT 180030
1C BT 180040
1D BT 170040
1E BT 170050
1F BT 160050
1G BT 160030
1A BP4 30800 S
1B BP430900
1C BP060900
10 BP060800
1A BS518069 S
18 BS627088
18 XT660250
18 BT260080
1C BT220090
2A BR600710
3A BR600720
H
f
F
G
4A BR600730
23
U
P
23
U
P
700417
70O417
700417
700418
700418
UNCLASSIFIED
5A BR590750
1A XT60S155 S
1B BS365648
1A XT6551S7 S
18 BR480880
1C BR470890
10 BR460890
1E BR 460900
1F BR4 50900
1G BR490900
1H BR500900
18 Y0700120
1C YD680120
10 YD700100
18 BR590750
1C BR580740
G
�UNCLASSIFIED
YYMMDD CT2 PRO
700418
700418
700418
700418
700418
700418
700418
700418
700418
700418
700418
700418
700418
700420
700420
700420
70042S
702
045
700425
700425
700425
700426
702
046
702
046
700426
702
046
702
046
700427
700427
700427
702
047
702
047
700427
700427
700428
700428
700428
700428
700428
700431 2
700431
70O431
700431
700S02
700 3
057
700
058
700
058
700
058
700
059
700
059
700
059
700510
700510
700510
700510
700510
700510
700513
700513
7005 1 3
H
GAL
T
U
07
24
U 000D
30
U
U
P
LEG
COORD
S I M
1D BR570750
1E BR580720
IF BR590720
1G BR580870
1H 8R480880
11 BR500880
10 BR500890
1K BR420020
1L BR430020
1M BS4 10030
1N BS4 10020
2A BR580859
2B BR478970
.18 BS639381
1C BS632375
10 BS629378
1B AT975132
1C BT015125
1D BT020100
1E BT020080
1F AT945108
1B AT975132
1C BT015125
1D BT020100
1E BT020080
1F AT945108
1A YD827137
1B BT090230
1C BT 100230
1B AT975132
1C BT01512S
1D BT020100
1E BT020080
1F AT945108
18 AT975132
1C BT015125
1D BT020100
1E BT020080
1F AT945108
1A BP430800 S
1B BP430900
1C BP06O900
10 BP060800
1A ZD116013
1A XT492472 S
1B BT229317
1C BT229312
10 BT226312
1B BT229317
1C BT229312
1D BT226312
1B BT229317
1C BT229312
1D BT226312
1B YD640130
1C YD670130
10 YD670105
1B BT229317
1C BT229312
10 BT226312
F
G
YYMMDD CTZ PRO
700514
700514
700514
700515
700515
700515
700517
700517
700517
700 3
063
700611
700611
700611
700612
700612
700612
700612
700612
700612
700612
700612
700612
700613
700613
700613
700613
700618
700618
700618
700618
700618
700618
702
068
702
068
700628
700629 702
069
702
069
703
060
703
060
70O630
7 0 0 1072
700
072
700702
700
072
700812
700812
700812
700812
700812
700812
700813
700813
700813
700814
700814
700814
700814
700814
700814
21
Page 136
H
U
GAL
T
P
LEG
COORD
S I M
1B BT229317
1C BT229312
1D BT226312
18 BT058251
1C BT058249
1D BT051249
1B BT229317
1C BT229312
10 8T226312
1A YC 140070 S
1B BS876325
1C BS868317
10 BS867321
1B BT047256
1C BT058245
1D BT058256
1B BT047256
1C BT058245
1D BT058256
1B BS876325
1C BS868317
10 BS867321
1A BS873327
1B BS876325
1C BS868317
1D BS867321
1B BT047256
1C BT058245
1D BT058256
1B BT047256
1C BT058245
1D BT058256
1B AT964997
1C AT966994
1D AT950996
H
1B AT964997
1C AT966994
03
UNCLASSIFIED
U OO110 P
1D
1B
1C
1D
1A
AT95O996
AT964997
AT966994
AT950996
AT958002 S
1B AT964997
1C AT966994
1D AT950996
1B
1C
1D
1E
1F
1G
1B
1C
1D
1B
1C
10
1B
1C
10
BS624470
BS620503
BS6 16468
BS6 15567
BS597529
BS590498
BS490730
BS450730
BS440690
BS52O420
BS535397
BS540403
BS520388
BS540393
BS540400
H
�UNCLASSIFIED
YYMMDD CTZ PRO
700814
700814
700814
700815
700815
700815
7 0 16
08
700816
700816
700818
700818
700818
700818
700818
700818
700818
700818
700818
700819
700819
700819
700819
700819
700819
700819
700819
700819
702
080
700820
700820
700820
700820
702
080
700820
700820
700820
700820
702
080
700820
700820
702
080
702
080
700821
700821
70082 1
700821
700821
700821
700821
70082 1
700822
700822
700822
700822
700822
700823
700823
700824
702
084
700824
H
GAL
T
LEG
COORD
1B BS500420
1C BS470420
1D BS470460
16 BS500420
1C BS470420
10 BS470460
18 BS3704S8
1C BS440505
10 BS456563
16 8S354446
1C BS375434
10 BS380450
1E BS377470
1F 8S360480
1G BS350550
1H BS338549
11 8S330525
U BS344485
1B BS354446
1C BS375434
10 BS380450
1E BS377470
1F BS360480
1G BS350550
4H BS338549
11 BS330525
1J 8S344485
1B AT966247
1C AT991254
10 AT986253
1B BT093230
1C BT110230
10 BT1 10237
16 BT020230
1C 8T060200
1D BT060230
1B BT090260
1C BT 100260
1D BT 100250
1B BT 130235
1C BT130218
1D BT0802OO
16 BT 110250
1C BT 120250
10 BT 120240
18 BT135280
16 BT 160220
1C BT 160230
10 BT 140230
1B BT 170255
1B BT150010
1C BS 135985
1D BS 125995
1B BT1640OO
1C BS 180995
1B BT145279
1B AT945098
1B AT945120
1C AT940120
10 AT940098
S I M
YYMMDO CTZ PRO
700824
700827
700827
700827
700827 1
700827
702
087
700827
700827
700827
700827
702
087
700827
700827
702
087
700827
700827
700827
700827
700827
700828
700828
700828
700828
702
088
700828
700828
702
088
700828
700828
700828
700828
702
088
700828
700828
700828
700828
700828
700828 1
700829
702
089
700829
700829
700829 1
700830
703
080
700830
7O0830
703
080
703
080
700830
700830
700830
703
080
700830
700830
700830
700830
703
080
700830
03
137
H
GAL
T
U 00035 P
LEG
COORD
S 1 M
1B BT145279
1B AS990980
1C BS045975
1C BS030950
1A BT265266 S
16 BS034963
1C BS028954
10 BS023953
16 BS045979
1C BS042979
1D BS039976
1B B5040950
1C BS035960
10 BS035950
1B AS987954
1B AS991968
1B BS007970
16 BS014973
1B AS984947
16 BS015966
16 BT010130
1C ST020080
10 AT946100
' 1B AT972134
1C AT980121
16 BT010119
18 AT987099
G
1B AT971084
03
U
P
03
U
P
UNCLASSIFIED
1B
1C
10
1E
1F
1B
1B
1C
10
1B
1A
16
1C
10
18
BTOO4104
BT019104
BT020099
BT008099
BT005095
AT972104
AT952122
AT951106
AT945108
AT966125
BT533094 S
BT010130
B008
T200
AT946100
BT000124
1A BT533094 S
1B BT010130
1C B 0 0 8
T200
1D AT946100
1B AT993975
16 BS003980
1C BS006975
tO BS000975
1E AS999970
1B BT012125
16 BT018115
1B AT990110
1B BT004090
1C AT992110
18 AT980104
1B AT970103
1C AT970097
G
G
�UNCLASSIFIED
YYMMDO CTZ PRO
700830
700830
700830
700831
700831 1
700901
700
098
700
098
700
098
700
098
700
098
700 1
099
700 1
099
700911
700911
700911
700917
700920
700920
700921
700921
700921
702
093
700923
700923
700925
70092S
700925
701001
701001
701001
701007 1
701009
701013
701013
701013
701014
701014
701014
701031
701229 3
710114
710122
710319
710319
710319
710319
710319
710319
710319
710319
710319
710319
710320
710320
710320
710320
710320
710320
710320
H
GAL
T
03
U
P
01
01
U
U
P
P
03
U
P
24
U 00110
U
D
U
U
LEG
COORD
S I M
1D AT965095
18 AT977082
1B AT982093
1B BT160210
1A BT533094 S
1B YD532315
1B BS215780
2A 8S 175750
3A BS 195728
4A BS 150772
48 BS 176784
1A YD1 17702 S
U YD13S643 S
1B YC600940
1C YC580920
1D YC600920
1B YC636862
1B YC633863
1C YC667869
1B YC62S830
2A YC668892
3A YC668868
3A YC888763
4A YC886745
3A YC881726
2A YD 1001 28
3A Y0095130
4A YD096148
1B YC854757
1C YC884747
1B XC6 12930
1A BT533094 S
3A YDS 15857
2A YD063242
3A YOOS8239
4A YDOSS293
1B ZC164215
2A YD9 19793
16 AT210180
1A YD490198
1A XT086818 S
1A BS630855
1A BT5S5035
1B YD010570
2A XD98S551
1B XD982510
1C XD98S510
1D XD988547
1E XD982S42
2A X0979544
2B XD978510
3A XD992523
3B YDO 15560
1B XD982510
1C XD985S10
10 XD988547
1E X0982542
2A XD979544
2B XD978S10
3A XD992S23
G
H
H
G
YYMMDO CTZ PRO
710320
710321
710321
710321
710321
710321
710321
710321
710321
710322
710322
710322
710322
710322
710322
710322
710322
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710323
710425 1
710504 1
711124 3
711128
711129
711130
03
03
19
UNCLASSIFIED
Page 138
H
GAL
T
U 01600 P
U 080P
00
U
0
U •
U
U
3B XDQ15560
1B XD982S10
1C XD985510
1D XD988547
1E X0982542
2A XD979544
2B XD978510
3A XD992523
3B YDO 15560
1B XD982510
1C XD985510
1D XD988547
1E XD982542
2A XD979544
2B XD978510
3A XD992523
3B YD015560
1B X0982510
1C XD985510
10 X0988547
1E XD982542
2A XD985550
2B XD979544
2C XD978510
20 XD975510
2E XD975544
2F XD985550
3A YD020558
3B XD995548
3C XD992551
3D YDO 15560
3E YD020558
1B XD982510
1C XD985510
1D XD988547 S
1E XD982542 S
2A XD979544 S
2B XD978510 S
3A XD992523 S
3B YDO 15560 S
1A BT533094 S
1A BT533094 S
1A YT603120 S
1A XT990130
1A XT990130
1A XT990130
G
G
H
�
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
013
Folder
The folder containing the original item.
0109
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Description
An account of the resource
<strong>Corporate Author: </strong>U.S. Army & Joint Services Environmental Support Group
Date
A point or period of time associated with an event in the lifecycle of the resource
September 12 1985
Title
A name given to the resource
Services HERBS Tape - A Record of Helicopter and Ground Spraying Missions, Aborts, Leaks, and Incidents
Subject
The topic of the resource
HERBS database
herbicide application
Ranch Hand
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/90b72923a486d86fddcbfa9031178e82.pdf
4f245730fb6d4f290356ece15974756c
PDF Text
Text
Item ID Number:
001 eo
Howard, John D.
Corporate Author
RBDBPt/ArtitiB TltlB Herbicides in Support of Counterinsurgency Operations: A Cost-Effectiveness Study
Journal/Book Title
Yaar
i Bui
1972
Month/Day
March
Color
D
132
Introduction and background gives brief overview of Operation Ranch Hand and use
of herbicides in Vietnam.
Friday, January 05, 2001
Page 160 of 194
�Howard, J. D,,
5 ^ 1972
.
Herbicides in support of counterinsurgency
operations: a cost effectivness study
I/UNLIMITED
AD A0745180
Technical
Report
£EJEIOMEDICAL LIBRARY
JAW 10 1980
distributed by
fiQClIMENTS
Defense Technical Information Center
DEFENSE LOGISTICS AGENCY
Cameron Station*Alexandria, Virginia 22314
UNCLASSIFIED/UNLIMITED
�* - -4
1.0
11.25
�o
00
NAVAL
SCHOOL
Monterey, California
T-H
THESIS
HERBICIDES IK SUPFOl^ OF
COUNTERIKSURGEKCy OPERATIONS:
A COST-EFFECTIVENESS STUDY
John DaXton Howard
Thesis Advisor:
NATIONAL TECHNICAL
INFORMATION SERVICE
James R. Caora
March 1972
ion pubtic. x.e£e&!>e.; datuiittien untuniltd.
K.
\
�Herbicides in Support of Counterinsurgency operations:
A Cost-Effectiveness Study
John DaIton Howard
Major, United States Army
B.S., United States Military Academy, 1964
Submitted in partial fulfillment of the
requirements for a degree of
MASTER OF SCIENCE IN OPERATIONS RESEARCH
from the
NAVAL POSTGRADUATE SCHOOL
March 1972
Author
Approved by:
Thesis Advisor
Chainrari, Department of Operations Research
// and Administrative Sciences
Academic Dean
�UNCLASSIFIED
Cl as<unration
DOCUMENT CONTROL DATA - R & D
!.*!• avrrstt rmptttt tt
j*. REPORT SECURITY cn-.iif ic* TIO«
t of title, fcodr ttf *t>*tr*ft
TtN6 A C T I V I T Y
Unclassified
Naval Postgraduate School
Monterey, California 93940
J*. SltOU*
Herbicides In Support Of Courterinsurgency Operations:
A Cost-Effectiveness Study
of t*«6tt •nd.inC*ir»ire <****»
Master's Ihesisj March 1972
John D. Howard
C NO. O
EPOBT D A T E
130
March 1972
M. C O M T K A C T Oft G R A N T NO.
44
M. OntCIMATOM't HE'QMT MUMICHIH
». fHOJECT NO.
• 6. O T H E R *E»O*T HO(I> (
tft/«
IS. D I J T A i e u T I O M t T A T E M E M T
Approved for public release; distribution unlimited.
It. SUPPLEMENTARY NOTES
11. SPONSORtNC UILIT A R T A C T I V I T Y
I). A K S f K A C T
This study develops costs, effectiveness criteria, and
cost-effectiveness ratios for military herbicide systems and three
other alternatives which can perform the missions of foliage removal
and crop destruction in support of counterinsurgency operations.
The results reflect the Vietnam combat environment wheie all systems
were employed at sometime during the period 1965-1971. The systems
considered are aerial delivery of herbicides by UH-1 helicopters
and ue-123 Air Force aircraft, tactical land clearing with crawler
tractors, "slash and burn" clearing with indigenous cutters, and
fireboizbing with CH-47 helicopters. The effectiveness criteria
focus on the ability of these systems to perfona the two missions
and withstand the rigorous constraints of a hypothetical combat
mission. From these criteria, two sets of cost-effectiveness vectors
are obtained to allow a decision maker the opportunity to evaluate
each system and determine a possible force structure to accomplish
the two missions in a Vietnam-type insurgency.
DD/r.,1473
UNCLASSIFIED
S/N 01 Of*«Q7-«S!t
Security Ctatsificitio*
�UNCLASSIFIED
S«eurit¥ Classification
LIM K A
l*N K
•
KKT W0»0»
»OLt
tri>. • c
«« T
Cost-effectiveness
Herbicides
Tactical Land Clearing
Firebombing
"Slash and Burn" Clearing
Counterins urgency
|
1
DD /,T.,!473 «8*«>
^^
UNCLA SSIFI ED
Security CUstiftcttiet
>.]«BI
�ABSTRACT
This study davelops costs, effectiveness criteria, and
cost-effectiveness ratios for military herbicide systems and
three other alternatives which can perform the missions of
foliage removal and crop destruction in support of counterinsurgency operations. The results reflect the Vietnam
combat environment where all systems were employed at
sometime during the period 1965-1971. The systems considered
are aerial delivery of herbicides by UH-1 helicopters and
UC-123 Air Force aircraft, tactical land clearing with
crawler tractors, "slash and burn" clearing with indigenous
cutters, and firebombing with CH-47 helicopters.
The effec-
tiveness criteria focus oh the ability of these systems to
perform the two missions and withstand the rigorous
constraints of a hypothetical coiribat mission. From these
criteria, two sets of cost-effectiveness vectors are
obtained to allow a decision maker the opportunity to evaluate each system and determine a possible force structure to
accomplish the two missions in a Vietnam-type insurgency.
�TABLE OP CONTENTS
I.
INTRODUCTION
A.
II.
PURPOSE
B.
6
•
BACKGROUND
•
•
6
7
THE ALTERNATIVES
14
A.
AERIAL DELIVERY OF HERBICIDES
14
1.
UC-123 —
14
2.
UH-1
•
•
16
•
20
B.
C.
"SLASH AND BURN" CLEARING
28
D.
III.
TACTICAL LAND CLEARING ~
PIREBOMBING
30
METHODOLOGY
33
A.
ASSUMPTIONS
•
33
B.
PARAMETERS
C.
COST ANALYSIS
D.
EFFECTIVENESS CRITERIA AND COST-EFFECTIVENESS
•
•
34
•
35
MEASURES
E.
36
PARAMETER SENSITIVITY
—
38
IV.
ANALYSIS OF AERIAL DELIVERY OF HERBICIDES
40
V.
ANALYSIS OF TACTICAL LAND CLEARING
75
VI.
ANALYSIS OP "SLASH AND BURN" CLEARING
92
VII.
ANALYSIS OF FIREBOKBING
100
VIII.
INSIGHTS AND CONCLUSIONS
109
A.
RESULTS OF THE ANALYSIS
109
B.
INSIGHTS
C.
CONCLUSIONS
•
•
•
—
112
114
�APPENDIX A:
DETAILED HERBICIDE COSTS
116
APPENDIX B: DETAILED COSTS FOR TACTICAL LAND CLEARING— 118
APPENDIX C:
DETAILED COSTS FOR FIREBQMBING
APPENDIX D: DATA SOURCES
120
—
BIBLIOGRAPHY
— 121
—
124
INITIAL DISTRIBUTION LIST
FORM DD 1473
•
—
128
•
,»—
__
..
�ACKNOWLEDGEMENT
This study was made possible through the contributions
and assistance of the V. S. Array Engineer Strategic Studies
Group, Washington, D. C., and Major Richard C. Bennett,
senior project director in that office. A special acknowledgement, goes to Mr. J. T. Soules, Vice President of the
International Depar-iaent of the Rome Plow Company, whose
correspondence and interest in the study provided the author
with a wealth of data and many insights into the salient
features of tactical land clearing.
�I.
A.
INTRODUCTION
PURPOSE
The purpose of this study is to conduct a costeffectiveness evaluation of military herbicide systems in
a counterinsurgency environment. The test case for the
determination of relevant costs will be those dollar costs
incurred during the systems' empJoyment in vegetation
renoval and crop destruction missions .in support of combat
operations in the Republic of Vietnam (RVN) during 1965-1971.
Since costs are the values of alternatives foregone, the
study will address three other techniques used for foliage
clearance and crop control in RVN during the same timeframe.
The alternatives to herbicide operations which will
be considered are:
1. Tactical land clearing operations.
2. "Slash and burn" clearing using indigenous
labor forces.
3. Firebomb?ng.
Each method will be discussed in detail in Chapter II.
Specifically excluded from the scope of the study is
consideration of the externalities that night result from
possible damage to the ecological balance of the host
country.
The cost measures will attempt to show the relative
dollar expenditores araong the systems involved. Several
�measures of effectiveness will be used to Judge their output
and ability to accomplish the missions of foliage reioval
and crop des'
=tion under combat conditions. These,
coupled with the cost measures, will yield cost-effectiveness
figures which will be the basis for comparisons, These
comparisons will present the decision maker with sets of
data on the strengths and weaknesses of the individual
alternatives and combinations of the systems.
B.
BACKGROUND
The proper use of cover and concealment has always been
a critical factor ..n planning military operations.
History
is full of examples of armies that effectively used natural
cover and foliage.
Often, judicious use of these elements
made up for other deficiencies in the forces.
The colonial
settlers of early America learned the arts of cover and
concealment from the Indians and later put them to good use
in the War of Independence.
As warfare evolved from the
strjiight-line formations of the 19th century and the
trenches of World War I, it became apparent that strict
adherence to the principles of concealment was not reserved
solely for the guerrilla or irregular soldier.
Hence,
tactics and methods were developed in an attempt to deny
any potential enemy, insurgent or conventionally organized,
the protection and sustenance that might be offered by the
vegetation.
�The term "herbicide" was coined in the 1930's to
enctmpass that family of chemicals which are antiplant
agents.
Some members of this family were found to be
systemic hormones which entered broad-leaf plants touching
off wild growth and eventually killing then. Others were
determined to be dessicants which injured the foliage by
direct chemical action on contact. Throughout World War u,
military research in chemical warfare played an important
role in the development of the potent herbicides now in
world-wide use. Although initial efforts were directed at
the discovery of suitable dessicants (for use as antierop
agents), scientists from the university of Chicago determined that some of these growth regulators might be applied
to grasses and tropical plants. This generated a great deal
of interest in the defoliation or foliage removal properties
of the chemicals since many tons of explosives had been
expended on Pacific islands to deny the Japanese concealment
afforded by the tropical rain forests.
In early 1945,
successful tests were conducted in the Florida Everglades
concerning the possibility of using several inorganic
defoliants in aerosol form, The results from this work
prompted the Army to recommend the use of ammonium thiocynate in the Pacific theater.
This recommendation was not
adopted for fear of the repercussions that might arise from
the agent's association with chemicals of the cyanide
faaily.
The war ended prior to the testing of a more
suitable agent.
8
�In the late forties, the research generated during World
War II was readily employed by civilian industry.
The
previous discovery of the organic chemicals 2,4-D and 2.4,5-T
fostered revolutionary steps in chemical plant control and
stimulated the development of a host of new agents. These
herbicides were more effective, more selective, and less
hazardous than the former compounds.
Chemicals such as
piclorara, bromacil, cacodylic acid, and paraquat were
tailored to perform specific kinds of vegetation control.
Consequently, their use at home and abroad became widespread.
In 1950 the estimated market for herbicide? came
to §1.5 million while by 1965, it had gruwii to over $211
million.
(This was prior to extensive military purchase of
certain agents for use in RVN.) In 1959 alone, American
farmers treated 53 million acres of acres of agricultural
land not to mention the thousands of miles sprayed by local
government agencies and private corporations to control
growth along highways, powerline right-of-ways, fire breaks,
and ditches.
(House and others, 1967.1
>,
J
The Department of Defense (DOD) did not become involved
in herbicide operations until 1958.
The success of British
defoliation operations with helicopters in Malaya prompted
several feasibility studies on acceptable defoliants and
delivery techniques.
In 1961, on request of President Diem
and the government of RVK, a test program was established to
assist in countering that nation's growing Communist-inspired
insurgency.
The Vietnamese army (ARVN) found that the most
�difficult and frustrating task was locating the enemy.
The
dense forests and jungles offered the Viet Cong (VC) excellent concealment which permitted them to cove with relative
impunity to within striking distance of key military installations , lines of communications (LOG), and government
centers. By removing parts of the foliage, the Allied
forces hoped to increase aerial and ground surveillance capabilities and deny the use of certain areas as sanctuaries.
The actual herbicide operations began under the codename
RANCH HAND in January 1962 with three specially configured
U.S. Air Force (U3AF) UC-123B aircraft.
The operations
proceeded for the next two years at a moderate scale but
with increased enemy resistance.
Ground fire became so
intense that in March of 1965 fighter escorts were provided
on a permanent basis.
The demand for defoliation and
controlled crop destruction missions increased as U.S.
participation in the war grev. This resulted in the RANCH
HAND program being expanded in 1966 into a squadron-size
unit, 12th Air Coimr-ando Squadron (later the 12th Special
Operations Squadron), with an equipment level of 18 aircraft
and headquarters at Bien Hoa Air Base.
In the peak years of
defoliation operations (1967-1968), the squadron was
increased to 24 aircraft.
jKcConnell, 1970.1
To supple-
ment the 12th Special Operations Squadron, some U.S. division commanders were given the authority to conduct local
defoliation and crop destruction missions in their area of
operations (AO) with U.S. Army helicopters.
These operations
�were usually complementary to the RANCH HAND sorties and
employed local aviation assets thit were diverted froia other
lift tasks.
From the inception of the test program, great effort was
oade to insure proper targets were picked and spraying of
friendly areas was prevented.
Each mission was approved by
the local Vietnamese province chief, the Military Assistance
Command Vietnam (KACV), and the U.S. Embassy, crop destruction targets were subject to special scrutiny so that the
most harm would be done to the VC and the least to the local
inhabitants. A commission was established to contpensate and
reimburse those people who had suffered financial loss as a
result of herbicides.
Although friendly areas were never
specifically targeted, some spray did occasionally drift
causing damage to rice crops or rubber trees.
U.S. authori-
ties attempted to take prompt action on any claims whenever
this situation occurred.
Iconzales
1968 J
Concurrent with increased herbicide operations in
Vietnam, there was an expanding controversy over the program
in the united States.
Critics asserted that if chemical
herbicides were coroaonly used, it might not be long before
more noxious chemical agents are considered usable.
Others
have claimed that such an indiscriminate weapon results in
as much suffing for the local populace as the VC.
19681
and
fLewallen
|Hersh
1971 J . The scientific community
raised the question of the ecological consequences of
repeated herbicide applications.
11
The American Association
�for the Advancement of Sciences (AAAS) has been and still is
the center of the controversy. Probably the most vocal and
widely quoted critic within AAAS is Dr. Matthew Meselson, a.
Harvard University biologist.
Or. Meselson chaired the AAAS
Herbicide Assessment Commission and visited Vietnam on a
five-week tour.
In the committee statement to an AAAS
convention, the following assertions were mades
1. fhe Army's crop destruction program was a
failure.
2.
Cae-fifth to one-half of Vietnam's mangrove
forests had been "utterly destroyed."
3.
One-half the trees in the mature hardwood
forests north and west of Saigon were
dead. 1
Several other scientists who had previously visited RVH in
1958-19S9 strongly recommended and lobbied for the cancellation of the herbicide operations until scientists had time
to study the long-term effects of the program,
Pfeiffer
[orians and
1970]
These recommendations coupled with severe criticism from
certain members of Congress and other citizens helped bring
about the suspe: sioa of herbicide operations in the summer
of 1970.
On 7 October 1970, Public Law 91-441 directed the
Secretary of Defense to prepare a study to identify the role
%offey, Phillip M., "Herbicides in Vietnam: AAAS Study
Finds Widespread Devastation," Science, 15 January 1971,
p. 43.
12
�of herbicides in support of combat operations and evaluate
their utility in KVB. It also required him to contract
with the National' Academy of Sciences (HAS) for a comprehensive study to determine the ecological and physiological
effects of the herbicide program in RVN. By 1 March 1972,
the Secretary of Defense was required to transmit the DOD
findings together with the RnS study to the President and
the Congress.
It is against this background of U.S. use of herbicides
and Congressional concern about the role of herbicides that
the examination of the alternatives discussed in the next
section has been undertaken.
13
�II. ALTERHRTIVES
A.
AERIAL DELIVERY OF HERBICIDES
Aerial delivery is the prime method of dissemination of
chemical herbicides for large-scale defoliation or crop
destruction missions. Other methods, such as use of the
three-gallon hand-pucp sprayer, the M-106 riot control
dispenser, and boat-counted spray systems, have beep employed
in Vietnam but will not be considered in the context of this
study. However, all herbicide missions are designed to
accomplish some or all of the following objectives:
1. Deny tlie enemy cover and concealment and
channel his movement.
2. Deny the enemy the capability to forage
off tne land.
3. Deny tae enemy ambush sites adjacent to LOG.
4. Provide improved aerial and electronic
surveillance.
1. Delivery By Fixed Wing Aircraft (UC-123)
The major portion of the U.S. herbicide effort is
carried by a modified version of the Air Force's two-engine
medium cargo carrier, the C-123B "Provider."
Ahe
aircraft
is given a spray capability ("UC" designation) by the
installation of the Hayes AA-45 system which consists of a
1,000 gallon internal tank, an operator console, and three
high pressure spray booms. Since most missions are carried
14
�out at low altitudes and low speeds, the performance of the
aircraft is significantly upgraded by the addition of turbojet engines.
The intensity of enemy ground fire in Vietnam
has forced the Air Force to further protect the UC-123K with
additional armor plating for the crew ami engines.
The
DC-123K's travel in fighter escorted flights ranging anywhere from two to seven aircraft, depending on the target
configuration.
Each aircraft dispenses its 1,000 gallon
load in four minutes at less than 150 niles per hour and 150
feet off the ground.
The Hayes ays ten can be adjusted for
variable dissemination rates; however, these rates are
usually between one and one-half gallons to three gallons
per acre.
[Major Pyatt]
Photo # 1: Pour UC-123 aircraft of the 12th Air Commando
Squadron defoliating a jungle area east of Siigon. June 1968
U.S. Array Photograph
15
�2. Delivery By RotaryWing Aircraft (UH-1)
In certain areas, ground commanders are authorized
to conduct local herbicide operations. When CC-123 aircraft
are not available to do the Job or the target is too small
to merit fixed wing sorties, the UH-1 helicopter (commonly
known as the "Huey") can be equipped with an internal tank
and spray booms. In initial operations in RVU, some U.S*
Army nalts used a field expedient which employed a 55-gallon
drum fitted with rubber hoses and sprayers mounted on the
helicopter skids.
The second generation system used in the
UH-1 is the AGAVENCO sprayer, developed by a Las Vegas firm
for use in agricultural work. This system can be mounted in
the aircraft in less than one-half hour and consists of a
200 gallon tank, pump, and pressurized nozzles.
of the Array (DA) Training Circular (TC) 3-16
[Department
1969 ] . The
UH-1 fitted with the AGAVENCO provides the same dissemination rates as the UC-123 but its capacity is considerably
less. Although the system is designed for a 200 gallon
capacity, the combat requirements of two pilots, two door
gunners, and a system operator cut the UH-l's lii't capability
to such an extent that the tank can only be loaded with 100
gallons.
I^TC Rudrowj
The use of the helicopter in RVN for delivery of
herbicides has been far less standard than the operations of
the 12th Spscial Operations Squadron. Since division
comifcanders were the controlling authorities for these
missions in each AO, the methods used varied considerably
16
�throughout the theater.
Ideally, several "Hueys" should be
employed for efficiency's sake. However, since no helicopters were set aside specifically for herbicide missions,
they were normally diverted on a one-by-one basis from other
conibat sorties. The security escorts, the AH-lG ("Huey
Cobra"), faced the same problem, and while a defoliation
helicopter should be supported by two Cobras, on r«any occasions, none were available.
did not curtail the missions.
However, this lac'k of security
\LTC Rudrow and LTC Saiiches]
Photo # 2: UH-1 helicopter taking-off on a defoliation
mission.
U.S. Army Photograph
17
�3. Chemical Agents
ORANGE, WHITE, and BLUE will Toe the agents considered
in this study.
These chemicals do not constitute the
complete spectrum of herbicides, but they were the most
widely used in support of U.S. combat operations in RVN.
Table II-l: Composition and Use of Selected Agents
AGENT
COMPOSTTTQW
USES
ORANGE
5056 2,4-D(r»-butyl.2-4 dicholoroph*".noxyacetate)
50% 2,4,5--7(n-butyl,2,4,5trichorophenoxyacetate)
WHITE
20% Picloraro (4-araino-3,5,6- General defoliation:
trichloropicoline acid) Slower acting but
80% 2,4-D(trisopropanolamine| more persistent than
General defoliations
wangrove, jungle,
and low-land scrub
trees.
ORANGE
BLUE
3 pounds per gallon of
water of:
65?o cacoclylic acid
35% inert ingredients:
sodium chloride, sodium
sulfate, calcium sulfate
and water.
Crop destruction:
Most effective
against grassy plants,
rice, manioc, corn,
and banana trees,
During defoliation operations in RW, agents ORANGE
and WHITE were used interchangeably.
It was found that these
agents did not permanently destroy all vegetation, although
the mangrove swamps still show heavy effects of the spraying.
Recent pictures taken of heavily defoliated areas show
considerable regrowth of foliage in hardwood forests and
along waterways.
The NAS study will address this question
2
DA TC 3-16, Employment of Riot Coatrol Agents, Flaree,
Smoke, Antiplant Agents, and Personnel Detectors in CounterGuerrilla Operations, p. £0-81, April 1 6 .
39
18
�In detail along with other ecological effects of chemical
herbicir?s.
[Tschirley
1963] and [office of Deputy
Assistant Secretary of Defense (ODASD) 1971] ..
4. Coverage and Limitations
The present sprayer systems used in both fixed and
rotary wing aircraft allow variable dissemination of lierMcides. 'rhese rates are as follows:
Table I1-2: Herbicide Dissemination Rates
Mission Type
Rate
Defoliation
Crop Destruction
3ftree gallons/acre
One and one-half to three
gallons/acre
[DA TC 3-16 1969]
The use of herbicides in support of conibat operations
is limited in several respects.
The best time to apply them
is during the particular plant's most active growing period.
While spraying during the dry season (which corresponds to
the non-active period of most plants) does produce defoliation, the vegetation dies at a slower rate.
In ac'lition,
the proper atmospheric conditions must exist to insure
maximum coverage of the aerosol, assuming the aircraft is
flying at the proper speed and altitude. An inversion
temperature gradient and a wind of less than eight knots
insure not only proper coverage of the target but also minimize the probability of drift onto friendly areas.
This is
particularly important in an insurgency environment where
unintentional destruction of the indigenous population's
19
�property and crops would be detrimental to the position of
the counterinsurgent forces.
B.
TACTICAL LAND CLEARING
A tactical land clearing operation is designed to support
the ground tactical forces by denying the enemy any use or
benefit that might be gained from heavily vegetated terrain.
Unlike herbicide missions, a well-planned clearing operation
seeks to not only remove foliage but also the source of it
as well.
This produces an advantage above those received by
defoliation since surveillance is improved in the horizontal
dimension as well as the vertical.
This improvement is
realized by:
1. An increased ground-based anti-personnel
radar capability.
2. Increased visual observation.
3. Improved fields of fire.
4. Physical elimination of potential ambush
sites and base areas.
A secondary benefit derived from land clearing is the
possible economic enhancement of the area. Marketable
tiitiber felled during the operation can be extracte'"- for the
local lumbering industry, and if the tactical situation
pernits, there is the potential for conversion of this
unused land for productive agricultural cultivation.
Pamphlet (Pam) 525-6
1970 ] .
20
iDA
�1. Equipment and Organization
Tactical land clearing revolves around the proper
use of a standard crawler tractor equipped with the Rome K/G
blade and kit assembly. This item of equipment, commonly
referred to as the "Rome Plow," was developed by Ernest
Kissner of Lottie, Louisiana for land reclamation of heavily
wooded tracts. The success of the blade prompted Mr. Kissner
to sell the rights to his equipment to the Rome Plow Company
of Cedartown, Georgia.
Since 1957, it has been produced to
fit all standard sizes and makes of tractors
(Caterpillar,
Allis-Chalroers, International Harvester). The tractor and
Rome blade became the method accepted for pilitary land
clearing in 1966 after a test period at Fort Belvoir,
Virginia and Vietnam of practically all known commercial
clearing equipment. [Rome Plow Company, Training Program
November 19711.
The Rome K/G treedozer, unlike the bulldozer blade
which clears by uprooting, works on the shearing principle
in that the total horsepower of the tractor is applied to
the sharp cutting edge extending the length of the blade.
In addition to the cutting edge, a wedge-like projection,
the "stinger," extends forward from the left of the leading
edge of the blade.
This allows larger trees to be split in
one or more passes before they are actually felled by the
cutting edge.
In order to permit faster operation with less
operator fatigue, a flat sole is mounted on the heel of the
blade to float on the surface of the ground and conform to
21
�topographic irregularities. Through the technique of
shearing the vegetation at ground level or below, its disposal by burning or extraction is much faster because it is
soil free. There is less soil disturbance since the tilted
blade cuts the vegetation rather than uprooting it. [DA
Para 525-6 1970] .
'She "Rome Flew" has become the nucleus of the
recently organized Engineer Land Clearing Company whose
primary mission is, "... to destroy or clear extensive der.i,e
vegetation in critical areas for the purpose of denying its
use by the enemy as bases of operation, supply bases, marshalling areas, ambush sites, and cover and concealment."-5
This unit, part of the U.S. Army Corps of Engineer organization, has thirty medium crawler tractors each equipped with
the Rome kit. It was spawned by the success of the "Rome
Plow" used initially in twos and threes by practically all
engineer elements in RVH. The land clearing role became so
large that in 1969 the Army organized the 62nd Engineer
Battalion to handle the clearing requirements in M_litary
Region III. Usually one of its three plow companies was
placed in support of a divisional clearing mission.
Tha
company was found to be the primary unit for employment
since fragmenting it into smaller elements for prolonged
periods of time resulted in the loss of maintenance posture.
[62nd Engineer Battalion Letter February 1971]
United States Army Combat Developments Command, Table
of Organization and Equipment Number 5-87T - Engineer Land
ClearingConpany, p. 1, 7 February 1969.
22
�Photo #3: Rome K/G blade and protection group on a
Caterpillar D7F tractor.
Rose Plow Company Photograph
23
�2. Clearing Estimates and Limitations
It is virtually impossible to establish exact rates
at which any piece of equipment can clear land.
Such
factors as vegetation type, terrain, climate, enemy situation, and quality of assets available will directly influence this. Accurate estimates require a detailed clearing
reconnaissance to include several "tree counts" for tree
size, diameter of large trees, and secondary growth estimates. The information frcra this reconnaissance can be
placed into one of several forculas developed by the Rose
Plow Company to determine time required per acre cleared.
[Rome Industries Salesgram, 1 September 1971.1
In the event
that'this procedure cannot be followed, the Department of
the Army has established planning estimates for clearing
operations using one land clearing tractor for various types
of cuts:
Table II-3: Land Clearing Estimates
VEGETATION
UNIT
{Equipment-hours/unit)
AREA CLEARING
STRIP CLEARING
LIGHT: Less than
12 inches in diameter Acre
.4
.
6
MEDIUM: 12 to 18
inches in diameter
Acre
.
8
1.3
HEAVY: -Greater than
18 inches in diameter Acre
1.3
2.1
Several factors which constrain tactical clearing
operations are soil trafficability, support requirements.
4
Department of the Army Parphlet 525-6, Land Clearing
Lessons Learned, p. 60, 16 June 1970.
~
24
�and determination of the enemy to resist the land clearing
mission. Since the medium tractor with the Rome kit has a
gross weight of more than 20 tons, the ground must be relatively solid to permit movement.
This would restrict its
use in areas subject to heavy seasonal rainfalls and locations that are inundated on a regular basis, such as
mangrove swamps.
Even if the terrain permits movement of
the tractors, there is always the possibility that it is
interlaced with streams, canals, or steep-sided gullies.
Supporting troops are necessary to install bridging across
these obstacles and assist in tractor recovery operations.
Aviation support is required for proper command and control
of large scale cutting operations, m many cases, the
engineer commander must be airborne to guide the lead
tractors since, in heavy vegetation, the operators' visibility is negligible. Aerial reconnaissance of the cut is
also essential for sound planning and accurate assessment
of the clearing to be accomplished. During RVN clearing
operations, the land clearing companies of the 62d Engineer
Battalion were furnished observation helicopters on the
average of five hours per working day.
|62d Engineer
Battalion Letter, February 1971.J
For immediate protection of the land clearing
company, the desired security force is one armored cavalry
troop or one mechanized infantry company. Foot infantry
would have difficulty in keeping up with the tractors and
would have no protection from falling trees. If the area
25
��Photo # 5: Land clearing with the Rome K/G blade on a D7
Caterpillar tractor.
Rome Plow Cornpany Photograph
27
�C.
"SLASH AND BURN" CLEARING
Indigenous personnel can be hired to assist in many land
clearing operations or to conduct small-scale clearing
efforts on their own ("slash and burn" operations). They
can be eraplo*'ed in clearing vegetation adjacent to lines of
communications (LOG), around support bases, and removing/
burning debris from other operations.
The objectives of
this technique are similar to the tactical land clearing
operations with the additional function of releasing U.S.
troops for more pressing combat roles.
1. Organization
Usually, the personnel for the operations are
recruited and hired by the U.S. force's Civil Affairs staff
working in conjunction with the host country's local and
national labor office. These officials determine the
salaries and working conditions.
They attempt to get job
applicants with previous experience in clearing or lumbering.
The equipiiient, support, and supervision for the
clearers is furnished by the U.S. unit working in the AO.
This system was used by the Army during the Korean
War.
It was designed to help the Republic of Krrea's massive
unemployment problems and assist the allies in accomplishing
tasks requiring unskilled labor.
The Koreans served as
ammunition bearers, porters, kitchen police, and woodcutters.
Its success was such that at the end of the war the Korean
Service Corps (KSC) was formed on a paramilitary basis.
28
�To the present day, the KSC has provided labor augmentation
for the residual United Nations troops that have remained
in Korea.
2. Clearing Estimates and Limitations
Like tactical land clearing, production rates are
dependent upon many variables: morale, health, state of
experience, terrain, crew size, and supervision.
Planners
must also consider the tiice required to transport the
personnel to and froca the clearing sites since security
requirements would eliminate the possibility of remaining
in the area overnight.
The planning rates that have been
established by DA are:
Table I - : Clearing By Hand
I 4
VEGETATION
UNIT
HAN-HOURS PER UNIT
LIGHT: Less than 12
inches in diameter.
Acre
125
MEDIUM: 12 to 18 inches
in diameter.
Acre
350
HEAVY: Greater than 18
inches in diameter.
Acre
600
LIGHT: Same as above but
strip 10 meters wide.*
100 Linear
Meters
25
MEDIUM: Same as above
but strip 10 roaterr. wide.*
100 Linear
Meters
70**
**
*Strip clearing.
**Approxiir.ately 100 man-hours/linear acre and 280 man-hours/
linear acre.
5
Ibid.. p. 55.
29
�The use of "slash and burn" techniques for vegetation
removal is usually limited to secure areas or where major
combat operations are already in progress.
Time serves as
an additional constraint on the method since a great many
cutters are required to clear an area in a short period.
However, it is particularly useful in areas where the soil
trafficability will not support the heavy equipment required
for tactical land clearing.
D.
FIREBOMB1NG
Firebonibing is a method of reducing vegetation by burning
the foliage with incendiary munitions. The primary means to
accomplish this is by dropping drums of thickened fuel
(napalm) from helicopters or fixed wing aircraft.
The
technique is especially applicable to area clearance in locations where there is a definite dry season during the year.
The objectives of firebombing coincide with those of herbicide operations but the results differ in "zhat the trees are
permanently destroyed and not subject to regrowth. The
tactic ./as first used in RVN in 1967 during Operation PINK
ROSE in which Air Force aircraft were employed to drop the
cannisters of napalm on the target areas. Its purpose was
to burn-off enemy infiltration routes in the northern
provinces and base areas in War Zone C and D, all of which
had b^en previously treated with herbicides.
1970 I
30
[McCcnnsll
�1. Organization and Equipment
Authority to burn portions of an AO is usually
delegated to the division commanders. The Array uses the
twin-engine CH-47 helicopter ("Chinook") to conduct firebombing missions. Thickened fuel, consisting of gasoline
Mixed with M-4 fuel thickener, is placed in salvaged 55gallon drums and sling-loaded beneath the CH-47.
Fifteen
to twenty drums are carried in one lift, depending on the
aircraft's fuel load and weather conditions.
When the
aircraft is over the target, the drums are released and fall
in a cluster into the impact area.
The drops are supervised
by a command and control officer in a light observation
helicopter (LOH), and if air assets are available, security
is provided by several helicopter gunships (AH-lG).
JLTC
Rudrow j
2. Coverage and Limitations
Evaluation of the coverage of a firebombing mission
is very difficult since proper burning is subject to many
condition.0. Some of the factors that effect and limit the
coverage are:
(1) Dryness of the vegetation
(2) Wind and temperature
(3) Probability of a drum cluster detonation
upon contact with the ground
(4) Number of drums per lift.
31
�These variables dictate the use of a probabilistic model to
estimate the coverage of any particular firebombing mission.
In addition to the factors mentioned above, firebombing missions are limited by the utilization of the CH-47
in other roles.
The "Chinook" has become the workhorse for
the Army's medium lift tasks. In RVN, it has been extensively used for transportation of artillery pieces and
resupply of forward bases.
Hence, there is a high demand
for the aircraft, and the commander roust decide on which
missions he places the higher priority.
32
�III.
METMDODQGY
The alternatives for this study will be analyzed with
respect to the two primary missions of herbicide operations:
1. Removal of foliage (defoliation) in order to deny
the enemy cover and concealment.
2. Ths destruction of crops in the enemy's territory in
order to curtail his ability to forage off the land. To
accomplish this, costs for each method oust be isolated in
some uniform manner and in units to facilitate a costeffectiveness evaluation for several measures of effectiveness (MOE). The vectors resulting from this evaluation can
then be compared on an intra-systera, inter-system and forcemix basis.
The analysis of the alternatives will take the form of
the major subheadings below. Each of these sections
attempts to amplify the "how and why" of the methodology
used in Chapter IV through VII.
A.
GENERAL ASSUMPTIONS
Implicit in the assumptions for each alternative is the
adherence to the system descriptions of Chapter II. Several
general assumptions are also applicable.
In order to simplify the o-ialysis and the data collection, all alternatives are assisted to have commenced their
operations at the same point in time.
It is also assured
that all systems are in "steady state" and not subject to
33
�the initial erratic fluctuations in costs that new systems
often demonstrate prior to the occurrence of the "learning
curve" phenomena.
At the end of the systems' life, all are
given a zero residual value.
Finally, no adjustments are made to the costs for
inflation. While inflationary pressures have abated slightly, it is doubtful that the price stability of the early
1960's will return in the near future.
This could introduce
some bias when looking at yearly costs, total system cost
(T3C), and investment replacement of primary mission equipment (PME) over the planning horizon.
[Augusta and Snyder
197 oj
B.
PARAMETERS
The planning horizon for the analyses will be ten years.
Like the explicitly stated parameters for each alternative,
this is a reasonable estimate but in no way reflects any
official policy. The reviewer should be cautioned that the
planning horizon and other inputs are optimistic estimates
and adverse conditions car change thea significantly.
Where
a great deal of uncertainty exists as to the parameter
values, upper (U) and lower (L) cost bounds will be specified for each alternative. Most of these bounds reflect the
judgement of men who were involved with these systems during
counterinsurgency operations in RVN.
34
�C.
COST ANALYSIS
All costs will be determined in reference to one unit
equipment (UE) . A UE could be one specially equipped
aircraft, one crawler tractor with the Rome kit, or a crew
of indigenous cutters for "slash and burn* clearing.
With
this in mind, life cycle costs will be identified through a
generalized input structure.
Since no research and develop
ment (KD) costs are encountered, only the following major
cost categories will be investigated:
Investment Cost ( C
1)
Operating Cost (OC)
Procurement Costs
Maintenance
Stock Costs
Modernization
Replacement of Equipment due to
Attrition or Operational Loss
Initial Travel
Transportation
Replacement
Pay and Allowance
Fuel, oil and lubricants (POL)
Replacement Training
Munitions
Security
Special Control
Fisher 197 l
These inputs are used to obtain a system cost (SC) by
evaluating each cost category with respect to the major
subsystems of each alternative. The basic equation used in
the analysis is:
T LT
SC = a L«
i
j
TT
ICi-t + a L. *—
J
i j
OC<<
J
where a_ is a constant to obtain costs in the desired units
(i.e., $/year, ^/mission, or $/day) and ic*j is the jth
investment cost of the ith subsystem. Generally, costs will
be determined in units associated with basic operating tines.
35
�Ground-based systems will be evaluated in terms of dollars
per day and aviation systems in dollars per mission.
Included in the operating cost input program will be
several opportunity costs. Although they'will never be
reflected in tables of costs held by service comptrollers,
they are very real costs due to the scarcity of personnel
and equipment assets in combat. There is difficulty judging
what cost should be attached to a supervisory or security
force that could be gainfully employed in other combat operations, m order to tackle this problem in the study, the
cost assessed will be that operating cost incurred by the
force over the period that it was used.
D.
EFFECTIVENESS CRITERIA AND COST-EFFECTIVENESS MEASURES
1.
Effectiveness C r i t eria
The measures of effectiveness (MOE) should be
closely related to the mission objectives.
However, it is
very hard to quantify the results of any denial operation
because one soon gets into the realra of trying to determine
"why something did not happen."
These types of objectives
force the writer away from "objective-oriented" MOE's and
toward the "performance-oriented" effectiveness criteria.
Two KOE's will be utilized in order that a balanced
presentation of each alternative may be achieved.
a. MOE * 1 - "Area"
The first MOE will be that of "area treated,
cleared or burned per normal operating period."
36
These
�three terras show the different effects that each alternative
has on the terrain. However, they present an evaluation of
each system's effectiveness and give a specific indication
of their performance capability during a normal operating
period.
b. MOE # 2 - Constrained Cost Minimization
This MOE is designed to determine which alternatives can complete a given mission subject to the exigencies
of combat.
It attempts to take a reasonable mission of
denying the enemy cover and concealment in a given area and
requiring that this be completed prior to certain time
limits and within theater asset constraints.
In program
format:
Minimize the cost of denying cover and concealment in
a 6,000 acre base area
Subject to:
(1) Mission accomplishment in 30 days or less.
(2) Mission asset requirements w4thin the
supply capability of the responsible
commander.
A vegetation removal mission was chosen since
these were the roost common of the herbicide missions in RVN.
The figure of 6,000 acres was designated because thij is
approximately 25 grid squares on a 1:25,000 or 1:50,000
topographical map and could easily be a suspected insurgent
base area. Although this is a large scale mission, it is
not unreasonable since there have been defoliation/clearing
operations in War Zone C and other parts of Military Region
37
�Ill in RVN that encompassed larger areas (during Operation
3W3CTIO8 CITY). The effects of reducing the mission size
are also examined in Chapter VIII, Section B.
Constraint # 2 of the program retires the determination of what will be the "supply capability of the responsible coonander." To resolve this, the author will use his
judgement and past experience in RVN to determine whit are
"reasonable" and "unreasonable" asset requirement*? to
accomplish a particular mission.
2. Cost- E ffectIvenes s Measureg
Using the cost measures of the analysis section and
the effectiveness criteria, cost-effectiveness measures can
be developed for each system in dollars per acre.
These
measures can then be segregated into mission categories for
foliage removal and crop destruction with maximum and oiniraura cost limits. These coupled with the cost minimization
v. ctors will help illuminate the differences in the systems,
their costs, and their effectiveness in support of counterinsurgency operations.
E.
PARAMETER SENSITIVITY
Sensitivity analysis will be used to test the parametric
uncertainties in each system. The testing will examine the
system costs as the parameters vary over a reasonable range
of values. Although the only relevant costs are dollar
costs, the sensitivity tables will show dollars and cents.
Certainly, the calculation of costs to the actual pennies
38
�is not relevant or meant to be a serious cost estimate.
However, this is done since they demonstrate the orders of
magnitude of change over the range of the parameter values.
39
�IV.
A.
ANALYSIS OF AERIAL DELITSRY OF HERBICIDES
ASSUMPTIONS
1.
UC-123
a.
Each aircraft has an ejected life of ten years
after modification for herbicide operations.
b.
hours.
[Major Pyatt]
Each sortie has an expected duration of two
[Major Hidalgo]
c.
Flights over a given target consist of between
two and seven h^xbicide aircraft.
d.
Security for each flight consists of four USAF
A-1E "Skyraider" aircraft.
Control for each flight consists
of one forward air controller (FAC) in a USAF OV-10 "Bronco."
[Downs and Scrivner
e,.
1970J
Each UC-123K has a 90 per cent coverage effi-
ciency for its 1,000 gallon load.
{See sensitivity analy-
sis. Sec. E)
2.
UH-1
a.
A variety of "Hueys" haie been employed in RVN.
For this study, use of the UH-1H is assumed.
b.
Each sortie has a duration of one-half hour.
Rudrew]
c.
A flight over a given target consists of one
helicopter.
d.
The AGAVENCO sprayer wJH be the only helicopter-
raounted system considered.
Although the capacity of the
40
�tank is 200 gallons, weight limitations tinder combat
conditions curtail the load,
will be analyzed.
e.
A 100 gallon per mission load
[t,TC Sanchesj
When available, armed helicopter security
consists of two AH-lG "Cobras."
f.
and [DA -re 3-16 1969 ]
[LTC Rudrow]
the OT-lH has a 90 per cent coverage efficiency
for its 100 gallon load.
It is employed under the same
operational and climatic conditions as the UC-123 missions.
{Also see sensitivity analysts, Sec. E)
B.
PARAMETERS
!
•
Flying Hours
Since the DC-123K has a two-hour mission duration,
25 missions per month per aircraft (or 600 hours per year)
will be the study parameter. Data indicates that the sortie
rate varies considerably over a year's operation and that the
use of 25 sorties per month would not be unreasonable [Major
Hidalgo J . A similar number of flying hours per year for the
UH-lH would dictate a sortie rate of 100 missions per month.
However, this is probably less than the normal rate since
the UH-lH has a prograrsed flying-hour limit of up to 960
houis per year in an active combat environment.
Manual (FM) 101-20
[DA Field
1970J . This implies that the effects
of the sortie generation rate for both aircraft should be
examined in a sensitivity analysis (Section E).
41
�2-
Cost Bounds
Bounds on certain portions of the herbicide costs
are set by the variation in security, control, and transportation costs that can occur in normal operations.
These
parameters set the "optimistic and pessimistic" bounds for
system cost. Since the UC-123 flights range from two to
seven aircraft, the security and control cost (for four
A-lE's and one OV-10) must be pro rated in accordance with
the number of herbicide aircraft per flight to obtain a cost
for one unit equipment (UE). Costing the helicopter system
does not present this problem since the operations are
usually conducted with one UH-1 (assumption c>.
Hence, the
security costs for a UH-1 mission can range from zero to the
cost of using two "Cobras" for one-half hour.
The UH-1 has
an additional bound on the i»..3stment cost formed by the
mode of transporting (surface or air) the AGAVENCO system to
the cornbat theater.
C.
COST ANALYSIS
1.
Is_o la t ion o f Re le vant Cos ts
A detailed breakdown of these costs can be found in
Appendix A.
a. UC-123K
Research and Development; None.
Investment Costs for the aircraft subsystem:
(1) Initial procurement of the aircraft is a
sunk cost since the C-123B's were drawn from air assets that
42
�existed in the Air Force inventory. Hence, it will not be
considered.
(2) Jet engine modification:
C-123B to a turbo-jet model (C-123K)i
Conversion of the
$302,732/aircraft.
[Miss Lucky]
Operating Costs for the aircraft subsystem:
[
(1) Operating and nsainteaance (O&M): $7QO,000/
^
Captain Wallace j
(2) Modernization cost: h two per cent per year
cost is incurred by each aircraft for raodernization expenditures.
.02 x 5870,000/aircraft = $l?,400/aircraft/year.
[captain Wallace]
(3) Security costs:
A-1E is $200/AOur.
The operating cost for one~~
Major Sims
The munition expenditures
for one A-iF; are $1250/raission.
f LTC Cooper]
For a two-
hour mission with four A-lE's, the cost amounts to $6600/
mission.
(4) Control costs:
The operating cost for the
OV-10 is $54/liour and $1000/aircraft for a full load of
munitions.
[liTC Monoham 1 This amounts to a control cost
i
J
of $1108/roission.
(5) Combat attrition rates are negligible since
<Nfc
only two aircraft have been lost to enemy fire since 1962.
j Downs and Scrivner
1970 ]
43
�Investment Cost for the aerosol subsystem;
(1) The dispenser mechanisii consists of the
installation of the Hayes AA-45 system at a cost of $37,254/
aircraft.
[Miss Lucky I
(2) Additional armor plating: $19,354/aircraft.
[Miss Lucky]
Operating Costs for the aerosol subsystem;
( ) Maintenance of the dispenser systcs* training
1
the operators, and stocking spare parts are included in the
cost of operating the aircraft.
( ) Cost of herbicides:
2
The USAF is responsible
for procurement of herbicides for all users. The cost of
the agent includes shipment and storage costs.
[Mr. Carter]
AGENT
COST/GALLON
COST/MISSION
WHITE
$7.78
$7,780
ORANGE
$7.24
$7,240
BLUE
$2.31
$2,310
b.
UH-1H
Research and Development: Hone.
Investment Cost for UH-lH; This is a sunk cost
since the helicopter used for herbicide operations is diverted from Army aviation assets on a "need* basis.
Operating Costfor UH-lH;
( ) O&M costs are rated at 15 per cent of the
1
aircraft procurement cost.
JMr. Donaldson] Since the UH-lH
44
�costs $266,578 [DA FM 101-20 1970J , the O&M cost is
approximately $40,000/year.
(2) Crew salaries are not included in Army O&M
estimates.
Normal conibat crew on a UH-1 is two pilots and
two door gunners.
These yearly opportunity costs amount to:
2 x $14,000/officer/year = $28,000/year
2 x $10,000/enlisted man/year = $2Q,000/year [DA Fact
Sheet
1971j and I Major Howe ]
(3) Security costs range from zero (no security)
to $200/mission for two AH-lG "Cobras." (Appendix A)
Investment Costs forthe aerosol subsystem;
(1) Procurement of AGAVENCO system: $7,850
[MT. Drake|
(2) Transportation cost for the AGAVENCO: $545
by ship and $1,937 by aircraft. (Major Howe 1
(3) The expected life of the UH-1H equipped for
herbicide missions is ten years. [ Mr. Donaldson]
Operating Costfor theaerosol subsystem;
( ) The maintenance cost of the AGAVENCO system
1
is nine per cent of the procurement cost: S707/year. [ Mr.
Drake]
(2) The system requires one operator: $iO,000/
year.
(3) Herbicide costs:
45
�AGENT
COST/GALLON
COST/MISSION
WHITE
$7.78
§778
ORAHGE
$7.24
$724
BLUE
$2.31
$231
IW. CarltonJ
2. Yearly Costs
Using the relevant costs and the herbicide parameter,
a yearly system cost can be developed from the formula:
SC = a L, L, ICjj + b Lf L» OCii
J
i
j
i 1
wr«re
a_ is the reciprocal of the expected life (and equal
to the planning horizon) and b
is a dimensional constant
to obtain costs la dollars per year.
a.
Identification of Costs for UC-123K
Investmant Cost = 1/10 (Engine modification +•
spray system + arnor) = $35,934/year.
Operating Cost = O&M cost + Security cost +
Control cost + Agent cost.
The security and control (S&C) costs for a UE on any
particular mission can be found in the following manner:
Security cost (U):
Security cost ( )
L:
$6600/flight
2 aircraft/flight
S6600/fliaht
7 aircraft/flight
_ $3300/aircraft
=
?943/aircraft
(A similar procedure determines the control cost.) Using
the parameter that a UC-123K flies 25 missions per month,
46
�the yearly mission rate would be 300 missions (msn) per
year. A typical calculation, this one for the upper bound
using Agent WHITE, is as fallows:
Operating Cost = §700,000/yr + §17,400/yr + 300rasn/yrx
§33QO/msn + 300 msn/yr x §554/msn + 300 msn/yr x §778Q/rasn =
§4,207,600/year.
Table IV-1: Yearly Costs for UC-123K
(Costs in Millions of Dollars per Year)
AGENT
LOWER BOUND
UPPER BOUND
WHITE
§3.417
$.4
424
ORANGE
§3.257
§4.081
BLUE
§1.777
§2.603
b.
Identification of Costs for UH-1H
Investment Cost - 1/10 (AGAVEHCO Cost +
Transportation Cost) = $979/year (U) or $840/year ( )
L.
Operating Cost = O&M Cost + Security Cost +
Agent Cost.
The UH-1 will fly 100 missions per month.
(Section B) An
upper bound cost using Agent WHITE: Operating Cost §98,707/yr 4- 1200 msn/yr x $200/msn + 1200 msn/yr x $778/msn
« §l,272,307/year.
Table *V-2: Yearly Costs for UH-1H
(Costs in Millions of Dollars per Year)
AGENT
LOWER BOUND
UPPER BOUND
WHITE
§1.033
§1.273
GRANGE
§ .968
§1.208
BLUE
§ .377
§ .617
47
�Table IV-2: Yearly Costs for UH-1H
(Costs in Millions of Dollars per Year)
AGEKT
LOWER BOUND
WRITE
$1.033
$1.273
ORANGE
$ .968
$1.208
BLUE
$ .377
$ .617
c.
UPPER BOUND
Remarks
At this point a total system cost could be
readily identified. However, like the yearly cost, it is
extremely sensitive to the particular input parameters, The
parameter of "missions per year" accounts for a major
portion of the system cost solely by virtue of its multiplicative role in the cost formula.
The reviewer must
consider this when evaluating the systems with respect to
the outlay of funds on a yearly basis for a UE. More
important than the magnitude of the costs involved is the
relative difference between the two systems.
3. Mission Costs
cost of a herbicide mission gives the reviewer
a better insight into the dollars involved for a UE. This
cost is more suitable to relate to an effectiveness
criterion that is oriented toward perfon=ance.
Mission Investment Costt
Summation of the Investment Costs
(Expected Life)x(Number of Xsn/Year)
48
�Mission Operating Cost:
Summation of O&M Costs/year
Number of Msn/Year
Summation of Security, Control,
^ ^ent costs/Mission
fable IV-3: PC-123K Missioa Costs
(Dollars per Hission)
AGENT
LOWER BOUND
OPPER BOUND
1C
OC
SC
1C
OC
SC
WEITE
$120
$11,272
$11,392
$120 $14,025
$14,145
ORANGE
$120
$10.732
$10,852
.'12®
$13,485
$13,605
BLUE
$120
$ 5,802
$ 5,922
$128
$ 8,555
$ 8,675
The costs are not categorized for the helicopter since the
UE-lP investment cost is negligible.
Tal/le IV-4t UH-lH Miss JOB Costs
(Dollars per Mission)
AGENT
LOWER BOUN*?
PPfgR BOUND
WHITE
$861
$1061
ORANGE
$807
$1007
BLUE
$314
$ 514
It is evident after this analysis that the agent
cost comprises a large portion of the system cost for both
alternatives.
It accounts for approximately 50 per cent of
the UC-123K costs and about 80 of the 0«-1 mission cost.
The extent of this can be examined by locking at the two
systems participating in defoliation operations.
If the
cost of the agent is varied from one dollar to ten dollars
per gallon, the effect on "dollars per mission" can be
49
�better illustrated.
This can also allow the reviewer the
opportunity to examine the cost expectation of a sudden
technicological breakthrough in the chemical industry
causing a decrease in prices or if current trends in upward
prices continue.
Table IV-5s Cost Variation Due to Agent Costs
(Dollars per Mission)
COST OF &GEHT
SYSTEM COST
($/Gal)
TJH-1
(S/Msn) UC-123
Hin
D.
Min
183
283
383
483
583
683
783
883
983
1
2
3
4
5
6
7
8
9
10
Max
383
483
583
683
783
883
983
4612
5612
6612
7612
8612
9612
10612
11612
12612
13612
1083
1183
1283
1083
Max
7365
8365
9365
10365
11365
12365
13365
14365
15365
16365
EFFECTIVENESS CRITERIA AND COST-EFFECTIVENESS MEASURES
1.
Effectiveness Criteria
a.
MOE fl - "Area"
This measure of effectiveness, "acres treated
per mission," presents the systems' overall or net effectiveness during a normal operating period.
.
Gallons/Mission
Effectiveness criterion (EC) = e x Gailons/Acre "
where e is the coverage factor.
EC
=
.9
x
For UC-123 operations,
1000 qal/tosn , 30Q
3 gal/acre
50
acres/mission
�EFFECTIVENESS CRITERIA (Acres/Mission)
AGENT
LOWSR BOUND
UH-1H
UC-123
UPPERBOUND
UH-1H
UC-123
WHITE
30
300
30
300
ORANGE
30
300
30
300
BLUE
60
600
30
300
b. MOE # 2 - Constrained Cost Minimizatior
This HOE takes the following mathematical
programming formats
Minimize the cost of defoliating 6000 acres
Subject to:
Mission completion 1 30 days
Assets required 1 Command's supply
capability
In addition to the assumptions of this chapter, several more.
are necessary to restrict the analysis.
(1) Flights by UC-123K's will be examined la
relation to a minimum of two and a maximum of seven aircraft
per flight.
( ) Agent ORANGE will be the defoliant.
2
( ) Spraying must be completed within five days.
3
The last restriction is necessary since herbicides require approximately three to four weeks t3 act on
tropical vegetation. For herbicides to be effective, they
must remove a sufficient amount of foliage to deny the
enemy use of the terrain for base areas and daylight
movement and to permit improved aerial observation.
51
The
�requirement is amplified by the following charts
Defoliant
Rate
1 \fk
2 Vk
1 H° 3 fto
ORANGE
3 gal/acre
1/
98
6 Ho
1 Yr
73/32 89/73 79
66
54
(The figure to the left of the slash represents percentage
of leaves desicated; that to the right represents the
percentage of leaves defoliated.
The single figure is
defoliation.)6
Therefore, it is imperative that the a«ent be
applied quickly to insure naximuin defoliation at the end of
30 days.
2. Cost-Sffeetiveness Hea sures
a. HOE tl
Cost-Effectiveness Measure =
Mission Cost
Effectiveness Criterion
Table IV-6A: Aerial Delivery of Herbicides
(Dollars per Acre)
AGENT
LOWER BOUND
UPPER BOUND
UH-lH
UC-123
UH-1H
UC-123
WHITE
§29
$38
$35
§47
ORANGE
$27
$36
§34
$45
BLUL
$ 5
$10
$17
$29
Breaking these costs into the two primary mission
categories (defoliation and crop destruction), isaxirauro and
House, W. B. and others. Assessment of the Ecological
Effects of Extensive or Repeated Use of Herbicides, p. 141,
Midwest Research Institute, 1967.
'
~~~
52
�minimum limits are formed.
The mission categories facilitate
comparison with the other alternatives.
This is readily
done since ORANGE and WHITE are general purpose defoliants
and BI-UE is exclusively used for crop destruction.
In the
next table, the tgaximuin and ^ntiimaa limits on defoliation
missions are formed by using Agent WHITE'S upper bound and
QRASGE's lower bound.
The uaximum and minimum cost vectors
for crop destruction can be taken directly from Table IV-6A.
Table IV-6B:
Cost-Effectiveness Measures for Aerial
Delivery of Herbicides
(Dollars per Acre)
MISSION
UH-1H
UC-123
MIN
MAX
MIN
MAX
Defoliation
$27
$35
$36
$47
Crop Destruction
$ 5
$17
$10
$29
b. HOE #2
Defoliation of a 6,000 acre area would require
ten flights of two UC-123K's or three flights of seven
IK-123K aircraft (each aircraft covering 300 acres per
mission).
The fiva-day dissemination period could easily
be accomplished even with the smallest flight.
If a
squadron organization existed, the requirement would have
little or no effect.
Upper Bound:
$13,605/aircraft/msn x 2 aircraft x 10 missions =» $272,100.
53
�Lower Bound:
$10,852/aircraft/n»sn x 7 aircraft x 3 nissions - $227,892.
Using the UH-lH's effectiveness criterion of 30
acres per mission, 200 sorties would be required.
This
implies that 100 helicopter flying hours would be needed in
a five-day period. This would be a tremendous drain on the
aviation assets of a division commander and would mean that
he would have to divert five to ten helicopters a day for
the better part of a week to psrlcrs the defoliation task,
Hence, a violation of the second constraint might be
realized.
Table IV-7: Minimum Cost Program For Defoliation
(Costs in Dollars)
SYSTEM
LOWER BOUND
UPPER BOUND
UC-123K
$227,892
$272,100
UH-1B**
$161,400
$201,400
The program constraints make the UH-1 virtually
infeasible for a mission of tteis scale.
E.
PARA1-CETER SENSITIVITY
The sensitivity analysis is presented to determine the
effect of variation of three of the parameterized inputs
for the herbicide alternative. The tests are performed on
the icaximura and minimum limits for the cost-effectiveness
categories in Table IV-6B.
1. Sensitivity of Sortie Generation Rate
a. UC-123 (Table IV-8A & SBj
54
�A sensitivity analysis indicates that this
parameter is not as crucial to the system cost explanation
as one might expect. Examination of the costs indicates
that even at the lower number of sorties per month the
system cost does not experience any appreciable rise. As
flying hours increase past the 600 hour per year mark, the
cost begins to experience an almost linear decrease.
55
�TABLE IV-8A
SENSITIVITY ANALYSIS - HERBICIDE DELIVERY BY UC-123K
SENSITIVITY OF SORTIE GENERATION RATE ($/ACRE)
DEFOLIATION
0 & M COST
MIN
MAX
SYSTEM COST
M|N
MAX
HOURS
PER YR.
INVESTMENT
COST
15.
360.
0.67
41.09
52.07
41.75
52.73
16.
384.
0.62
40.26
51.23
40.88
51.86
17.
408.
0.59
39.53
50.50
40.11
51.09
18.
432.
0.55
38.87
49.85
39.43
50.41
19.
456.
0.53
38.29
49.27
38,82
49.79
20.
480.
0.50
37.77
48.74
38.27
49.24
21.
504.
0.48
37.29
48.27
37.77
48.74
22.
528.
0.45
36.86
47.84
37.32
48.29
23.
552.
0.43
36.47
47.44
36.90
47.88
24.
576.
0.42
36.11
47.08
36.52
47.50
25.
600.
0.40
35.77
46.75
36.17
47.15
26.
624.
0.38
35.47
46.44
35.85
46.83
SORTIES
PER MO.
�TABLE IV-8A (Continued)
SORTIES
PER MO,
HOURS
PER YR.
INVESTMENT
COST
27.
648.
0.37
35.18
46.16
35.55
46.53
28.
672,
0.36
34.92
45.90
35.28
46.25
29.
696.
0.34
34.67
45.65
35.02
46.00
30.
720.
0.33
34.45
45.42
34.78
4.6
57
31.
744.
0.32
34.23
45.21
34.55
45.53
32.
768.
0.31
34, J3
45.01
14.34
45.32
33.
792.
0.30
33.84
44.82
34.14
45.12
34.
816. '
0.29
33.66
44.64
33.96
44.93
35.
840.
0.29
33.50
44.47
33.78
44.76
36.
864.
0.28
33.34
44.32
33.62
44.59
37.
88d.
0.27
33.19
44.17
33.46
4.4
44
38,
912.
0.26
33.05
44.02
33.31
44.29
39.
936.
0.26
32.91
43.89
33.17
44.15
40.
960.
0.25
32.79
43.76
33.03
44.01
OPERATING COST
MIN
MAX
SYSTEM COST
MIN
MAX
�TABLE IV-8B
SENSITIVITY ANALYSIS - HERBICIDE DELIVERY BY UC-123K
SENSITIVITY OF SORTIE GENERATION RATE ($/ACRE)
CROP DESTRUCTION
SORTIES
PER MOT
HOURS
PER YR,
INVESTMENT
COST
OPERATING COST
MIN
MAX
SYSTEM; COST
MIN
MAX
15.
360.
0.67
12.66
33.83
12.33
34.50
16.
384.
0.62
12.22
33.00
11.91
33.63
17.
408,
0.59
11.84
32.27
11.55
32.86
18.
432.
0.55
11.50
31.62
11.22
32.17
19.
456.
0.53
11.19
31.03
10.93
31.56
20.
480.
0.50
1.2
09
30.51
1.7
06
31.01
21.
504.
0.48
10.67
30.04
10.43
30.51
22.
528.
0.45
10.44
29.60
10.21
30.06
23.
552.
0.43
10.23
29.21
10.02
29.64
24.
576,
0.42
10,04
28.85
9.84
29.27
25.
600.
0.40
9.87
28.52
9.67
28.92
Ul
oo
�TABLE IV-8B (Continued)
SORTIES
PER KO.
HOURS
PER YR.
INVESTMENT
COST
OPERATING -COST
MIN.
MAX.
SYSTEM COST
MIN.
MAX.
26.
0.38
9.71
28.21
9.52
28.60
27.
648.
0.37
9.56
27.93
9.38
28.30
28.
672.
0.36
9.42
27.66
9.24
28.02
29.
696.
0.34
9.29
27.42
9.12
27.76
30.
in
624.
720.
0.33
9.17
27.19
9.01
27.52
31.
744.
0.32
9.06
26.97
8.90
27.30
32.
768.
0.31
8.95
26.77
8.80
27.09
33.
792.
0.30
88
.6
26.59
8.70
26.89
34.
816.
0.29
8.76
26.41
8.62
26.70
35.
840. '
0.29
8.67
26.24
8.53
26,53
30.
864.
0.28
8.59
26.08
8.45
26.36
37.
888.
0.27
8.51
25.93
8.38
26.20
30.
912.
0.26
84
.4
25.79
8.31
26.05
39.
936.
0.26
8.37
25.66
8.24
25.91
40.
960.
0.25
8.30
25.53
8.18
25.78
�CHART IV-1:
SENSITIVITY OF SORTIE GENE8ATION RATE (UC-123)
(System Cost (SC) in Dollars/Acre)
C
50..
DEFOLIATION
30 „ _
20 . ..
CROP D E S T R U C T I O N
10 . „
4
360
-I
-4
&0
600
4
720
Plying Hours per Year
60
840
{->
960
�b.
UH-1H (Table IV-9A & 9B)
fable 9A and 9B show that the costs per acre
fcr defoliation and crop destruction are virtually insensitive to the sortie generation rate of the aircraft.
"The
cause for this is the dominance of the agent cost.
For a
mission flown with Agent ORANGE (lower bound), the cost less
the defoliant is $83 per mission.
Shis condition persists
throughout this analysis.
2.
Sensitivity of Security and Control Costs
a.
UC-123K (Table IV-10)
In the analysis, S & C costs range from $1100
per mission to approximately $3350 per mission.
The lower
spectrum of the scale shows the costs that might be incurred
in a low-intensity environment that would require little or
no security.
The costs above $4000 per mission indicate the
incremental changes when high-performance aircraft are allocated to security roles in lieu of propeller-driven "Slcyraiders."
b.
UH-1H (Table IV-11A & 11B)
c.
Both sets of tables (10 and 11) show the effect
that security has on determining bounds on cost estimates.
They also point out that the difference in Agent WHITE and
Agent ORANGE for a similar security posture is almost
negligible.
61
�TABLE IV-9A
SENSITIVITY ANALYSIS - HERBICIDE DELIVERY BY UH-1
SENSITIVITY OF SORTIE GENERATION RATE ($/ACRE)
DEFOLIATION
SORTIES
PER MO.
HOURS
PER YR.
0 & M COST
MAX.
INVESTMENT
COST
MIN V
SYSTEM COST
MAX.
MIN.
GO.
0.05
28.70
37.17
28.74
37.22
64.
384.
0.04
28.42
36.88
28.45
36.93
68.
cr>
to
360.
408.
0.04
28.17
36.63
28.20
36.67
72.
432.
0.04
27.94
36.41
27.97
36.45
76.
456.
0.04
27.74
36.21
27. 77
36.24
80.
480.
0.03
27.56
36.03
27.59
36.06
84.
504.
0.03
27.40
35.86
27.43
35.90
88.
528
0.03
27.25
35.72
27.28
35.75
92.
552.
0.03
27.11
35.58
27.14
35.61
96.
576.
0.03
26.99
35.46
27.01
35.48
100.
600.
0.03
26.88
35.34
26.90
35.37
104.
624.
0.03
26.77
35.24
26.79
35.26
�TABLE IV-9A (Continued)
SORTIES
PER MO.
HOURS
PER YR.
INVESTMENT
COST
O & M COST
MIN.
MAX.
SYSTEM COST
MIN.
MAX.
108.
648.
0.03
26.67
35.14
26.69
35.16
112.
672.
0.02
26.58
35.05
26.60
35.07
116.
696.
0.02
26.50
34.96
26.52
34.99
120.
720.
0.02
25.42
34.88
26.44
34.91
124.
744.
0.02
26.34
34.81
26.36
34.83
128.
768.
0.02
26.28
34.74
26.29
34.76
132.
792.
0.02
26.21
34.G8
26.23
34.70
136.
816.
0.02
26.15
34.62
26.17
34.64
140.
840.
0.02
26.09
34,156
26.11
34.58
144,
864.
0.02
26.04
34. 90
86.03
34.52
140.
883.
0.02
25.99
34.45
26.00
34.47
152.
912.
0.02
25.94
34,40
25.95
34.42
156.
936.
0.02
25.89
34.36
25.91
34.38
160.
960.
0.02
25.85
34.31
25.86
34.33
�TABLE IV-9B
SENSITIVITY ANALYSIS - HERBICIDE DELIVERY BY UH-1
SENSITIVITY OP SORTIE GENERATION RATE (§/ACRE)
CROP DESTRUCTION
SORTIES
PER MO.
HOURS
PER YR.
INVESTMENT
COST
O & M COST
MIN.
MAX.
SYSTEM COST
MIN.
MAX.
60.
360.
0.05
6.13
18.94
6.15
18.98
64.
384.
0.04
5.99
18.65
6.01
18.69
68.
408.
0.04
5.87
18, 10
5.88
18.44
72.
432.
0.04
5.75
18,17
5.77
18.21
76.
456.
0.04
5.65
17.97
5.67
18.01
80.
480.
0.03
5.5b
3,7.79
5.58
17.83
84.
504.
0.03
5.4Q
17.63
5.50
17.66
88.
528.
0.03
5.41
17.48
5.42
17.51
92.
552.
0.03
5.34
17.35
5.42
17.51
96.
576.
0.03
5.28
17.22
5.29
17.25
600.
0.03
5.22
17.11
5.23
17.14
100.
�TABLE IV-9B (Continuea)
SORTIES
PER MO^
HOURS
PER YR.
INVESTMENT
COST
O & M COST
SYSTEM COST
MIN.
MAX.
MIN.
MAX.
104.
624.
0.03
5.17
17.00
5.18
17.03
108.
648.
0.03
5.12
16.91
5.13
16.93
112.
672.
0.02
5.07
16.81
5.08
16.84
116.
690.
0.02
5.03
16.73
5.04
16.75
120.
720.
0.02
4.99
16.65
5.00
16.67
124.
744.
0.02
4.96
16.58
4.96
16.60
120.
768.
0.02
4.92
16.51
4.93
16.53
132.
792.
0.02
4.89
16.44
4.90
16.46
136.
816.
0.02
4.86
16.30
4.67
16.40
140.
840.
0.02
4.83
16.33
4.84
16.34
144.
864.
0.02
4.80
16.27
4.81
16.29
148.
888.
0.0?
4.78
16.22
4.78
16.24
152.
912.
0.02
1.75
16.17
4.76
16.19
1S6.
936.
0.02
4.73
16.12
16.14
160.
960.
0.02
4.71
16.08
4.74
4.71
Ul
16.10
�CHART? IV-2:
SENSITIVITY OF SORTIE GENERATION RATE (UH-1)
(Systes Cost {SC> in Dollars/Acre)
SC
DEFOLIATION
30,.
25..
CROP
10..
360
480
DESItUCIIOH
600
Flying Hours per Year
�TABLE IV-10
SENSITIVITY ANALYSIS - HERBICIDE DELIVERY BY UC-123K
SENSITIVITY OF SECURITY & CONTROL COST
($/MSN)
DEFOLIATION
SECURITY + CONTROL = TOTAL S & C COST
SYSTEM COST
($/ACRE)
(S/MSN)
HIS.
0.
600.
1200.
10.
80
2400.
3000.
3600.
4200.
40.
80
50.
40
60.
00
6600.
0
100
200
300
400
500
600
700
800
900
1000
1100
0
.
700.
10.
40
2100.
2800.
3500.
40.
20
40.
90
5600.
6300.
70.
00
7700.
MAX.
32.50
34.84
37.17
39.50
41.84
44.17
46.50
48.84
51.17
53.50
55.84
58.17
34.30
36.64
38.97
•'•1.30
43.64
45.97
48.30
50.64
52.97
55.30
57.64
59.97
8.04
9.20
10.37
11.54
12.70
13.87
15.04
16.20
17.37
18.54
19.70
20.87
16.07
18.40
20.74
23.07
25.40
27.74
30.07
32.40
34.74
37.07
39.40
41.74
CROP DESTRUCTION
0.
600.
1200.
1800.
2400.
3000.
3600.
4200.
4800.
5400.
60.
00
6600.
0
100
200
300
400
500
500
700
800
900
1000
1100
0.
700.
1400.
21CO.
2800.
3500.
4200.
4900.
5600.
6300.
70.
00
7700.
67
�TABLE IV-11A
SENSITIVITY ANALYSIS... HERBICIDE DELIVERY BY 13H-1
SENSITIVITY OF SECURITY COSTS
DEFOLIATIGS
SECUKI7V COST ($/KSN)
SYSTEM COST ($/ACRS)
Mat.
0.
10.
20.
30.
40.
50.
(0.
70.
80.
90.
100.
110.
120.
130.
140.
150.
160.
170.
180.
190.
200.
210.
220.
230.
240.
250.
260.
270.
280.
290.
300.
MAX.
26.90
27.24
28.70
29.03
27.57
21. y&
28.24
28.57
28.90
29.24
2S.57
25.90
30.24
30.57
30.90
31.24
31.57
31.90
32.24
32.57
32.90
33.24
33.57
33.90
34.24
34.57
34.90
35.24
35.57
35.90
36.24
36.57
36.90
29.37
2S.70
30.03
30.37
30.70
31.03
31.37
31.70
32.03
32.37
32.70
33.03
33.37
33.70
34.03
34.37
34.70
35.03
35.37
35.70
36.03
36.37
36.70
37.03
37.37
37.70
38.03
38.37
38.70
�TABLE IV-11B
SENSITIVITY ANALYSIS - HERBICIDE DELIVERY BY UH-1
SENSITIVITY OF SECURITY COSTS
CROP DESTRUCTION
SECURITY COST
SYSTEM COST
(S/ACRE)
(S/KSN)
MIN.
0.
10.
20.
30.
4.
0
50.
6.
0
70.
8.
0
9.
0
100.
110.
120.
130.
140.
150.
160.
170.
180.
190.
200.
210.
220.
230.
240.
250.
260.
270.
280.
290.
3QO.
MAX,
5.23
5.40
5.57
5.73
5.90
6.07
6.23
6.40
6.57
6.73
6.90
7.07
7.23
7.40
7.57
7.73
7.90
80
.7
8.23
8.40
8.57
8.73
8.90
9.07
9.23
9.40
9.57
9.73
9.90
10.07
10.23
10.47
1.0
08
11.13
11.47
11.80
12.13
12.47
12.80
13.13
13.47
13.80
14.13
14.47
1.0
48
15.13
15.47
15.80
16.13
16.47
16.80
17.13
17.47
17.80
18.118.47
18.80
19.13
19.47
1.0
98
20.13
20.46
�3. Sensitivity of Effectiveness Criterion (Table IV-12
and Table IV-13)
These tables demonstrate the effect on system cost
when commanders insist on conducting herbicide operations
when conditions such as temperature, wind, and weather are
less than favorable.
4. Remarks
Prior to completing the analysis, the effect of
variation of the agent cost in terms of dollars per acre c .
?n
be investigated.
(Reference Table IV-5) These show the
dominance of the agent costs.
Cost Variation Due to Agent Costs
(Cost in Dollars per Acre)
COST OF AGENT
§1
UC-123 ($/ACRE)
M1N.
§ 2
$ 3
$4
$ 5
$ 6
$7
$ 8
$9
§10
UH-1 ($/ACRE)
MAX.
MIK.
MAX.
$13
$15
$19
$22
$25
$29
$32
$35
$39
$42
$45
$25
$28
$31
$35
$38
$41
$45
$48
$51
$55
$ 6
$ 9
$16
$19
$23
$26
$29
$33
$36
$39
$43
$13
$16
$19
$23
$26
$29
$33
$36
70
�SABLE IV-12
SENSITIVITY ANALYSIS - HERBICIBg DELIVERY BY UC-123
SENSITIVITY OP EFFECTIVENESS OF COVERAGE
DEFOLIATION
COVERAGE
(ACRES/MSB)
SYSTEM COST
(I/ACRE)
% EFFECTIVE
KIN.
220.
230.
240.
250.
260.
270.
280.
290.
300.
310.
320.
330.
49.33
47.18
45.22
43.41
41.74
40.19
38.76
37.42
36.17
35.01
33.91
32.89
66.0
69.0
72.0
75.0
78.0
81.0
84.0
87.0
90.0
93.0
96.0
99.0
MAX.
64.30
61.50
58.94
56.58
54.40
52.39
50.52
48.78
47.15
45.63
44.20
42.86
CROP DESTRUCTION
COVERAGE
(ACRES/MSN)
MIN.
220.
230.
240.
250.
260.
270.
280.
290.
300.
310.
320.
330.
SYSTEM COST
($/ACRE)
MIN.
6.
60
6.
90
72.0
75.0
78.0
8.
10
8.
40
8.
70
9.
00
93.0
9.
60
9.
90
71
MAX.
13.46
12.87
12.34
11.84
11.39
10.97
10.58
10.21
9.87
9.55
9.25
8.97
MAX.
40
4.
460.
480.
50.
0.
520.
540.
560.
580.
60
0.
620.
640.
650.
EFFECTIVE
39.43
37.72
36.15
34.70
33.37
32.13
30.98
29.91
28.92
27.98
27.11
26.29
�CHART IV-3: SENSITIVITY OF EPFECTIVE2GSS OF COVERAGE (UC-123)
S60
$50 ' ~
S401--
S 3 0 --
S 20 . .
CROP
DESTRUCTION
S 10 ..
100
Percentage of Effectiveness
72
�TABLE IV-13
SENSITIVITY ANALYSIS - HERBICIDE DELIVERY BY UH-1
SENSITIVITY OF EFFECTIVENESS OF COVERAGE
DEFOLIATION
COVERAGE
(ACRES/MSN)
SYSTEM COST
($/ACRE)
% EFFECTIVE
MIN.
22.
23.
24.
25.
26.
27.
28.
29.
30.
31.
32.
33.
36.68
35.09
33.62
32.28
31.04
29.89
28.82
27.83
26.90
26.03
25.22
24.45
66.0
69.0
72.0
75.0
78.0
81.0
84.0
87.0
90.0
93.0
96.0
99.0
MAX.
48.23
46.13
44.21
42.44
40.81
39.30
37.90
36.59
35.37
34.23
33.16
32.15
CROP DESTRUCTION
COVERAGE
(ACRES/MSN)
MIN.
22.
23.
24.
25.
26.
27.
28.
29.
30.
31.
32.
33.
SYSTEM COST
($/ACRE)
MIN.
66.0
6.
90
72.0
75.0
78.0
81.0
8.
40
87.0
90.0
93.0
96.0
99.0
73
MAX.
7.14
6.83
6.54
6.28
6.04
5.81
5.61
5.41
5.23
5.06
4.91
4.76
MAX.
44.
4.
6
48.
50.
52.
54.
56.
58.
60.
62.
6.
4
66.
EFFECTIVE
23.37
22.35
21.42
20.56
19.77
19.04
18.36
17.73
17.14
16.58
16.06
15.58
�CHART IV-4:
SENSITIVITY OF EFFECTIVENESS OF COVERAGE (UH-1)
(System Cost (SC) in Dollars/Stare)
sc
,k
$50
$40 •
$30--
$20 ,
$10.
CROP
DESTRUCTION
-I
70
80
90
100
percentage of Effectiveness
74
9-
�V.
A.
TACTICAL LAKD CLEARING
ASSUMPTIONS
1. The vehicle examined will be the D7E/D7F medium
crawler tractor (made by the Caterpillar Tractor Company)
equipped with the Rone K/G clearing blade and protection
kit.
2. The expected life of the tractor under combat
conditions is two years.
| Major BennettJ The expected life
of the blade and protection kit is one year.
I 62d Engineer
BattalionJ
3. A land clearing company has 25 of its 30 medium
tractors operational at any one time.
I Planning factor from
DA Pam 526-6 197oJ
4. Security forces consist of one armored cavalry
troop or a comparable-size mechanized infantry unit.
[Major Bennett! The operation is controlled by the
commander who is airborne in a light observation helicopter
(LOH).
5. Crops are considered under the category of light
vegetation.
6. The discount rate is ten per cent.
B.
PARAMETERS
1. Utilization
The operating time for
^ Rome-equipped tractor
will be eight hours per day. .. >rmally, these vehicles work
75
�in tine field for 45 days prior to returning to their base
areas for a 15-day "stand down" and maintenance period.
[&2d Engineer Battalion Letter, February 1971j This implies
a 75 per cent work factor and 270 work days per year.
2.
Cost Bounds
a. Investment Cost
The investment cost for a tractor is bounded by
the consideration of inherited assets.
When the Rome
clearing blade was introduced in RVN, the tractors "in
country" were equipped with bulldozer blades. These blades
were simply converted by unit maintenance personnel. In
other situations, the kits and tractors were sent to RVN to
form land clearing units.
Thus, the upper bound considers
procurement of the initial tractor while the lower bound
considers the initial tractor to be a sunk cost.
b. Operating Cost
The operating costs are bounded by the security,
control, and readiness postures of the clearing unit.
The
desired security for a land clearing company is an armored
cavalry troop while a mechanized infantry company (-} is a
less desired but acceptable replacement. 1 DA Pam 525-6
1970J The security costs will be considered to range from
$130 per day to $80 per day for a UE.
(Appendix B) The
control costs are directly proportional to the use of the
LOU that is attached to the land clearing company during
clearing operations.
The attachment can be from several
76
�hours to all day. f62d Engineer Battalion 11 April
197 1]
The unit readiness rating determines the
equipment and personnel manning levels.
High ratings
dictate the assignment of two operators per tractor. However, during periods of budgetary austerity or when the
manpower pool cannot support this requireoent. this is
lowered to the assignment of one operator per tractor.
FuSACDC TOE 5-58T 1969^j
C.
COST ANALYSIS
1.
Isolation of Relevant Costs (Appendix Bj
a.
Investment Cost
(1) Investment cost for D7 Tractor.
This
investment cost is bounded by the requireraent to procure
the initial tractor.
Additionally, the expected life of
the D7 dictates replacement across the ten year planning
horizon.
Since replacement is necessary, the planner roust
consider the present value cf the dollars spent in order
for an equitable comparison to be made with the other
alternatives.
01
2
The replacement schedule will be:
345
67
8
9 10
The present value coefficients will be:
8
8
PV1 =
- _ = 3.5404 and PV2 =
£o (1 + r) 1
^
for i an even integer and r = .10.
77
--—j = 2.5404
( I f r) 1
I Hiishleif er
1970J
�D7 procurement cost:
$32,916
[DA Supply Bulletin (SB)
700-200 197l]
$ 2,400 [DA DCS, Logistics (LOG)
$35,316 1971]
(Appendix B)
Itotal -
Upper bound on the investment cost:
3.54 x $35,316=$125,019
Lower bound on the investment cost:
2.54 x $35,316=$ 89,703
(2) Investment cost for the Rome K/G blade and
kit.
The blade and kit have an expected life of one year in
cosbat which means purchase from time zero to the end of
year nine.
9
l
Z
4 n
i=0
i » 0,1,2,
_. _ 6.759 where
r = .10 and
(1+r)
,8,9.
Procurement cost:
$ 7,623
Transportation to RVN: $ 900
Total =
$ 8,523
[DA SB 700-200
fpA DCSLOG 197ij
(Appendix B)
Investment cost: 6.759 x $8,523 = $57,607.
(3) Investment cost due to combat attrition.
The Rome-equipped tractors of the 62d Engineer Battalion
(Land Clearing) have experienced a 25 per cent attrition
rate when engaged in tactical clearing.
[Major Bennett]
This would mean the replacement of the tractors and kits on
a yearly basis. The present value "ill be:
9
PV4 = )
r
= 5.759 where
~ (i+r)i
i - 1,2,...,8,9.
r « .10
and
The investment cost for a UE is:
5.759 x .25 x ($35,316 + $8,523) = $63,117.
78
�(4) The total investment a-jrtorized over the
planning horizon is §24,574 per year (U) and 521,043 per
year ( )
L.
b. Operating Cost
(1) Hourly costs. Unless otherwise noted, the
costs listed here come from the caterpillar Performance
Handbook.
Fuel:
(Light Vegetation) 5.5 gal/hr x $.15/gal * $.83/hr
(Medium Vegetation)
7.0 gal/hr x $.15/gal = $1.05Ar
(Heavy Vegetation) 9.0 gal/lir x $.15/gal = $1.35/hr
Lubricants and filters; $.33/hr.
Tractor repairs:
Using the Caterpillar repair factor, th«
repair cost would be $4.60 per hour. However, a review of
the data furnished by Major Bennett indicates that $7.00
per hour is a more realistic figure.
Rome blade and kit repairs:
$1.8Q/hr. 1 Major Bennett)
Total hourly costs:
Heavy vegetation
Medium Vegetation
Light Vegetation
$10.48
$10.18
$9.96
(2) Daily corts.
Operators' salaries:
Security cost:
Control cost:
$55 (U)
$130
$6 (U)
$27 (L)
(U)
$80 (L)
$4 (L)
(Appendix B)
2. Daily Costs
1C = Yearly cost/365 days and OC = 8 hours/day x
Hourly cost + Summation of Daily Costs.
�Tab le V-lj Daily Costs
(Dollars per Day)
VEGETATION
LOWER BOUND
1C
OC
UPPER BQUJJD
SC
1C
OC
SC
Light
$58
$191 $249
$67
$271 $338
Medium
$58
$193
$251
$67
$273
$340
Heavy
$58
$195
$253
$67
$275
$342
3.
Yearly Costs
Investment cost:
Operating coxtt
365 days/year x investment cost/day.
270 days/year* x Operating cost/day.
*
Tractors work 270 days per year (Section B ) .
Table V-2: Yearly Costs
(Dollird per Year)
VEGETATION
LOWER BOUND
UPPER BOUND
1C
OC
SC
1C
OC
SC
Light
21,043
51.570
72.613
24,574
73,170
97.744
Median
21,043
52,110
73,153
24.574
73,710
98,284
Heavy
21.043
52,650
73.693
24,574
74,250
96.824
D.
EFFECTIVENESS CRITERIA AND COST-F-FFEfTIV'^SS MEASURES
1.
EffectivenessCriteria
a.
KOE it 1 - "Area"
This HOE considers the system's net effective-
ness during a normal day's operation.
The criteria takes
into consideration the three classifications of vegetation
and the two principal types of cuts.
80
�__, . .
_ .. ,
Hours available
Effectiveness Criterion = •- , •. —•
Clearing rate
Using the clearing rates from Table II-3, the effectiveness
criteria for a UE can be obtained.
Table V-3t Effectiveness Criteria for One Tractor
(Acres per Day)
VEGETATION
AREA CLEARING
STRIP CLEARING
Light
20
13.33
Medium
10
6.15
Heavy
6.15
3,8
b. KOE # 2 - Constrained Cost Minimization
Minimize the cost of clearing 6000 acres
Subject to:
Mission completion £ 30 days
Assets required
£ Ability of commander to supply
In order to examine the performance of the land clearing
operation under constrained cost rsiniraization, several
additional assumptions are necessary:
(1) Vegetation is either categorized as heavy or
medium.
(2) Area clearing is required.
(3) Cost per day is based on 30 tractors in the
unit although only 25 are operational.
( ) Land clearing cornpany has a high readiness
4
rating and security is provided by a cavalry troop (i.e.,
upper bound cost figures for heavy and medium area clearing
will hold). Area clearing rates for a land clearing company
8t
�with 25 of its 30 mediura tractors conducting sustained
operations are:
Heavy vegetation
Medium vegetation
100 acres/day
250 acres/day
j . Para 525-6
p
1970J
2. Cost-Effectiveness Measures
a. KOE #1
Table V-4:
Tactical Land Clearing
ollars per Acre)
VEGETATION
AREA CLEARING
STRIP CLEARING
Lower
Bound
Upper
Bound
Lower
Bcund
Upper
Bound
Light
$12
$17
$19
$25
Medium
$25
$34
$41
$55
Heavy
$41
$56
$66
$90
The raission categories must take into consideration the terrain sensitivity of this alternative. The
Biinisuxn cost for both land clearing and crop destruction
are those costs incurred during light area clearing while
tl»e -axirouro costs for land clearing are those that occur
tiurir.g heavy strip clearing (sasiRuiB costs for crop destruction come during light strip clearing).
82
�Table V-5: Cost-Effectiveness Measures forTactical Land
Clearing
(Dollars per Acre)
MISSION
MINIMUM
MAXIMUM
Land Clearing
$12
$90
Crop Destruction*
$12
$25
*fhe Rome-equipped tractor is lieited to areas where crops
grow on trafficable terrain,
This eliminates many paddy-
grown crops from this type mission.
b. MOB # 2
As pointed out previously, a medium land clearing
company can clear 100 acres per day in heavy vegetation and
250 acres per day in medium vegetation.
The time constraint
on a 6,000 acre mission would require two companies working
for 30 days in heavy vegetation and one company working for
24 days in medium vegetation.
The cost per day for a
company are:
Heavy vegetation - $10,260
Medium vegetation - $10,200.
The cost in_ doj-lar^ for this KOS is:
UPPER BOUND:
LOWER BOUND:
E.
$615,600
$244,800
PARAMETER SENSITIVITY
1.
Utilization
(Table V-6 A,B, & C)
The tables show the variability in costs (dollars
per acre) that occur in accordance with the operational
83
�hours per day of each vehicle.
The tables indicate the
importance of a high utilization factor, consistent with the
operators' and support elements' ability to perform the
required daily maintenance on the tractors.
2. Security (Table V-7A, B, & C)
fluctuation in security cost demonstrates the
effect on system cost when the commander varies his security
posture from no protection to that equivalent of a reinforced
armored cavalry troop.
84
�TABLE V-6As
MAX COST - LAND CLEARING
LYSIS - TACTICAL LAND CLEARING
IIPMENT UTILIZATION - STRIP CLEARING
Heavy- Clearing
UTILIZATION
{HOURS/DAY)
R&DCOST
5.0
0.00
28.28
5.5
0.00
6.0
INVESTMENT
COST
C & M COST
SYSTEM COST
102.14
130.42
25.71
94. a 6
120.57
0.00
23.57
88.79
112.35
6.5
0.00
21.75
83.65
105.40
7.0
0,00
20.20
79,35
99.45
7.5
0.00
18.85
75.43
9 4.20
8.0
0.00
17.67
72.09
89.77
8.5
0.00
16.63
69.15
85.78
9.0
0.00
15.71
66.53
82.24
9.5
0.00
14.88
64,18
79.07
10.0
00
.0
14.14
62.08
76.22
10.5
0.00
13.47
60. 17
73.63
11.C
0.00
12.85
58.43
71.29
11.5
0.00
12.30
56.85
69.14
12.0
0.00
11.78
55.40
67 . 18
GO
**
�TABLE V-6BJ
MAX. COST -CROP DESTRUCTION
SENSITIVITY ANALYSIS - TACTICAL LAND CLEARING
SENSITIVITY OF EQUIPMENT UTILIZATION - STRIP CLEARING
Light Clearing
LIZATION
nm
5.0
5 .5
6.0
R ft.»
COST
INVESTMENT
cor.T
9 *•
M COBT,
fYSTEty coa-tf
36.95
0.00
8.08
7.35
8
26 . 7
26 .79
0.00
6.73
25 .06
31.79
6.22
7.
0
0.00
0.00
5 .77
23 .59
22 .33
29.80
28. 10
7.5
0.00
5.39
21 .24
26.63
8.0
0.00
5.05
20 .29
25.34
8.5
0.00
4.75
19 . 4
4
24.20
9.
0
0. 0
0
4.49
18 .70
23.18
9.5
0.00
4.25
18 .03
22.28
10 .0
10 .5
0.00
0. 0
0
4.04
3.85
17 .42
16 . 8
8
21.46
20.73
11 .0
0
0. 0
3.67
16 .38
20.06
11 .5
0.00
3 .51
15 .93
19.44
12 .0
0.00
3 .37
15 ,52
18.88
6.5
0.00
34. 14
�TABLE V-6BJ
MIN. COST - CROP DESTRUCTION AND LAND CLEARING
SENSITIVITY ANALYSIS - TACTICAL LAND CLEARING
ENSITIVITY OF EQUIPMENT UTILIZATION - AREA CLEARING
Light Clearing
INVESTMENT
COST
O & M COST
SYSTEM COST
0.00
0.00
0.00
4.61
4.19
12.90
12.09
17.51
16.28
3.84
11.41
15.25
6.5
0.00
10. &*
7.0
0.00
3.55
3.29
10.35
14.39
13.64
7.5
0.00
3.07
9.93
13.00
8.0
0.00
2.88
9.55
12.44
8,5
0.00
9.0
0.00
2.71
2.56
9.23
8.94
11.94
11.50
9.5
0.00
8.67
11.10
10.0
0.00
2.43
2.31
8.44
10.75
10.5
0.00
2.20
10.42
11.0
0.00
2.10
8.23
8.03
11.5
0.00
2.01
7.86
9,86
12.0
0.00
1.92
7.70
9.62
UTILIZATION
HOURS/DAY
5.0
5.5
6.0
3
R 6, n COST
10.13
�CHART V-l: SENSITIVITY OF TRACTOR UTILIZATION
(System Cost (SC) in Dollars/Acre)
S120--
S100- -
SCO..
LAND C L E A R I N G
S60 • •
s-io..
S20.
•4CROP
/DEST.
(L)- LC AND
CD
1
5
6
1-
9
8
10
Utilization - (Hours/Bay)
88
11
T2
�TABLE V-7A:
MAX. COST - LAND CLEARING
SENSITIVITY ANALYSIS - TACTICAL LARD CLEARING
SENSITIVITY OF SECURITY COST
STRIP CLEARING
Heavy Clearing
SECURITY COSTS
(S/DAY)
SYSTEM COST
($/ACRE)
0.
55.64
10.
58.2?
20.
6.9
08
30.
63.52
40
6.4
61
50.
68.77
60.
71.39
70.
74.02
80.
76.64
90.
79.27
100.
81.89
110.
84.52
120.
87.14
130.
8.7
97
140.
92.39
150.
95.02
160.
97.64
170.
100.27
180.
102.89
190.
200.
105.52
108.14
89
�TABLE V-7B:
MAX. COST - CROP DESTRUCTION
SENSITIVITY ANALYSIS - TACTICAL LAND CLEARING
SENSITIVITY OF SECURITY COST
STRIP CLEARING
Light Clearing
SECURITY COSTS
CS/DAY)
SYSTEM COST
($/ACRE)
0.
15.59
10.
16.34
20.
17.89
30.
17.84
40.
18.59
50.
19.34
60.
20.09
70.
20.84
80.
21.59
90.
22.34
100.
23.09
110.
23.84
120.
24.59
130.
25.34
140.
26.09
150.
2.4
68
160.
27.89
170.
28.34
180.
29.09
190.
2.4
98
200.
30.59
90
�TABLE V-7C:
MIN. COST - LANE) CLEARING AMD CROP DESTRUCTION
SENSITIVITY ANALYSIS - TACTICAL LAND CLEARING
SENSITIVITY OP SECURITY COST
AREA CLEARING
Light Clearing
SYSTEM COST
($/ACREj
SECURITY COSTS
($/DAY)
0
.
84
.4
1.
0
89
.4
20.
9.44
30.
9.94
4.
0
10.44
50.
1.4
09
6.
0
11.44
70.
11.94
8.
0
12.44
90.
1.4
29
100.
13.44
110.
13.94
120.
14.44
130.
14.94
140.
15.44
-
150.
15.94
160.
16.44
170.
16.94
180.
17.44
190.
17.94
200.
1.4
84
91
�VI. AHALYSIS OF "SLASH AND BURN" CLEARING
A.
ASSUMPTIONS
1. A crew consists of 45 men with one U.S. enlisted man
as supervisor.
All crew members are considered workerr
since no allowance is made for any internal chain of command
axaong the personnel.
[ Mr. Underwood!
2. Payraant of the indigenous cutters is consistent with
those rates paid in Military Region IV in the fall of 1970.
3. This type of clearing takes place in secure areas or
where security is provided by units already engaged in major
land clearing operations.
4. The U. S. units provide transportation for the
workers to and from the clearing site.
are drawn from current inventories.
Tools for the cutters
[Mr. Underwood I
5. Crops fall into the category of light vegetation.
While the first four statements can be categorized a"
"assumptions," they all have basis in fact.
Mr. Elton
Undersood of the Array's Engineer Strategic Studies Group
verified these on a trip to RVN in May and June of 1971.
The data he returned with contained detailed information on
a U.S.-sponsored operation in An Kuyen Province on the Cau
Mau Peninsula during the period September to December 1970.
However, their inclusion as assumptions is- meant to preclude
their being taken as policy for MACV as a Ahole.
92
�B.
PARAMETERS
1. Tha utilization parameter will be in units of "hours
per day."
For this portion of the study, a utilization
factor of eight hours per day and 270 work days per year
will be used. This corresponds to the utilization rates of
Chapter V. However, both of these inputs ar3 part of the
working conditions that are agreed upon by the U.S. Civil
Affairs office prior to hiring the civilian crews.
2. Ccst Bounds
The bounds on each method of cutting and each type
of vegetation are set by the maintenance and transportation
costs. These costs can range from zero to some preset value.
The cost for maintenance of the workers* tools and equipment
will be set at five collars per crew per day. The transportation cost will be ten dollars per crew per day (based on
the utilisation of two trucks for approximately one hour per
day).
C.
COST ANALYSIS
1. Isolation of Relevant Costs
The only costs incurred by this method of clearing
are operating costs.
The only investment cost would ba the
procurement of tools, but by assumption # 4, these are sunk
costs.
a. Salaries
Each man is paid 200 piasters per day and
furnished one meal at a cost of 37 piasters per day.
�JKr. Underwood! This amounts to approximately $.86 per man
or $38.80 per crew per day based on the 197Q exchange rate
of 275 piasters to one U. S. dollar.
b. Supervision
The opportunity cost for using one U. S. enlisted
man as a supervisor is $10,000 per year or $27 per day.
I Major Howe]
c.
Transportation
In some cases, the crews could walk from their
assembly points to the clearing sites.
If this were not
feasible, two trucks would be needed for approximately an
hour each day to transport the crews. Cost:
(Irt or zero ( )
L.
$10/crew/day
(Section Bj
d. Maintenance
Cost:
$5/crew/day (U) or zero ( )
L.
(Section B)
2. Daily Costs
Daily cost = Crew salaries +• Supervision -f Transportation + Maintenance
Upper Bound: $81 per crew per day
Lower Bound: $66 per crew per day
3. Yearly Costs
Yearly cost = 270 days/year x Cost per day
Upper Bound: $21,870 per year
Lower Bound: $17,820 per year
94
�D.
EFFECTIVENESS CRITERIA AND COST-EFFECTIVENESS MEASURES
1.
Effectiveuess Criteria
a. HOE # 1 - "Area"
This MOE presents the system's net effectiveness
during a normal day's operation.
Since this alternative is
sensitive to the three classifications of vegetation and two
types of clearing (strip and area), six criteria will be
determined.
,
Hours available x Crew size
Effectiveness Criterion (EC, —€iearjLng Rate
The clearing rates are obtained from Table II-4. For light
area clearing:
„,
EC =
8 hr/dav x 45 men
. „„
.,
-£—«
= 2.88 acres/day
125
roan-hours/acre
Table VI-1:
Crew EffectivenessCriteria
(Acres per Day)
VEGETATION
AREA CLEARING
Light
2.68
3.6
Medium
1.0
1.3
.5
.5
Heavy
b.
STRIP CLEARING
MOE # 2 - Constrained Cost Minimization
Minimize the cost of clearing 6,000 acres
Subject to:
Mission completion 1 30 days
Personnel and equipment required 1 Ability
of Local
Area to
Supply
95
�Several assumptions are necessary to complete the examination
of this MQE:
(1) The vegetation is either medium or heavy.
(2) Method of clearing will be "area" type.
2. Cost-Effectiveness Measures
a. MOB f 1
Cost-Effectiveness Measure =
Cos t/crew/day
•-
For area clearing in light vegetation ( )
U:
$81/crev/day
2.88 acres/day = ?28 Per acre'
Similar calculations yield the following tablei
Table VI-2: "Slash and Burn" Clearing
liars per Acre)
AREA CLEARING
STRIP CLEARING
Lower
Bound
Upper
Bound
Lover
Bound
Upper
Bound
Light
$23
$28
$18
$23
Medium
$64
$79
$51
$63
$147
$180
$147
$180
VEGETATION
Heavy
If these costs are to be depicted by mission categories, the
vegetation classifications and the method of clearing must
be encompassed by the maximum and minimum limits. Although
this gives a large interval for the costs to be within, the
review must ren>en±>er that vegetation removal by ground
personnel and equipment is extremely sensitive to the type
of terrain which the work is being conducted in.
96
�Table VT-3: Cost-Effectiveness Measures for "Slashand
Burn" Clearing
(Dollars per Acre)
MISSION
MINIMUM
MAXIMUM
Land Clearing
$18
$180
Crop Destruction
$18
$ 28
b. MOE # 2
In order to analyze this program, one nmst first
look at the constraints.
In medium vegetation, a crew of 45
can only clear one acre per day. The size of the operation
dictates that at least 200 acres must be cleared per day in
order to meet the 30 day time constraint. This would mean
200 crews or 9,000 men would have to be hired.
It is
doubtful that the host government could supply or the U. S.
units could secure that many workers. Hence, this method of
clearing is considered infeasible for a large scale land
clearing operation.
E.
PARAMETER SENSITIVITY
Since indigenous cutters are paid by the day, it would
be important to examine the cost fluctuation over a range of
possible utilization factors.
As might be expected by
noting the units of the clearing rr-tes (man-hours per acre),
changing the utilization factor from the established eight
hours p*1'" uay results in a large cost variation.
This shows
the importance of negotiating a work agreement that insures
enough "time on the job."
It also amplifies the costs
97
�incurred if the cutters' pick-up point were far from the
clearing site, causing an excessive amount of transportation time to jecrease the crew utilization, or if the
supervisor were unable to motivate his crew.
TABLE VI-4:
VEGETATION REMOmi>
SENSITIVITY ANALYSIS....SLASH AND BUBM CLEARING
SENSITIVITY OF CREW UTILIZATION.. .ARES. BURNING
(Heavy Clearing)
UTILIZATION
(HOURS/DAY)
MAXIMUM SYSTEM COST
i^/^C&E)
5.0
$288.61
5.5
6.0
6.5
7.0
7.5
8.0
262.37
240.51
222.01
206.15
192.41
180.38
8.5
9.0
169.77
151.90
10.0
10.5
11.0
144.31
131.43
131.19
SENSITIVITY OP CREW UTILIZATION
STRIP CLEARING
(Light Clearing)
UTILIZATION
MAXIMUM S1STEM COST
29.41
26.74
24.61
22.63
21.01
5.0
5.5
6.0
6.5
7.0
7.5
19.61
8.0
18.38
8.5
9.0
9.5
10.0
10.5
11.0
17.30
16.34
15.48
14.71
14.01
13.37
98
�TABLE VI-5;
CROP DESTRUCTION
SENSITIVITY AKALYSIS... .SLASH AKD BURN CLEARING
SENSITIVITY OF CREW UTILIZATION.. .AREA CLEARING
(Light Clearing)
UTILIZATION
(HOURS/DAY)
MAXIMUM SYSTEM COST
(S/ACRE)
5.0
5.5
60
.
6.5
4.0
51
41.00
37.58
3.9
46
32.21
30.06
28.18
26.53
25.05
23.73
22.55
21.47
20.50
70
.
7.5
80
.
8.5
90
.
9.5
10.0
10.5
11.0
SENSITIVITY OP CREW UTILIZATION.. STRIP CLEARING
(Light Clearing)
UTILIZATION
MAXIMUM SYSTEM COST
29.41
26.74
24.51
22.63
21.01
19.61
18.38
17.30
16.34
15.48
14.71
14.01
13.37
5.0
5.5
60
.
6.5
7.0
7.5
8.0
8.5
90
.
9.5
10.0
10.5
11.0
99
�VII.
ANALYSIS OF FIREBOMBING
v
A.
ASSUMPTIONS
1. Firebombing is conducted with the C-raodel medium
helicopter (CH-47C - "Chinook").
2. Each sortie has an expected d^jration of one-half
hour. I LTC Ruirowj
3. A flight over a given target consists of one CH-47C.
j LTC Rudrow J
4. Salvaged slings and salvaged 55-gallon drums are
used in the drops. M-4 fue:l thickener is mixed with gasoline to form a six per cent solution of thickened fuel.
j DA TC 3-336
1965 j Twenty drums will be carried on one
mission (or more common terminology, one "drop").
[LTC RudrowJ
5. The number of missions over a target area is
dependent on the requirement to have a .90 probability of
success from one or more drops.
6. When available, security forces consist of two AH-1G
arnied helicopters.
However, unlike herbicide missions with
the UH-1, firebombing missions will not be flown unless one
AH-lG is present.
One OH-6A or OH-58A light observation
helicopter will provide the necessary control. [LTC RudrowJ
100
�B.
PARAMETERS
1.
Flying Hours
Initially, the flying hours for the CH-47 that will
be used as basis for the analysis will be the saiae as the
other aerial systems. A mission duration of one-half hour
implies that the helicopter will fly 100 sorties per month
in order to reach the specified 600 flying hours per year.
However, like the UH-1 helicopter, this is below the CH-47's
programmed limit of flying (720 hours per year) in an active
combat environment.
|DA FM 101-20 1970 J The effects of
this difference will be examined in a sensitivity analysis
of the sortie generation rate in Section E.
2. CostBounds
The bounds on the mission costs are obtained by the
variation cf the security and control posture that often
results during normal employment. Control of a drop is
accomplished by a representative of the ground commander in
an LOH. However, if the Chinook pilots are familiar with
the mission and the AO, the presence of the LOH is unnecessary. Under normal operating conditions, security is
provided by two AH-lG helicopters.
The lower cost bound
is reached when only one armed helicopter is used.
The use
of one "Cobra," even under die most austere conditions, is
due to the vulnerability and lack of maneuverability of the
CH-47.
101
�C. COST ANALYSIS
1. Isolation of Relevant Costs
The only costs incurred by this method of vegetation
removal are those that are categorized as operating costs.
The procurement of the CH-47 is treated as a sunk cost since
the helicopter is diverted from normal lift missions to
conduct firebombing operations.
a. 0 & M cost is rated at 15 per cent of the
procurement cost of the helicopter, j Mr. Donaldson! The
w»
*i
procurement cost for the CH-47C is $1,536,424.
700-200 197l]
O & M cost:
b. Crew salaries:
[DA SB
$230,000 per ycir.
Crew consists of two officers
and one enlisted roan. [DA FM 101-20 1970] Total cost:
$38,000 per year.
(Major Howe]
c. Security forces:
$200 per mission (U}-2 AH-lG's.
$100 per mission (L)-1 AH-lG.
(Appendix A)
d. Control:
$ 25 per mission (U)
0
(Appendix C)
e. Thickened fuel:
(L)
$163 per mission. (Appendix C)
2. Mission Cost
SC = (O & M cost + Salaries)
Number of Missions/Year
+ Security cosfc +
Control cost + Agent cost
Cost per Mission
LOWER BOUND
UPPER BOUND
$ 486
$ 611
102
�3. Yearly Costs
The yearly cost is extremely sensitive to the input
parameters.
This, coupled with the fact that the CH-47
would never be solely employed for fireborabing missions,
diminishes its importance.
Cost per Year
I^JWER BOUND
UPPER BOUND
$583,200
D.
$733.200
EFFECTIVENESS CRITERIA AND COST-EFFECTIVENESS MEASURES
1.
Effectiveness Criteria
a. MOE t 1 - "Area"
The effectiveness of any one mission is contingent upon many variables. The condition of the vegetation,
weather, scattering effect of the incendiary fuel, and the
probability of detonation of the drura cluster require that
the evaluation of effectiveness be accomplished with a
probabalistic model. An appropriate model would be a two
or three dimensional fragmenting projectile model.
However,
this would require the determination of a lethality function
and directional variances of the bursting radii of the
cluster just to obtain a conditional single drop probability
of burn (pB). Since this data was not available, a
model was used. The probability statement is:
Prob
Fire burns 50 acres in one
or raore drops (missions)
when n drops are made
103
= Prob(pB,n) = . 0
9.
�This uses the data from assumption # 5 and has the implicit
assumption that 50 acres will be burned per B drops
(missions).
Prob(pB,n) = 1 - (1 - pB)n
where pB
is the probability that 50 acres are burned on
any particular drop.
Inherent in this model are the assumptions that:
(1) pB
is the same for all drops.
(2) There is statistical independence between drops
(or no information is gained from one mission to the other).
An evaluation of n
for Prob(pR,n) £ . 0 yields:
9
PB
n
.2
10
.3
7
.918
.4
5
.922
.5
4
.3
98
.6
3
.936
.7
2
.1
9
.8
2
.6
9
.9
1
.
9
Prob(pB,n)
. fapp)
9
For this portion of the analysis, PQ = .4, which will
necessitate five drops or missions to insure a .9 probability of burning 50 acres on at least one of the five drops.
b. KOE # 2 - Constrained Cost Minimization
Minimiza the cost of burning 6,000 acres
104
�Subject to:
Mission completion £ 30 days
Assets required £ Local command supply capability
Two CH-47 helicopters would be required to fly ten sorties
per day for 30 days in order to be 90 per cent sure that
this method would burn off 6,000 acres. Like aerial delivery of herbicides in the UH-1 constrained cass, this
represents a significant drain on the area's aviation asset*:,
Few commanders could afforci such a program due to the
important role the "Chinook" plays in combat support and
combat service support operations in an insurgency conflict.
For this reason, it is felt that the second constraint is
violated, and thus, the alternative is infeasible. The area
would have to be reduced significantly for firebombing to be
a viable alternative.
2. Cost-Effectiveness Measures
N x Mission Cost
System Cost = ;
where N = the
50 acres/mission
nuraber of missions (drops).
No differentiation is made between crop destruction and
foliage removal for this alternative.
The reviewer should
not overlook the problems encountered in RVK when attempts
tfere made to burn large caches of dry rice.
Therefore, live
rice and other paddy-type crops would be virtually impervious to destruction by firebombing.
105
�Tafcle
tfll-1:
Cost-Sffecti mess Measures for FireboiBbing
(DolJ ;:s per Acre)
MINIMUM
$49
E.
MAXIMUM
$61
PARAMETER SENSITIVITY
1.
Sensitivity ofSortie GenerationRate (Table VII-2J
Table VII-2 indicates that the number of missions
flown per month has relatively little effect on the cost of
burning an acre.
iMs is due to the fact that only $223 per
mission are subject to fluctuations caused by a variable
sortie rate.
(Mission cost vectorj ($611, $456).) The
remainder of the costs are caused by security, control, and
fuel costs and these are based OE a flat rate per sission.
2.
Sensitivity of Probability of Burn on any Single
Drop (pB)
(Table VII-3)
T*»is testing shows the effect of varying the single
drop probability of burn over a reasonable range of values,
In actual operations, pB would law- a tendency to be at the
lower end of this spectrum rather tfian the higher.
3.
Sensitivity of Security
tests
(Table VII-4)
These parameter values raage from zero to the cost
that would be ir-urred if three escort heliccpters accompanied the mission.
106
�TABLE VII-2
SENSITIVITY AKM.YSIS - FIREBOMB ING WITH CH-47
SENSITIVITY OP SORTIE GENERATION R .TE ($/ACRE)
SORTIES
PER MO.
HOURS
PER YEAR
SYSTEM COST
MIN.
SYSTEM COST
MAX.
78.
470.
54.81
67.31
80;
480.
54.22
66.72
82.
490.
53.65
66.15
83.
500.
53.10
65.60
85.
510.
52.57
65.07
87.
520.
52.07
64.57
88.
530.
51.58
64.08
90.
540.
51.11
63.61
92.
550.
50.66
63.16
93.
560.
50.23
62.73
95.
570.
49.81
62.31
97.
580.
49.40
61.90
98.
590.
49.01
61.51
100.
600.
48.63
61.13
102.
610.
48.27
60.77
103.
620.
47.91
60.41
105.
630.
47.57
60.07
107.
640.
47.24
59 74
108.
650.
46.92
59.42
110.
660.
46.60
59.10
112.
670.
46.30
58.80
113.
660.
46.01
58.51
115.
690.
45.72
58.22
117.
700.
45.44
57.94
118.
710.
45.17
57.67
120.
720.
44.91
57.41
107
�TABLE VII-3
SENSITIVITY ANALYSIS - FIREBOKBING WITH CH-47
SENSITIVITY OF PROBABILITY OP BURN ON ONE DROP
(§/Acre)
# OF DROPS
10.
8.
7.
6.
5.
4.
4.
3.
3.
' 3.
2.
2.
2.
2.
1.
P.
SYSTEM COST
MIK.
0.20
0.25
0.30
0.35
0.40
0.45
0.50
0.55
0.60
0.65
0.70
0.75
0.80
0.85
0.90
97.27
77.81
68.09
58.36
48.63
38.91
38.91
29.18
29.18
29.18
19.45
19.45
19.45
19.45
9.73
SYSTEM COST
KAX.
122.27
97.81
65.59
73.36
61.13
48.91
48.91
36.68
36.68
36.68
24.45
24.45
24.45
24.45
12.23
TABLE VII-4
SENSITIVITY ANALYSIS - FIREBOMBISG WITH CH-47
SENSITIVITY OF THE SECURITY COSTS
($/Acre)
SECURITY COSTS
($/MSN)
SYSTEM COST
MIK.
SYSTEM COST
KAX.
0.
25.
50.
75.
100.
38.63
41.13
43.63
46.13
48.63
41.13
43.63
46.13
48.63
51.13
125.
51.13
53.63
150.
175.
200.
225.
250.
275.
300.
53.63
56.13
58.63
61.13
63.63
66.13
68.63
56.13
58.63
61.13
63.63
66.13
68.63
71.13
108
�VIII.
INSIGHTS AND CONCLUSICTIS
The need for defoliation and crop destruction is a
direct result of the tropical growth, clinate, and peculiarities of insurgency warfare.
It would be difficult to
imagine the necessity of these measures in a conventional
war in a barren country like the Republic of Korea or in
many areas of Western Europe. Conventional war raises the
additional security problem of antiair protection and the
costs incurred to insure local air superiority.
These and
other problems of the "linear war" have not been considered
here.
Hence, ths conclusions drawn froa this study are
applicable only to those parts of the world affected by
certain climates, vegetation, and the press4-7 needs of
con&ating an eneasy insurgent.
A.
RESULTS OF TEE ANALYSIS
1. MOE # 1
The first measure of effectiveness attempted to
focus on each system's performance capability. A complete
display of the results allows a better comparison of the
alternatives.
Table VIII-1: Cost-Effectiveness Vectors for KOE * 1
(Dollars per Acre)
IGLIAGE REMOVAL
HERBICIDES
UC-123 UH-1H
TACTICAL LAND
CLEARING
"SLASH AKD
BURN"
FIREBOMB ING
MAX.
$47
$35
$90
$180
$61
MIN.
$3S
$27
$12
$ 18
$49
109
�CROP DESTRUCTION
HERBICIDES
UC-123 UH-1H
TACTICAL LAND
CLEARING
"SLASH AND
BURiT,
FIREBOMBING
§29
MIN.
$17
$25*
§28
$61*
$10
$ 5
$12*
$18
$49*
*Not appropriate where rice is the staple of the diet.
Table V-5)
(See
Tactical land clearing and "slash and burn" clearing
show considerable variability in their maximum and minimum
cost limits. This is due to the terrain sensitive nature
of both systems. This, coupled with the different clearing
results (one improves vertical surveillance while the other
improves both vertical and horizontal surveillance), makes
comparison with aerial-supported methods difficult.
If
comparisons are made within aerial categories and within
ground categories for each mission type, dominance can be
used to eliminate some vectors, since the maximum and
minimum limits for these two groups of systems are caused
by the same factors.
FOLIAGE REMOVAL
Aerial Systems
UH-1
Ground Systems
"Rome Plow"
MAX.
$35
$90
MIN.
$27
$12
When tactical land clearing and firebocibing are
eliminated as alternatives for crop destruction, herbicide delivery by UH-1 dominates all other vectors.
110
�2. HOE # 2
This measure of effectiveness attempted to amplify which
system(s) could meet a rigorous set of hypothetical combat
conditions.
The program format was:
Minimize the cost of defoliating/clearing
6.000 acres
Subject to:
(1) Mission accomplishment in 30 days
( ) A reasonable amount of assets to
2
complete the task.
The major additional assumptions stated:
( ) Spraying (using Agent ORANGE) must be
1
accomplished within five days.
( ) The vegetation is either medius or heavy and
2
area clearing is required.
(3) Ground systems are considered to be in a
high state of readiness.
Table VIII-2: Cost Minimization vectors for Foliage Removal
( 0 0 acres) with Tice and Resource Constraints
60
(Costs in Dollars)
Herbicides
UC-123K
Tactical Land Clearing
IU)
$272,100
§615,600
(L)
$227,900
$244,800
**Infeasible alternatives are not shown.
The preceding table shows that only two alternatives
can meet a stringent set of combat conditions.
Ill
�More important than the actual dollar costs is the
relative cost difference between the tvro systems. By
looking at this change in the cost minimization vectors, it
is possible to examine the incremental costs incurred to
vgain another dimension in surveillance capability.
A
defoliation mission usually improves only vertical surveillance.
Although roost of the leaves are off the vegetation,
the trees and undergrowth remain to restrict visual and
electronic surveillance frcru the ground-
a tactical land
clearing operation removes all vegetation and thus produces
a horizontal capability ai well as the vertical.
It can
also be assumed that an area which has been subjected to
land clearing restricts enemy movement and channelizes his
movement far more th?Jt the same defoliated terrain.
B.
INSIGHTS
In order to check the information of Table ¥111-2 is
not biased by the scale of the operation, the mission size
can be restricted.
By reducing the area by 50 per cent,
another set of cost minimization vectors can be obtained.
The assumptions of KOE # 2 are maintained with the exception
of having the UC-123 flights ran^e from two to five aircraft.
Table VIII-3:
Cost Minimization Vectors forVegetation
-.emoval of 3,000 Acres
(Costs in Dollars)
HERBICIDES
UH-1
TACTICAL LAKD
UC-123
CLEARIKG
(U)
?100,700
$136,050
$307,800
(L)
$ 80,700
$112,930
$112,400
112
�(Firebombing would be feasible only if the area were less
than 1,000 acres.)
The relaxation of mission requirements indicates that
the UE-1 defoliation system is minimum cost system and for
this program dominates the other alternatives. However,
the figures do not show the faster mission accomplishment
rate of the UC-123 or the complete clearance capability of
the D7 tractor equipped with the Rome K/G clearing blads.
In order to gain isore insight into the problem of
distinguishing between the systems, a "conanen mission"
vector can be obtained for each alte .'native.
This vector
attempts to show the cost per acre for foliage removal under
conditions that are most likely to occur in a counterinsurgency situation.
It differs from the results of
Table VIII-1, which were oriented toward optimistic and
pessimistic estimates, in that it can be considered to be
the "best estimate."
The conditions making up the "coirjrson
mission" are:
1. Defoliation/foliage
removal operation (far more
cciCTon than crop destruction).
2. The vegetation is classified as medium or heavy
since thicker terrain is more valuable to the enemy for use
as sanctuaries, staging areas, hospitals, and base carcps.
3. Clearing is limited to area type since strip
clearance is restricted to vegetation removal (anti-arabush
measures) along lines of cocnunication.
113
�4. Defoliation systems use Agent ORANGE since it is
faster acting than WHITS but not as persistent.
5. Land clearing units have two operators per tractor
and the optimum security and control available.
Reference:
Table IV-6A, Table V-4, Table VI-2, and
Table VII-1.
Table VIII-4: Common Mission Vectors (Dollars/Acre)
HSRBICIDES
UH-1
UC-123
TACTICAL LAND
CLEARING
"SLASH AKD
BURN"
PIREBOKBING
()
U
$34
$45
$56
$180
$61
()
L
$27
$36
$34
$ 79
$49
Again, herbicide delivery by UH-1 helicopter dominates
"*-il other alternatives.
These results serve to confirm the
findings shown in Tables VIII-1 through VIII-3.
C.
CONCLUSIONS
The cost-effectiveness measures obtained in this study
through the evaluation of the two measures of effectiveness
indicate that a force mix of herbicide aircraft and land
clearing tractors woyldrocs'-likely provide a costeffective solution to the foliage removal/crop destruction
missions faced during counterinsurgency operations in an
RVN-type environment, especially when one takes into
account that horizontal and vertical vision is desirable.
However, this is not meant to exclude the employment of
fireboxr£>ing or "slash and burn" clearing %\?hen the other
systems are not available to do the job.
114
�The ratio of the force-mix must be determined through
further examination of the problem. The decision to use
the UH-1, UC-123, or both as herbicide delivery systems
would depend on the intensity of the conflict, the commitment of U.S. assets, and the desired flexibility of the
over-all force structure. Certainly the helicxpter provides
more flexibility since it can be used for «any other combat
support tasks, fhe UC-123 accomplishes its mission at a
much faster rate but is entirc-ly cojiiBitted to aerbicide
operations since its configuration does not lend itself to
easy modification.
Likewise, the aaount of tractors and
their desired organization (sections, companies, battalions)
would be a function of the increased costs that the decision maker might be willing to accept to gain tJie benefit
of a two dimensional '.surveillance capability.
If the results of this study are to be useful in the
allocation of funds to foliage removal/crop destruction
missions, the decision maker must develop a detailed
situation estimate and employment model. This would include
a threat analysis of enemy forces and capabilities, an estimate of friendly forces and objectives, and a contingency
analysis of possible commitment areas.
If this were
accomplished and if an RVN- type environment were encountered
in the scenario, then the results of this study nay be
applicable in determining a proper mix of systens to effectively accomplish these two combat support missions.
115
�APPENDIX A
DETAILED HERBICIDE COSTS
A.
UC-123K
1. yearly operating cost for a squadron in Pacific Air
Force (PACAF);
[captain Wallace^
Direct element
Modification/spares
Maintenance - Operating
Support Equipment
Personnel
§ .5 million
$1.7 million
$ .1 million
$2.9 million
$5.2 million
Major support commands
Base operating
Depot Maintenance
$ .7 million
$1.2 million
$1.3 million
other
$3.2 million
TOTAL = $8.4 million
This figure is for 12 aircraft.
Thus the operating cost for
one aircraft is $700,000 per year.
2.
Modification costs
a.
[Hiss LuckyJ
Installation of the Hayes AA-45 system.
Total
of 51 aircraft modified.
$1.4 million
$ .3 million
$ .2 million
$1.9 million
b.
Hardware
Installation
Initial Spares
Engine modification.
$36.1
$11,2
$ 8.1
$55.4
million
million
million
million
116
Total of I .3 aircraft.
Hardware
Initial spares
Installation
�c. Armor plating. Total of 31 aircraft.
§400,000
$100,000
$100,000
$600.000
B.
Hardware
Initial spares
Installation
UH-1H
Security costs for UH-1 herbicide missions.
flying hour costs for AH-lG: $64 per hour
1970J or $32 per mission.
Direct
[DA FM 101-20
If approximately $70 were
allowed for munitions and salaries of pilots, the cost of
one AH-lG on a security escort mission would be $100.
117
�APPENDIX B
DETAILED COSTS FOR TACTICAL LAND CLEARING
A.
Cost of lubricants and filters.
The Caterpillar
Performance Handbook (Sec. 21, p. 5) gives a quick estimate
of $.26 per based on oil at $1 per U.S. gallon, grease at
$.20 per pound, EP oil at $1.10 per U.S. gallon, and filters
at U.S. Consumer's List Prices.
Under heavy operating
conditions, these costs increase by 25 per cent.
B.
Typical repair costs over a two-year period for medium
tractor and Rome kit
Number
5
2
1
5.5
18
2.5
1.2
2
C.
in RVN:
Major Bennett]
Eguipr;.3nt
Unit Cost Total Cost
Engir/5
Transmissions
Winch
Cabs
Cutting Blades
Blades
Radiators
Track assembly
$6,129
$4,498
$4,750
$1,600
$ 278
$1,887
$1,200
$1,249
$30,645
$ 8,996
$ 4,750
$ 8,800
$ 5,004
$ 4,718
$ 1,440
$ 2,498
$66,850
Security cdsts are based on the approximate field
strengths of an armored cavalry troop and a aechanized
infantry rifle company ( )
-.
Usually, the trocp will field
approximately 130 to 140roei.while the infantry company
would have between 100 and 120 men. The cavalry troop
would have 20 or more tracked vehicles and tbe infantry
unit would have 10 to 15.
118
�D. Costs for a light observation helicopter are based on
direct flying hour costs of $30 per hour. JDA FM 101-20
1970]
E. Transportation Cost to RVN:
Shipping, Surface
General Cargo ($/Ton)
Line Haul within U.S.
Port Handling, West Coast
Ocean Shipping
" Port Handling, RVN
Other
"
D7 Tractor:
Rome kit and blade:
Equipment weights:
$40
$21
$72
$14
$3
$150 per Ton
jpCSLOG 1971]
16 tons x $150/ton = $2400
6 tons x $150/ton = $ 900
JMr. Soules I.
119
�APPENDIX C
DETAILED COSTS FOR FISIS3MBING
A,
Control costs are based on direct hour flying costs of
the LOH which are $30 per hour.
JJ3A FM 101-20
197o[|
This
coupled with the pilot's salary and Use ground commander's
representative yields a control cost cf $25 per mission.
B.
Thickened Fuel:
Pounds of M4 Thickener Headed for XJmrious Blends of
Thickened Fuel
Gallons of Gasoline
4%
«3&
8%
40
5
?%
10
50
6%
1§
13%
[DA tC 3-366
1965J
Ten pounds of M4 thickener are used with each druo (55
gallon) of gasoline.
M4 thickener costs $1.30 per 20 pound
can.
1971 ] Using a cost of $.15 per gallon
j~DA SB 700-200
of gasoline, a drum of thickened fuel «^osts $8.15.
$8.IS/drum x 20 drums/mission = 5163 per mission
120
�APPENDIX D:
DATA SOURCES
The personnel listed in this appendix contributed in the
assembly of data for the study.
The contributions and the
office/address (as of June 1971) are listed as documentation.
1. Aerial delivery of herbicides.
Mr. Carlton W. Carter: USAF Deputy Chief of Staff (DCS),
Systems and Logistics (S & L), Washington, D. C. Costs of
herbicides to include transportation and storage.
a. UC-123K
(1) Miss Joyce B. Lucky:
USAF ODCS, S & L,
Washington, D. C. UC-123 codification costs for engine
modifications, spray systera, and armor plating.
(2) captain James A. Wallace, USAF:
Office of the
Coiaptroller of the Air Force, Washington, D. C. Procurement
and operating costs for the UC-123K.
(3) Major Robert Pyatt, USAF: ODCS, Plans and
Operations {Special Operations Division), Washington, D. C.
General information about herbicide operations.
(4) Major Peter D. Hidalgo, USA: Office of the
Assistant Chief of Staff for Force Development (OACSFCR),
Washington, D. C. Verification of sortie duration and
sortie generation rates.
(5) LTC Kenneth M. Cooper, USAF: ODCS. S & L,
Washington, D. C. Operating cost for A-1E.
121
�(6)
LTC Arthur L. Monahan, USAF:
Washington. D. C.
(7)
ODCS, S & L,
Munition costs for FAC's.
Major John D. Sins, USAF:
Resources, Washington, D. C.
ODCS, Programs and
Hourly operating costs for
the OV-10 and A-1E.
b. UH-1:
(1) LTC Manuel L. Sanches and LTC Robert G. Rudrow,
USA:
OACSFOR, Washington, D. C. Aerosol system and capa-
city, attrition rates, security configurations, mission
duration, and system coverage.
(2) Mr. F. X. Donaldson:
OACSFOR, Washington, D. C.
Maintenance factors and expected life of UH-1.
( ) Mr. Drake: Operations Manager, Agricultural
3
Aviation Engineering Company, 1333 Patrick Lane, Las Vegas,
Nevada, S9109. AGAVENCO System: Cost, size, maintenance
factor, and capacity.
(4) Major Robert Howe, USA: Engineer Strategic
Studies Group, Washington, D. C. Personnel salaries costs
and transportation costs for the AGAVENCO.
2. Tactical Land Clearing.
a. Major Richard Bennett, USA: Engineer Strategic
Studies Group (ESSG), Washington, D. C. 07 tractor and Rome
kit repair costs and rates.
b.
Mr. Jim Guthrie: Supervisor of Defense services
Section, caterpillar Tractor Company, Peoria, Illinois.
General information about the Caterpillar tractor.
122
�c. Mr. J. T. Soules: Vice President of International
Department, Rome **low Company, Cedartown, Georgia. General
information about the Rome clearing blade and kit.
3. "Slash and burn" Clearing.
Mr. Elton Underwood:
ESSG, Washington. D. C. Payaent
rates for indigenous clearing crews and verification of
clearing rates.__
4. Firebopbing.
LTC Robert G. Rudrow, USA: OACSFOR, Washington, D. C.
Security, control, equipment, and duration of the missions.
123
�BIBLIOGRAPHY
Some sources listed in this bibliography are classified.
However, the information used in this study came from
unclassified sections of these documents.
1. American Ersbassy, Report on theHerbicide Policy Review
(U) , ySOlil'IDttft'PBf, Saigon, August 1968.
2. Augusta, Joseph H, and Snyder, Christopher L., Defense
Planning In A High Inflation Economy, paper presented
at 26th Military operations Research Symposium,
Monterey, California 17-18 Kovember 1970.
3.
Boffey, Philip M., "Herbicides in Vietnam: AAAS Study
Finds Widespread Devastation," Science, v. 171,
p. 43-47, 8 January 1971.
4.
Caterpillar Tractor Coir.pany, Peoria, Illinois, The
Caterpillar Performance Handbook, e«I. I, section 21,
Deceirber 1970.
5.
Cook, Robert E., Haseltine, William, and Galston, A. W.,
"What Have We Done to Vietnam?" The new Republic,
p. 18-21, 10 January 1971.
6.
"Defoliants-A Closed Case?"
15 January 1971.
7.
Department of the Air Force, Air Force Manual 172-3,
USAF Planning Factors (U), iTi'll lliliLll Hi . H Washington,
'i
D. C., 31 March 1971.
8.
Department of the Army, 18th Engineer Brigade, APO San
Francisco 96307, Demonstration and Testing in Vietnam,
July-August 1966.
•
Commonweal,
p. 363-364,
9.
, DA PAH 525-6, Lessons Learned - Land
Clearing, p. 23-79, Washington, D. C,, June 1970.
10.
, DCS Logistics, Transportation Analysis
Division, Budget Cost Factors for Cargo Movements,
p. 1-3, Washington, D. C., 15 July 1971.
124
�11.
, Fact Sheet.- Personnel Investnsant Costs,
Washington, D. C., 12 October 1971.
12.
, FM 101-20, united States Army Aviation
Planning Manual (U), CONFIDENTIAL, p. 1-10, p. 4-2 4-3, Washington, D. C., August 1970.
13.
, SB 700-200, Array Adopced/Other Selected
Items and List ofReportable Items, p. 2-355 - 2-358.
Washington, D. C., December 1970.
14.
, TC 3-16. Employment of Riot Control Agents,
Flame, Smoke, Ahtiplant Agents, and Personnel
De tec tors in Co untergue r r ilia opera t ions, p. 62 - 81,
Washington, D. C., April 1969.
15.
, TC 3-366, Flame FueIs, p. 3 - 5, p. 8 - 13.
Washington, D. C., July 1965.
16. Directorate, Tactical Evaluation, Project CHECO Southeast Asia F°p^rt July 1961 - June 1967 (u),
SECRET, Headquarters pacific Air Force, 11 October
1967.
17. Downs, E. D. and Scrivner, J. H., De fo1iat ion Opera tions
in Southeas t Asia (U), SECRET, Maxwell AFB, Alabama,
1970.
18. Fisher, Gene H., Cost Considerations in Systems Analysis.
p. 63-118, American Elsevier Publishing Co.. 1971.
19. Gonzales, Arturo F., "Defoliation - A Controversial U.S.
Mission in Vietnam," Data, v. 13, p. 12-15, October
1968.
20. Goodell, Hon. Charles E. (New York), U.S., Congress,
Senate, Congressional Record, 91st Cong., 2d sess.,
S-1574-S-1580.
21. Headquarters, 62d Engineer Battalion, APO San Francisco
96491, Letter, Subject: "Ea^ic Land Clearing
Briefing," February 1971.
22.
, Letter, Subject: "Narrative to Accompany
Slide Briefing, 11 April 1971.
23. Headquarters, 169th Engineer Battalion, APO San Francisco,
Letter, Subject; "Land Clearing Test Program
Completed, 16 August 1971.
�24. Hersh, Seymour M. , Chemical and Bio log-teal Warfare America's Hidden Arsenal, p. 144-167, Bobbs -Merrill
Company, 1968.
25. Heyroont, I. and others, A Guide for Reviewers of Studies
Containing Cost Effectiveness Analysis, Research
Analysis Corporation, July 1965.
26. Hirshleifer, J. , Investment, Interest, and Capital, p.
48-49, Prentice-Hall, 1970.
27.
House, W. B. and others. As sesstnen t o f Ecolog ical
Effects of Extensive or Repeated Use of Herbicides,
p. 1-72 and p. 108-150, Midwest Research Institute,
30 November 1967.
28.
Kastenroeier, Hon. Robert W. (Wisconsin)* U.S., Congress,
House, "Ecological Destruction in Vietnam,"
Congressional Record - Extension of Remarks, 92d Cong.,
1st sess., E-22SC - E-2293.
29. Lewallen, John, Ecology of Devastation;
p. 58-94, Penguin Books, 1971.
Indochina,
30. McCarthy, Richa7.-d p. , The ultimate Folly, p. 75-98,
Alfred A. Knopf/ 1971.
31. McConnell, Arthur F. (LTC, USAF) , "Mission: Ranch Hand,"
Air University Review, p. 89-94, v. 21, n. 2, JanuaryFebruary 19^0.
32. Nelson, Hon. Gay lord (Wisconsin), U.S., Congress, Senate,
"Environmental Warfare," congressional Record , 91st
Cong., 2d sess., S-14217-S-14230.
33. Office of Deputy Assistant Secretary of Defense (Systems
Analysis') , Southeast Asia Analysis Report - March/April
1971 (U) , SECRET, p. 35-36 and p. 41-43, Washington,
D. C., 14 May 1971.
34. Orians, Gordon H. and Pfeiffer, E. W. , "Ecological
Effects of the Wai in Vietnam," Science, v. 168,
p. 544-554, 1 May 1970.
35. _
, and _
, "Mission to Vietnam - Part
I," Scientific Research, v. 4, p. 22-30, 9 June 1969.
36. _
, and _
, "Mission to Vietnam - Part
II," Scientific Research, v. 4, p. 26-30, 23 June 1969.
126
�37. Rome plow company, cedartown, Georgia, Land Clearing
Equipment for Vietnam, p. 1-5, 22 April 1966.
38.
, Presentationto U. S. Army - Equipment for
Land Clearing in Vietnam, p. 108, 9 February 1966.
3S.
, Salesgraro; Guide for Estimating Production
with Rome K/G Clearing Blade, 1 September 1971.
40.
, Military Applications of the Rome K/G
Clearing Blade, November 1971.
41. Tschirley, Fred H., "Defoliation in Vietnam," Science,
v. 163, p. 779-786, 21 February 1969.
42. U.S. Anxsy Combat Developments Command (USACDC), Table of
Organization and Equipment 5-87T - Engineer Land
Clearing Company, Fort Belvoir, Virginia, 7 February
1969.
43. Westing, Arthur H., "Ecocide in Indochina," Natural
History, v. 80. p. 56-60, March 1971.
44. Young, Hon. Stephen K. (Ohio), U. S., Congress, Senate,
Congressional Record. 91st Cong., 2d sess., S-21486 S-21488.
127
��
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
015
Folder
The folder containing the original item.
0160
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Creator
An entity primarily responsible for making the resource
Howard, John D.
Date
A point or period of time associated with an event in the lifecycle of the resource
1972-03-01
Title
A name given to the resource
Herbicides in Support of Counterinsurgency Operations: A Cost-Effectiveness Study
Subject
The topic of the resource
Ranch Hand aircraft
herbicide application
military impact
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/477bddbf9cb17864a16972db77199468.pdf
412dfdc0085642aa18e6a9a7308c49ee
PDF Text
Text
00165
Author
Corporate Author
Report/Article Title Table: 52 Herbicide Release Missions, Vietnam, 1964-1970
Journal/Book Title
Year
00
°o
Month/Day
Color
Number of Images
D
4
Table includes information on altitude, herbicidai agent, location, and number of
troops; some entries incomplete.
Friday, January 05, 2001
Page 165 of 194
�ALTITUDE
DATE
GALLONS
AGENT
UTM
LOCATION
NUMBER OF TROOPS
Near Target 2-14a
(mission from BIEN HOA)
641013
2
660312
CR 040070
Coast SOUTH QUI NHON
3
660821
XT 535385
West of PHUOC VINH
4
661001
BQ 905900
South of QUI, NHON (Near Highway)
5
670301
700
XT 575365
West of PHUOC VINH
6
670412
1,000
BT 0870
Southeast of DA NANG
7
670423
400
B
YD 600240
YD 628258
35KM West of HUE vie of
CAMP EVANS
8
670505
400
W
YT 690440
YT 650420
9
670605
500
W
ZC 150660
10
670711
0
YT
YT
XT
XT
XT
YT
YT
0
/'
\
995136
942147
965166
985154
017192
022145
010137
BIEN HOA
\
\
670813
I
670817
1,150
B
Area of BR
35KM E. DA NANG
(over water)
12,087
�(2)
(CON'T)
NUMBER
ALTITUDE
DATE
13
671006
15
671029
AGENT
670930
14
GALLONS
16
UTM
LOCATION
UNK
500
BIG MOSE
w
17
YS 4497
LONG KHANH PROVINCE
671121
YT 995136
BIEN HOA
671204
4000
NUMBER OF TROOPS
YS 424770
Over Target (UNKN)
BT 133690
(over water)
Over Water
YS 015912
DONG NAI River 15KM East
of Siagon
YT 070570
YT 080690
On Target (UNKN)
w
YT 0724
On Target (UNKN)
0
UNK
Over Water BQ Area
18
1200
671210
19
3500
680106
20
680329
22
680411
0
680208
21
1,000
1,000
8
12,087
10KM away NAI
BE 1158
23
4500
680426
1,000
0
CUIONG CITY 20KM North
of Siagon
24
5000
680507
1,000
w
Near XUAN LOG
847
25
5000
680527
4,000
w
8KM South of XA XUAN LOG
847
26
6500
680606
YD 422323
960
Nearest Unit 31st
Engr. at PHUOC
VINH
�(3)
(CON'T)
NUMBER
ALTI1
GALLONS
AGENT
UTM
4500
LOCATION
NUMBER OF TROOPS
ACCIDENTAL DUMP
680606
27
28
DATE
YD 100240
680609
70KJ! West of HUE
29
680611
6,000
0
VR 9726
ON TARGET
30
680616
3,000
¥
YT 4977
ON TARGET
1,000
W
MISSION LOG
CQ 1,623
ON TARGET
BT 265018
Coast Midway between CHU
LAI & DA NANG
YS 140510
XUAN LOG (RUNG SAT Special
Zone)
31
7500
680619
32
6500
680623
33
2500
680630
34
7000
680812
10,000
0
680821
1,000
B
35
B
847
Near CHU YANG K'LIM
BP 220920200890
TRUNG PHAN (PHUOC AN Village)
0-in that
area
0
36
4000
680826
BP 635995
Mountain Road
37
4700
680929
XS 408800
LONG AN Province
38
7500
680929
YT 440930
BIEN HOA
12,087
39
4200
681107
YT 25380YT 080230
BIEN HOA
12,087
681107
YT 6175463
BIEN HOA
12,087
40
1,823
�(4)
(CON'T)
DATE
41
1000
681119
42
500
681121
B
43
1800
681201
44
7500
45
2000
UTM
B
46
GALLONS
AGENT
ALTITUDE
NUMBER
LOCATION
NUMBER OF TROOPS
BIEN HOA
BIEN HOA
Runway
12,087
BIEN HOA
12,087
0
DIAN
690103
0
BINH TOY Prov.
690129
W
Between PHU CUONG and
BIEN HOA
690202
1800
6000
YT 2507
Over Mountains
YT 013188030219
NY QUOI Village (BIEN HOA)
21
ON TARGET
YC 9040
7,865
47
3500
690325
48
7000
690411
49
2000
690412
50
4500
690422
BT 4823
Near TAM KY on Coast
51
690710
ZV 1811
ON TARGET
52
700410
BS 3662
Southwest of CHU LAI
1000
0
B
12,087
�
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
016
Folder
The folder containing the original item.
0165
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Table: 52 Herbicide Release Missions, Vietnam, 1964-1970
Subject
The topic of the resource
HERBS database
herbicide application
Ranch Hand
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/2700448d4c27fac85d82aaafc94508c9.pdf
99f0f4db39c2196f5e1875b47be6f336
PDF Text
Text
00174
Auther
International Business Machines Corporation, 1601 N.
Kent Street, Arlington, Virginia 22209
ReDOPt/ArtlCle Title Application File Description: Herbicide File (HERBIE - MACV) (HERB01
OASD/REPRO)
Yuan
1971
March 1
Mr
17
Description of a database of herbicide application mission data.
Friday, January 05, 2001
Page 174 of 194
�. p]' cation File Description
V
Herbicide File (HERBIE - MACV)
{HERB01 - OASD/REPRO)
File Dote:
1 March 1971
Project Officer:
John C. Patterson
8312, OX7-2356
File Programmers:
A.B. Harmon
F.J. Sears
IBM Support Group
0X5-0491
This Application File Description has been prepared by the
International Business Machines Corporation, 1601 M. Kent
Street, Arlington, Virginia
22209, for
the
National
Military Command System Support Center under DCA Contract
Number DCA 1QQ-70-C-Q014.
�CHAPTER 1
FILE DESCRIPTION
Purpose
The purpose of the HERBIE file is to provide users with a
means of retrieving herbicide mission history data. The
data in the file is classified CONFIDENTIAL.
Information Types
Data in the file is presented in a single fixed record for
each unique flight mission. Information on flight number,
mission route, type and quantity of herbicide sprayed, abort
reasons appeared in the original file {HERBIE).
When the
file was revised by OASD (REPRQ) data on'track length, flow
rates, concentration rate and acres sprayed were added.
Input Source
The HERBIE file, was developed for use by the Military
Assistance Command, Chemical Operations Division, Vietnam,
Data for this file was extracted -from monthly worksheets
prepared
by Chemical Operations Division, MACV, using
information received from their .primary data sources.
File Revision History
The HERBIE file has been converted to a new and expanded
file, HERB01. The data in the new file includes all of the
data in HERBIE with the addition of several new data fields,
This new data, designed to enhance analysis of herbicide
missions, was developed by specially prepared programs using
HERBIE data as input. The new data fields are identified in
Chapters 2 and 3 by marking with an asterisk.
User Organization
The
Regional Programs Division of the Office of the
Secretary of Defense (OASD/REPRQ) is the primary user of the
information in this file.
Data Record Arrimgen'ent:
Data contained in each record of the ^EKBQl file is arranged
•as follows:
Control Set - Uniquely identifies a record
�1.
2.
Date of flight mission
Combat Tactical Zone over which a mission
was flown
3.
Mission Project Number
4. ' Multiple run of mission indicator
5.
Multiple province, mission coverage indicator.
Fixed Set
1.
2.
3.
4.
5.
6.
7.
8.
Province Data
Aircraft scheduled and delivery data
Herbicide type and gallons sprayed
Aircraft abort data
Run type
Acres sprayed
Concentration and flow rates
Total track length of mission,
Periodic Set 1 - Mission Track Data
1.
2.
Coordinate data - UTM and Lat/Leng
Length of legs of track of mission
File Growth Rate
The file is not expected to grow except through corrections
to present data records. It includes data from July 1965 to
December 1970.
File Size
The file contains approximately
5100 fixed records and
13,500 periodic records. The record size ranges from 104 to
1216 bytes and the file occupies 20 cylinders of 2314 disk
of space. A magnetic tape copy of this file is maintained.
�CHAPTER 2
FILE FORMAT TABLE
File Name - HERB01
FLD/GRP
NAME
STATEMENT
OPERATOR
FIELD
SIZE
YY
MM
DD
DATE
FIELD
FIELD
FIELD
GROUP
002
002
002
FIELDS - YY
CTZ
NUMBR
XRUN
MISSION
FIELD
FIELD
FIELD
GROUP
ALPHA
ALPHA
ALPHA
ALPHA
MM
FIELD
GROUP
CTL
CTL
CTL
CTL
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
GROUP
MULTI
FIELD
FIELD
GROUP
FIELD
PROJ
001
006
002
002
002
002
ALPHA
NUMER
ALPHA
NUMER
NUMER
NUMER
ALPHA
AIRA
002 .
005
FIELDS - AGENT
HIT
MISSION
ALPHA
FIELDS - AIRF
AGENT
GAL
AGGAL
ALPHA
ALPHA
GROUP
FIELDS - DATE
FLAG
SEQNQ
PROV
AIRF
AIRA
AIRP
AIR
ALPHA
ALPHA
ALPHA
ALPHA
XRUN
001
FIELDS - CTZ
RECID
DD
001
008
001
FIELDS - NUMBR
MULTI
PRQJ
MODE
902
AIRP
ALPHA
NUMER
ALPHA
GAL
NUMER
�FLD/GRP
NAME
STATEMENT
OPERATOR
FIELD
SIZE
MABRT
WABRT
BABRT
ABORT
FAIL
FIELD
FIELD
FIELD
FIELD
GROUP
001
001
001
001
NUMER
NUMER
NUMER
NUMER
ALPHA
FIELDS - MABRT
TYPE
HECTARE
SQKILO
ACRES
AREAS
FIELD
FIELD
FIELD
FIELD
GROUP
WABRT
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
FIELD
ENDFS
ABORT
ALPHA
NUMER
NUMER
NUMER
ALPHA
SQKILO
GROUP
ACRES
ALPHA
FIELDS - PRQV
FAIL
AREA
CONT
FLOW
TRACK
0TMID
UTM
LATLONG
CORDS
KMLEG
MILEG
BABRT
001
. 008
008
008
. FIELDS - HECTARE
FIXED
MODE
008
008
008
008
002
008
015
015
004
004
AIR AGGAL HIT
TYPE AREAS
CTL
NUMER
NUMER
NUMER
NUKER
ALPHA
ALPHA
ALPHA
COORD
NUMER
NUMER
�CHAPTER 3
FILE DETAIL
Field/Group names preceded by an asterisk (*} are new
field/groups in HERB01. All other fields/groups appear in
both the KERBIE and HERB01 versions of the Herbicide file.
Control Set
!
£
FIELD/
GROUP
LENGTH
CODE
DATA VALUES
*YY
FIELD
2
65-70
ALPHA
This field contains the year of the mission, i.e.,
70 for 1970.
*MM
FIELD
2
1-12
ALPHA
This field contains the month of the missions, i.e.,
04 for April.
*DD
FIELD
2
1-31
ALPHA
This field contains the day of the mission.
DATE
F in
HERBIE
G in
HERB01
6
ALPHA
This data element contains the date of the mission.
*CTZ
FIELD
1
1-4
ALPHA
This field identifies the Combat Tactical Zone over
which the mission was flown.
*NUMBR
FIELD
8
ALPHA
This field contains the mission project nuriber which
is normally six characters-left justified.
*XRUN
FIELD
1
A, B, C,
etc.
ALPHA
«
This field identifies the first, second, third, etc.
run of the mission.
�ID
FIELD/
GROUP
LENGTH
*MISSION
GROUP
9
CODE
DATA VALUES
. ALPHA
This group contains a unique mission number for a
project.
*MULTI
FIELD
1
X
ALPHA
An 'X1 in this field indicates that the mission
covered more than one province; if blank, only one
province.
PROJ
F in
HERBIE
G in
HERB01
11
ALPHA
This data element contains a unique identifier for
each mission.
RECID
GROUP
17
ALPHA
This group is composed of DATE and PROJ and provides
a unique identification for each record in the file.
Fixed Set
*FLAG
FIELD
1
Table A-l ALPHA
This field is generated after analysis of the records
or after the results of various statistical analysis have
been calculated.
*SEQNO
FIELD
6
OTMER
This field is generated by a special range program.
The sequence number is used to facilitate preparation of
plots.
PROV
FIELD
2
Table A-2 ALPHA
This field contains a code representative of the
province in which the mission was flown or, in case of
a multi-province mission, the province in which the
mission started.
AIR?
FIELD
2
H'l".''"
This field contains the number of aircraft scheduled
�FIELD/
GROUP
ID
LENGTH
CODE
•
DATA VALUES
to fly the mission.
AIRA
FIELD
2
NUMER
This field contains the number of aircraft actually
airborne for the mission.
AIRP
FIELD
2
NUMER
This field contains the number of aircraft actually
making delivery (productive) on a mission.
*AIR
GROUP
6
NUMER
This group contains the data elements AIRF, AIRA,
and AIRP.
AGENT
FIELD
2
0=Orange
B=Blue
W=Hhite
ALPHA
This field contains the type of herbicide used
on a particular mission.
GAL
FIELD
5
,
NUMER
This field contains the number of gallons of
herbicide sprayed during a mission.
*AGGAL
GROUP
7
ALPHA
This group contains the data elements AGENT and
GAL.
HIT
FIELD
2
NUMER
This field contains the number of hits taken
during a run.
MABRT
FIELD
1
NUMER
This field contains the number of aborts, either
air or ground, attributable to maintenance.
V7ABRT
FIELD
1
NUMER
This field contains the number of aborts
attributable to weather.
�FIELD/
' GROUP
ID
BABRT
FIELD
LENGTH
CODE
1
DATA VALUES
NUMER
This field contains the number of aborts
attributable to battle damage,
ABORT
FIELD
1
NUMER
This field contains the number of aborts
attributable to sources other than BABRT, WABRT,
and MABRT.
*FAIL
GROUP
4
. ...
NUMER
This group contains the data elements MABRT,
WABRT, BABRT, and ABORT.
TYPE
FIELD
1
D=Defoil- ALPHA
ate
C=Crop
•;.--'
This field contains the type of mission
flown.
, *HECTARE
FIELD
8
NUMER
This field contains a three decimal place
value equal to the reciprocal of the content of
the field CONT.
*SQKILO
FIELD
8
NUMER
8
NUMER
24
NUMER
Not used.
*ACRES
FIELD
Not used.
*AREAS
GROUP
This group contains the data elements HECTARE,
and SQKILO and ACRES when used.
*FIXED
GROUP
46
.
ALPHA
This group contains the dat*i "laments
AIR, AGGAL, HIT, FAIL, TY'.'!r, an ,1 ;.....".
*AREA
FIELD
8
•
8
�FIELD/
ROUP
G
IE
LENGTH'
CODE
DATA VALUES
This field contains the number of acres sprayed.
(Not to be confused with field ACRES which is not
used.) It is computed by multiplying TRACK by .08
by 247 by AIRP. The value contains two decimal
places of precision.
*CONT
FIELD
8
NUMER
This field contains the concentration of
herbicide in gallons per acre. It is computed
by dividing GAL by AREA. The value contains two
decimal places of precision.
*FLOW
FIELD
8
< NUMER
This field contains the flow rate in gallons
per second of herbicide dispensed from a single •
aircraft during a mission. It is computed by dividing
GAL by a figure obtained by multiplying AIRP by TRACK
by 14.95. The value contains two decimal places of
precision.
*TRACK
FIELD
8
NUMER
This field contains the total distance flown, in
kilometers, during the spray portion of a mission, and
is computed by summing the periodic field KMLEG. Each
track contains at least two points, a start and stop
point. The value is rounded and has no decimal places
of precision.
Periodic Set 1
UTMID
FIELD
2
ALPHA
This field contains the control field for the
subsets. They represent either UTM coordinate start,
turn or stop points, depending on the coordinate to
which they are attached. A' value of 10 represents the
start point of the first leg of a mission and succeeding
values (11, 12, 13, etc.) represent turn points. The
last value in the run is the end point. A 20 or 30,
etc. represents the start of a second or third leg of
a mission and succeeding values represent turn points
within that leg of the mission.
UTM
FIELD
8
ALPHA
This field contains the UTM coordinate value
�IE
FIELD/
GROUP
LENGTH
CODE
DATA VALUES
which represents the point of start, turnr or stop
of the leg of the mission.
*LATLONG
FIELD
15
ALPHA
This field contains the latitude-longitude
equivalent of the UTM value converted by a UTM
conversion program.
*CORDS
FIELD
15
"
COORD
This field contains the KIPS coordinate mode
presentation of LATLONG and is included in the file
to enable the execution of the circle search and
polygon overlap features of NIPS.
*KMLEG
FIELD
4
NUMER
This field contains the computed great circle
distance in kilometers between adjacent coordinate
points which defines a leg of a mission. KMLEGs for
a mission are summed for TRACK.
f
*MILEG
FIELD
4
NUMER
This field contains the converted value of
KMLEG in miles, computed by multiplying KMLEG by
.62.
10
�CHAPTER 4
FILE MAINTENANCE
This file is static and no update or expansion is expected.
Periodically, during analysis of the file, if an error in
the data is found and the correct value for the error can be
determined, the error is corrected. Otherwise, the record
in error is flagged, and no further action is taken.
11
�CHAPTER 5
RETRIEVAL AND OUTPUT
This file
developed.
is
new
and
Output from HERBIE is
(REPRO) analysts and are
requirement.
standard
reports
have
not
been
responsive to the needs of OASD
of " a one time report or plot
A formatted record dump has been prepared for display of*
data in each of the two HERBIE files.
Additionally,
Vietnam-wide plots of mission tracks by year and herbicide
type have been prepared. . '-
12
�APPENDIX A
CODE TABLES
13
�TABLE A-l
FLAG CODE LIST
1
Less than two UTM coordinates per track, or
total number of aircraft in AIRP = 0 or blank,
or total number of gallons in GAL = 0 or blank.
2
The concentration (CONT) is more than two
standard deviations away from the mean.
3
The inversion of concentration is less than two
standard deviations away from the mean.
4
Same as 2 except that FLOW is examined.
5
Conditions 2 and 3 exist at the same time.
6
Either conditions 2 and 4 or conditions 3 and 4
exist at the same time.
7
Conditions 2r 3, and 4 exist at the same time.
14
�TABLE A-2
PROVINCE CODE LIST
Quang Tri
Thua Thlen
Quang Nam
Quang Tin
Quang Ngai
Hue
Da Nang
II CORPS
06
07
08
09
10
11
12
13
14
15
16
17
93
94
Kontuin
Binh Dinh
Pleiku
Phu Bon
Phu Yen
Darlac
Khnah Hoa
Ninh Thuan
Tuyen Due
Quang Due
Lam Dong
Binh Thuan
Cam Ranh
Dalat
III CORPS 18
19
21
22
23
24
25
26
27
28
29
95
96
Binh Tuy
Long Khanh
Phuoc Long
Binh Long
Binh Duong
Tay Ninh
Hau Hghia
Bien Hoa
Phuoc Tuy
Long An
Gia Dinh
Vung Tau
Saigon
IV CORPS
Go Cong
Kicn "UO:VT
Kien ?/.cnr
Dinh Tuopg
Kien Hoa
30
31
32
33
34
15
�PROV
CODE
PROVINCE NAME
35
36
37
38
39
40
41
42
43
44
46
Vinh Binh
Vinh Long
An Giang
Kien Giang
Chuong Thien
Phong Dinh
Ba Xuyen
An Xuyen
Bac Lieu •
Chau Doc
Sa Dec
16
�
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
016
Folder
The folder containing the original item.
0174
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Description
An account of the resource
<strong>Corporate Author: </strong>International Business Machines Corporation, 1601 N. Kent Street, Arlington, Virginia 22209
Date
A point or period of time associated with an event in the lifecycle of the resource
March 1 1971
Title
A name given to the resource
Application File Description: Herbicide File (HERBIE - MACV) (HERB01 - OASD/REPRO)
Subject
The topic of the resource
herbicide application
Ranch Hand
HERBS database
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/d595d68acb0549b32c3243ca60639ec4.pdf
20b9b45d9ff14d8ad8a1cf26ff287ef9
PDF Text
Text
00183
Chapman, R.W.
DCA-CGTC-C312, Washington, D.C.
Herbicide Orange Proximity Program (HOPP)
Journal/Book Title
Yffif
1976
Month/Day
July 28
18
DBSCriptOIl NOttS
"This 'm B 9U!'de to using the HOPP, a computer program designed to answer the
question, 'During what time intervals was unit X in proximity to spray missions of
herbicide orange?"1
Friday, January 05, 2001
Page 183 of 194
�Herbicide Orange Proximity Program
(HOPP)
This is a guide to using the HOPP, a computer
program designed to answer the question,
"During what time intervals was unit X in
proximity to spray missions of herbicide
Orange ?"
RW Chapman
DCA-CCTC-C312
Washington, DC 20301
202-697-1731/2439
�?I*L2: I!C??
EXEC
Pi
? I L r D " F * O r » DSK HO?? Tll"rj
mm*" oc DS-: HOP? co:n:rr
FJL::D:;F 09 COM
CtS V?.£SI03 J, 3
2S
L E E C L SO BISSI23 80 HECFM P
FIL"DE? 10 D3K HOP? PATHS LBKCI, 89 01"317r SOOO REC?!t F?,
PILZDDF 12 DSK HOP? 3F.POET II-ECL '10 BIKSIZZ 800 P.SCFK F3
ICAD HCPP
ST't'T
CICSIQ ? 811-17 FH OFF 1
o PEIMTC HO?? eon":-!**
••
0 PEIIIT HOP? 7IL35
0. PHHITC HO?? E3?OHT
o ?ni:iT":» on
Herbicide Orange'Proximity Program (HOPP) needs the Job
Control Cards above for execution on the IBM 360 CMS.
* File 05 is user generated input data and run parameters.
Three examples of this file are on the following pages.
* File 06 contains comments on the run.
* File 09 is for console monitoring of the run.
* Pile 10 Contains the herbicide Orange flight path data that
comes from the HERBO-2 tape of all RVN herbicide missions.
The data has been organized into points and segments referenced
to a rectangular coordinate system. Corrections to the HERBO-2
data have been made where possible.
* File 12 is the HOPP REPORT. It lists the time periods for which
a unit (individual) was "in proximity" to agent Orange flight
paths. The parameters that can be used for defining proximity
are time and distance (both are specidied in File 05).
Distance will be from the cenfeerline of the flight path to the
unit location (enter in lOths of kilometers).
Time will be the period after a spraying for which the agent is
considered potent (enter the number of days).
In addition- to the "Proximity Periods" for the unit, File 12 also
lists the flight paths thatwere within the "proximity criteria",
i.e., the flight paths that were within the distance specified
during the time interval selecte'd for potency.
* Files 06 and 12 could .bo combined.
* Piles 05, 06 and 12 are printed out to (a) check th input,
(b) check forrun errors and (c) get the "answer", respectively.
* A detailed discusion of the files is included in the program
comment cards.
�PI
"II": 00?P
1
f* f# C
Cfto
1* ?*^ *~* T / ^ *S
I *-i-^iU!i
1
j, j1
f*f
,^*1 ,J f ;j*
H
1
ALPHA CC^PAJ: Y, 333 T J
005
01«
050
042
6C0901
660902
660906
650910
6603 11
P609 1H
660116
660917
6609 1D
660921
660927
661001
661010
661015
6f 1017
661019
661022
661023
661030
561101
661102
66 1201
66120U
6G1210
6 61215
67021 a
103
oco
333
XP976565
v r» f) -> f r rj ^
Yl?*'i'j"}7
XD9~"i?{i9
"O 970573
Xn9535 ! ??
The program will insert this location for the
2nd through the 5th of Sep 66 and switch to
YD244597 for the 6th through 9th, etc.
For periods "out of country", enter "RR9999991
for the location along with the exit date.
YD 2^42-5 37
NOTE: Dates must be in. ascendinq order.
Y2 2^12-3 7
YD175615
TD252607
YDR35132
YD 85 02*0
YDa^5132
YDtt31399
YP835132
YD 75 0230
last- 1 r»f at- inn
for
file 05 is set up for one unit,
1st line - Format(215) 1st "1" indicates one unit being processed.
2nd "1" is not needed for one unit runs, but
it must be less than "2",
2nd line - Format(16A4)Unit name {up to 64 characters)
3rd line - Format(6P5.1) Distance criteria in lOths of kilometers.
Up to 6 values may be entered.
4th line - Format(616) Time intervals in days. Up to 6 values
5th to 30th lines - Format(4X,312,2X,2A1,213) Date of arrival at a
location and location(UTM grid coordinataes).
Note: Last date is date of departure from RVN and location for this
date must* be BLANK,
�F1
HOPP
005 050
014 0 4 2
660901
660902
660906
6609 10
£60911
6 f: 09 1ft
660916
66 091?
660919
650921
660927
66 1001
661010
661015
661017
66 1019
661022
661025
661030
661101
661102
661201
661204
66 1210
661215
67021*4
100
000
- Proximity criteria
XD976565
XH^f-5^3
¥32^59"?
\D9759A9
XD5"*1";73
:OC635?.2
XD9S2695
7D9626?9
XD 97 6 56 5
Jn i,
J
J
* J-
_
vp97«j-,q4
YD 231*i*^
YD2^2607
TDV43604
Yl 2 "12637
Y7)14°r 0^1
YD 17 "6 15
y D1^86QJJ
YD 24 2 €.17
YD9?"1"'2
Y3 3532 13
Y3 3 15 1^2
Y3401.199
YD335132
YD759230
- Last location for 1st unit (must be blank)
327A CO?! IV \ N Y , 32f» K i
6C0902
660905
660910
660911
660914
6 609 16
660917
660919
660921
660927
661001
661010
66 1015
661215
<t
L
:*D 936593 - Dates and locations start right after the
YD244597
unit name.
v r j 075959
XD 97 0573
XD9 63582
XD 96 2 60 5
XD 96 2 6 00
XD 97 6 56 5
EF.999999
XD97W59'4
YD2'4 1*i9-YD242607
YD 14 1604
- Last location for 2nd unit (must be blank).
file 05 is set up for two units using the same "proximity
criteria" (time intervals and distances).
1st line - The "2" indicates 2 units being processed.
The "1" indicates the "proximity criteria" listed
the first unit will be used for ALL units
run (no limit on the number of units, but
reformat to read more than 99999 into the
gram) .
after
in this'j
must
pro-
�e f t <cir,n
fill! HO??
2
*.
J
%^*i*^
t * j 4* »^ .i. W,*
~>« i^ TV i
*»*«**
* ^ J * J
T
^ * ^ *
0
ALPHA conr •Li I f
I***/
005 050
OKI 0 4 2
660901
660902
660906
660910
6609 11
660913
660916
660917
660919
660321
660927
661001
66 10 10
661015
661017
661019
66 1022
661025
661030
661101
661102
661201
66120*
661210
661215
67021«
T1
050
"1 1 ^
1n 1
n '.jQ
J iJ
I ,?* ^ ?J
AH
^ *"m
*^
''
f D975 365
L- Proximity criteria for 1st unit
'.0^:6593
YD2^597
'^T)75"69
XDl^O*"??
'
4
X3 16 3 53 2
"Cn9i'260 c .
Y? 96 2 6 DO
" 3 37 6 5 " 5
IT9?9j r3* c
X!)974*" *i
YD 2^1 159 YP2U2607
YD 1-*3 63 4
T32U2S07
Y? 1 : J3C j^i
Y11 7 5 6 1 5
YD1U860U
YD232607
YD835132
YD350210
YD 33 5 132
Yn^0139°
i
YD 33 5 132
YD753230
- Blank location ends 1st u n i t ' s data.
3 TS CC*"' ?Ii!*Y f
005
f*!**;*l*7'M"Tn<£l1
TS i
inil^ij^j
3 3D RA.H
100 200 300 -tiOO 1 _ Proximity criteria for 2nd unit
060 090 120
j
XD 93 6 59 3
YD2UU597
XT) 97596 9
jfD970573
XD9635B2
X I) 96 26 05
Xn 96 2 600
XD976565 5^999999
XH97y59ll
YD 2U 1591
660902
660906
660910
660911
6609 U
660916
660917
660919
660921
660927
66 1001
'
'
'
66 10 10 YD 2 £12607
661015 YD1II360H
661215
|>This file 05 is set up for two units with different proximity
criteria.
'
1st line - The "2" indicates two units.
The "0" indicates proximity criteria will follow every
unit name in this r u n . The program cannot switch
modes of operation within a r u n , i.e., either
ALL units are followed by proximity criteria or
only tho 1st has proximity criteria which will
then be used for all units.
1
�:; HO;?? -
:
CHS ¥ 2 US 10 'T 3. 3 ?3
Yl
X2
' XI
1
4 34, 4 725.5 439.6
3 418,0 7 2 9 , 5 4 4 2 , 3
5 4 7 4 , 2 732,0 4 7 2. R
6 308.0 311.9 311.0
14
335,0 915,5 345.0
14 4 7 1 , 3 729,0 4 7 0 . 5
14 4 7 0 , 5 *T"> e,- , c
472. 4
/^
/
14
472. 4 726.9 4 7 1 , 2
16 319. 5 913.1
314.0
17 47S, 1 734.0 472.4
17 4 7 2 . 2 733,0 471. 3
13 322.2 919.3
31 Q. 4
13 316, 1 922.9 2 1 5 . 0
13 315.0 925.0 3 1 7. 5
20 317,0 911.0 3 2 S . O
20 325.0 913.0 317,0
20 31 "7, 0 927.0 3 1 0 . 0
21 337,0 072,0 1433, 0
21 4 0 0 . 0 883.5 3 9 4 . 0
21 394, 0 836.0 333.0
21 338.0 335.0 335.5
21 385,5 890,3 377.0
22 337,0 372.0 4 0 0 , 0
22 4 3 0 , 0 333.5 3 3 ^ . 0
836.0 333.0
2 2 39 '4. 0
22 333.0 335,9 335. 5
]•< T^Y
1976
Length
Y2
DATE UTM END POIMTS
5
6 5 Q ? 0 2 \ 3 1 "> 3 2 5 AS ^4 9140
C 503 3 4 1^925233 AH 97 33-'»5
2
650306 83299320 3S 27 5293
3
m
4
6SO"»07 Y T 0 3 0 1 1 3 Y 11 03 60
653315 YD353155 Y D 4 5 0 1 5 9
5
6 5 3815 f S 2 5 5 2 9 0 3 S 2 T 1 2 5 5
6
650815 i'S251255 3S 27 1261
7
a 650115 P3271263 E3 2 5 32 41
Q
9
653817 Y 9 1 5 1 3 1 ?D 1 'i 02 4 0
10
650318 !?3313340 ?.3 2 7 C 2 5 D
11
650213 3S270^30 :.S2!02HO
12
633319 Y D 2 2 2 1 9 3 YD 194? 33
13
653M9 YD 161 229 YD 15 02 5 3
653,319 YD 159 2 53 YD 17*" 241
14
15
530321 Y3170113 YD 2 "9 183
653321 Y D 2 5 0 1 3 3 I D 1 7 3 2 7 9
16
650821 YD 170270 YD 1002 10
17
18
6 5 0 3 2 2 YC370720 ZC 00033 5
19
650822 SC000835 YC 9 4 0 fl 6 -3 w*
650822 YC 34 036 3 YC380350
20
c
21
653322 YC330350 YC855 3-31 •H
6 5 0 3 2 2 YC855933 YC 7 7 08 2 3 fl
22
23
650823 YC870720 ZCO'00335 i4
a
24
650823 7.C000835 Y C 9 4 0 S 6 0 to
r
25
6 5 0 8 2 3 Y C 9 4 0 3 6 Q Y C S 3 0 3 O 4J
i. - J
650123 YC330853 Y C 3 5 5 9 3 3
•>*> -> G*; f. a 9 0.3
27
650323 YC855903 Y C 7 7 C 3 2 0 •H
O
6 53 3 2 '4 Y C 7 3 3 8 0 3 YC950350 ft
23 379, 0 880.0
23
23 369, 0 •^ 3 9, 0
553824 YC 60 on 90 YC710"90 u
29
o
24 3 7 1 . 0 372. 5
,13
6 5 0 8 2 5 Y C 7 1 0 7 2 5 YC 7 0077 3 4-i
'650326 YD330133 YD420160
25 333,3 913.3
31
27 5 2 1 . 2 « 9 3 . 0
BP700900 PP 75 087 7 «
650323
32
28 501,7 512.2
650329 BQ510122 30435162 N
33
29 4 9 4 . 1 516.2
34
650030 BQ435162 BQ510122
f
33 3 0 9 , 5 9 2 4 , 0
35 , 650903 Y D 0 9 5 2 4 0 YD OP 0330 I
o
36 3 1 0 . 0 932.0
650906 Y D 1 0 3 3 2 3
36
r
36 50 4. 4 6 4 5 , 0
6 5 0 9 0 6 B2570459 HP 62 5 6 -0
37
37 327.0 910.0
38
6 5 0 9 0 7 Y D 2 7 D 1 0 0 YD 3 65 02 5
650907 Bit 57 04 50 32625650
37 5 0 4 , 4 645,0
39
650908 Y €63 0360
38 368. C 836,0
40
P
41
650909 YD335000
P
19 333, 5 900.0
42
650110 YD! 8 50 00
P
. 4 0 333,5 900,0
n
41 352.0 831.5
43
650911 YC520315'
44
4 2 3 4 5. 5 333.5
650912 Y C 4 9 3 H 3 5
P
43 3 2 1, 0 9 3 0 . 0
45
650913 Y D 2 10300 YD 2 7 03 30
4 7 3 4 0 , 2 898. 1
650917 Y C 4 3 2 9 3 1
P
46
47 3 9 4 , 0 752.0
650917 Y 3 9 4 0 5 2 3
47
P
49 4 0c , 5 753.0
6
-40
650919 ZH.065593
P
940.0
51 3 1 . a
49
6 5 0 9 2 1 YD 1534 00
P
p
53 5 1 4 . 2 635,5
50
6 5 0 9 2 3 Bn6?3;l55
54 515, 1 672,0
51
650924 B K 6 8 4 7 2 0
P
6 5 0 9 2 4 . X T 4 00640
P
54 2 4 0 . 0 364,0
52
,
55 5 2 6 , 3 666.0
53
B 2 800660
6*0925
P
54
650925 XT 190 755
55 210.0 375, 5
P
56 506.7 670.0
•55
6 5 0 9 2 6 33600700
.. P
Printout info only - - •*!* - - - Data needed for
calculations ^
.e id - Extraictod froiri HER HO-?
'
NUM
1
714. 9
7C6. s
a
729.
306, u
915. 9
725. f^
726. 8
724, 3
924, o
725. 0
7 29. 0
923, 3
925. 0
924. 1
°13. 0
3 27. 3
921. 3
?83. "t
386. 0
383. 0
390. 3
3
87. 0
333. r.
336. T
° 3 5 ,1
2
? ?C *
1
3R* . 0
335. •3
12. 6
14.8
2,6
5, 3
10.0
1,7
2. 3
2.3
12. "
9.7
' 5. 1
3.2
2, '4
2,7
10.5
12, 3
Q
.2
17,4
6,5
6. 1
5,9
11.9
17.4
*\)-<m
J
6. 1
377,0
395.0
371,3
373,0
342.0
526.3
494.1
501.7
303,0
877. 0
816. 0
487. 7
516. 2
512. "*>
Q "* "1 0
509,4
336.5
509, 4
665, 9
9C2. ^1
665, 0
23. 6
12.1
20. 5
327.0
933, 0
6,7
11.9
16. a
°c?. 3
1 1,0
4,6
9.2
5. 6
3, r>
8.6
O« 1
v i
i-
A-
,
i
�f:[IE:
HOP? -
FQSTEAH
CSS Y 2 B S I C S 3,3
P1
*** n nn 3i ciO" C H A N G E
c
c
c
c
c
c
c
c
c
PM Ci!AP*IAll **
28 JTJLY 19?fi
r p. ox T MIT?
DCA-CCTC-C312,
PEGOF'AM *** 23 H A H C H 1980 **!{CPOO'}
202-697-l711'?ClO-"jC;
h ' A n H I U f i T O i ; , DC 2030 1 **
;IO? f 1")n "
T H E PAPPOSE OF T H I S P R O G R A M IS 10 F F T E F I i r i E T I « E I !,"TE P V A I, S (C A L !, E D !! C ? "> 1 1
1
• P E C X I K I T Y P E R I O D S 1 ) FOP K l i l C H A H K I T {OF I ! I D T V I D f J A I . ) "A3 I?, P - OX-:' OP 3-)'""
J1IITY TO T H E F L I G H T P A T H {CF P C I H T ) OF A i l E E B l C J OE o n A U G S K I S S I O U HOPOO"n'.-'i 1 -* -' i
HATEICES A N D FILES A R E D E S C E I F E H I S
HOP I'"'',
HCP';3'-
THE P P C f J B A E
COK30S U L O C { 2 , 2 1 6 7 ) ,*fA.*!S(1S) , J C F : I 7 f f i ) , DC?. IT (6) , F
r.i?EGEr; IDAT?.{3) ,LCC {-'*} ,u::ii5,?cEiT,jPA7E{3)
{^,6625) f I ? C 6 C 2 5 ) K O P j C V
! ? 0 TJ 3 : 3 1
HOT' 3 3 '."
E n ?-" !
r!0?33 1
f
c
c
c
c
c
D A T A I3/
V » l E / ' I i '/
DO 100 1 = 1 , 6
DCRIT{I) = 0 , 0
100 I C B I T ( I ) = 0 0 0
FILE 05 -
nopmr
USES I N P U T 0?
HOP 3 '^ 1
!'OP'"3*"
EH:! PAnr.a 2 T E F 5 A X D UXI3T 1ATA
TI Q p 1 "- 1
QUITS, PCSIT
Oil ITS = .nJMB'ii v* 0!.ITS j. C r -"_ P -5^«~ » .->S ^ t/
S
CETT ~ ~L\ 1 '''O P7""'"-'T1 3j^^7r^»«;^ * CF IT7~ !.*• * T
(=0) DC2IT 5
1C? IT XUST HE EXT"!^ 7 ) FCE r A C H 'IE IT
(=1) CF.ITEPIA FOP, Fimi O K I T W I L L SF I'STD FC 5 ALL OF ITS
" *« OT E "* i'l OD -j S C A ii .• 0 T E u M A X i L»
r
,,_
\*r
C
c
c
c
c
c
c
HAKE -
_,,„.,
,j y
!!C ? C "3
,.
|
,p^ .J,^
^
-
HOpm-F0pr02
HOPS 32
FOP y ~, "
...^P *,iio?"":"
DHIT D3STr,:!ATIO:: ( U ? TC o^i C H A F A C T - F C )
BCEIT - D I S T A N C E C H I T E E I A ( I H T E N T H S O E E I L C E E T I rs)
»,,.,,,»,,
OP TO 6 VAL'lES H A Y BE F E O C F S 5 ~ D - S 2 F E 3 V A L I J E ^ f c t - i ^ . j
c
c
c
c
c
c
c
Jj
- ' ^ - •'
"
HOPJ::
,-, , T
|
, ^ _-, ^
-t.:.-
1^^-L
-
-. -, -T •> --,
, ^ j i - j
HOP 3 3
no PO"-"
f
ICP.IX - SSAF.CH I!"i'EE\ AL ( I N D A T ? )
UP TO 6 ¥ALOE5 HAY B2 PECCESSED -
A 22 ' C V A L U E r-'tnc *r**- i r r ~ >
* j i.*
^BOXIKITY C R I T E R I A * 13 THE CCSDIIi A*TIO:^ OF A DCS IT
*.' *J
^
, » i-
i-
t-pno"'-"
HO?? 3
irf V- ~
- i— *-
s A"*J ICP.IT
"'
FOPO::
HOP00.7
nc?oo:'
Hc-?or ;"""
ESAD (05, 901) IIIIITS, PCRIT
901 F O R M A T (2 1 5)
DO 2000 OT= 1,0 SITS
R?,AD ( 0 5 , 9 0 2 ) E A H Z
90 2 FOHI1AT (1 6 A ^ )
HE IT E ( 06,<50 3) !lA:'iE
903 ?OP,:!AT{* C O H H E N T S 70R
c
c
c
HO? 00 ,
HOP 3 3:,
i;or»o? 4
HO" !-')HOP')"""HOP "33 :*
Ii'OPOv '!!0 n 03';
HCn33'i"
HO POO T
*,1cAa)
FILE 06 - C O H M E U T S S E B B O H R E S S A S ^ S
200
300
901
905
WO
906
IF ( P C R I T - 1 ) 3 0 0 , 2 0 0 , 4 0 0
PCEIT=2 EEAD{05,90'»)DCr,rr.
FOfii'i AT 1C F*">« 1)
F'lAD ( 0 5 , 9 0 5 ) ICFTT
FOEHAT (615)
B E A D ( 0 5 , 9 0 f . ) JOATr:, LCC
r O B H A ? ( t t X , 312, 2X, 211,213)
jforooa"
HOPOP"
H OP o ;)••-.
HOP03*"- ;
H0l»00 r
HGPQCF"
HOPOO'
c
-
'
,,,,,^. , ,,,-, T; , T ,^
—^,
�PILE:, ISO??
?OS?rJ»!I
c
JDATE,LOC
C
PI
cm
V S B S I 0 3 3,3
2 8 J t f L I ' 1'575
IDA??,LCC
.
tln?oov
HC">30r"
JDAT~ = DAT:: u:ni Ai?rr?E?. AI ™IPST » L 3 C f IICCATIC::)
c
HCP^-IS:
C
C
C
SIDE? ?!?L' U'lIT TC BE LOCATED AT 1112 FIEST 'I.OC 1 770", J D A T F ' J ' J T I L ^ O ? ^ ? ^ "
T:!K DAY P.^I'DRE I DAT" /-KP 7!i?r Si'ITCJ TO T!!L' NI-V f l , C C * — T H I C
HOP-1'"
?EATIIP.r, ALLOV'S ?!KIT DATr/L'JCATIO!;n TO S c S P F C I F I E ? O V ? 7 A LCJ'l "3?01',:
c
FOE 2Ac:i n:iiT, T H ~ PAY A?T"P "vrTiN", rv:i AiiD A "LA::-; frcA^ic::
C
M'JST. BE THE LAST r!tTJ:Y -
C
T* *' *T* T5 */
£*ii A Zi *
c
T^itr^ll**
jJii X . #
!T
t*
T—r^»f"tlyir%^*
A* WW* * l « , - L w - i i
703 " H C K ?
ft|-,'f»-»^
*»wW4jiJ
.
DO ^50 1=1,3
'
H50 I D A T E ( 1 ) = J P A T E { I )
ilP.ITE ( 1 2 , 9 0 7 )
907 F O E f l A T {' 11 ,79 ( ' * ' } )
.
,~ —,
L. .2,
n
^'-nr'-
"FIC')C C'JT C? C O ' f U T F Y , i:"CS! JJO?^:'"
,^,»,.u.
,_,_.,.,„,
1*111
*il ^L A JL
nr -w - T *ji
4 . ^ 4 , .It
•*,«.*., v, «, ^- .f-O^'^i*-'-
*
rb'pocp-
*
* l "-n''-07"
!-W"-:}7 '
-JO?" :--- :
::e:"'^7.
-
c
^:o??:7 -
C
TILE 12 - HO?P ES202T ( P R O G R A M OUTPUT)
908
"
.
rOEHAT |1),J
WHITE (12, 909) KAIiS
Q H Q F fw P 'i*- f*A " f *
^ W J?
4 ) it ' ' j*. I
n
'-n* ^ •srnrj'O'T' •*-/ i* *
Ttf
*,* W
*,
* - —j i VJ » > i
*
FIOX'37-'
I!C^307 r -
II r S 'l\ * fIl
J
Li|
P I,! .j. j. ^ I ij j,- * y v? "/ 1 i"i f\ i,'j j/j
n
-.
FI Lij J9 * CO I* ^>OL Cf 0 J'j. PUT
(TO KG** TC OE /* L! ?• !•-**. !!-!> P? C-i P A"!)
r-
••
:
CALL Z Y C 0 2 D { L O C » X 1 , Y 1 )
,
HOrO
.j _^ ^, ^
' XYCOPD - coirvnsTS UTH COOEDINATE LOCATION IKTO X,Y COCTDISATE^ HCPO,
I? (ilDI.LT, 1)GC TO 1200
575 IF (lIDl.Gr.21fi7) GO TC 1700
ULOC(2,S)=Y1
HO?-3
HOP'1
\
U L O C { I , K ) - r r M I T L O C A T I O N OH D A Y K
X COOED (1=1}, Y COOED {1 = 2}
ENTP.IES FOR M = !1D1,NB2 K H E P E N D 1 = "T^S"" BAY IS COO'JTPY
KD2 = LAST DAY IK C C 1 I K T H Y
500 E E A D ( 0 5 , 9 0 f ' , E T i n = s 1 1 0 3 ) i n A 7 E , L O C
CALL S ; D A T E { I D A T H f N D 2 )
I F ( L O C ( 1 ) . EQ, IB .OE. LCC (1) . K G - I R ) GO TO f > r O
CALL X Y C O U D ( L O C , X 2 , Y 2 )
'
550 I f C n 0 2 . L E . II) GO TO 1600
600 N = N * 1 .
.
-
nor- 1 ,]- 1 HOn013C
:!C?D101
:i-OP010r
fUP3103
!!0pf>1 0"
IIOP010?
HOP0107
HOPfMOr
HCP0109
HOP0110
�ril!!i-HQPP
P08TPAM
PI
? 8 J U L Y 1976
CHS V K E S I Q J I 3,3
f
650
C
C
C
C
nom i
no? 01 :
IF (H. G E. 2 167) GO TO I f i O O
IF f::C2.EQ. *J)8G TO 800
HOP31 1
'IOP01 "
THIS LOO? F I L L S I!? Til?. D A Y S B Z T W r ^ U D A I E E!1TPI£S
WHKJI THE M E X T D A T F (!:D2) IS HTi/.CfiFO, IT K I C K S CUT
no?" 1 1
i-OPOl *
!! 1 1' 0 1
*!GrC: 1 '
"'J"'"1 "
700 ULCC { 1 , ? ? } = X 1
IJLCC { 2 , " ) = Y 1
GO TO COO
H O P O i ";
C
!;CPC 1 I
800 IF (I.CC (1). HO. I?) HO TO SOO
IF (LOG (1},L*2> i") no TO 1000
uLoc{i f ::} =X2
";!CtJ0 " 2
no: 1 ?*:
ro !1 "i:
ULCC (2 f ?!) = Y2
c
C
C •
C
HC ? - 12
*? 0 P T 1 -
jvt't?^*T< vi?" LOC * " "^ C *" 3 "*" **C "' ^''py" n ^ **" ^ "\*5 " P ^ ^ j T- t *. £ H " r)
S A K E ll?/fi LOCATIO:; T H E OLD L C C A T I C M A " H THSM 3E7 A !,'K"
' : : E K ' L-CC :i?,p-i..
PO"" " "/
X1 = 7?
Y1=Y2
GO TO 500
;! 0 "" " " 2
~ 1 t? i ~ -
C
-,
j
900 X1=9999.
Y1=9999,
frtT>
i fji\
C
c
c
'
c
c
jjrsp-" "
r-.tt*"" rsT?
Uu« UT
r*f\H ?,'^~r«v *_
i- W U ,< i «">- I
»? < tiT'r i ri<- ft — »'
T " p1, « ^ ^ p »,,
i. w » ( » ^ U -
T . » T^i »t, T*?
, AT
». _
DISTA:;CH CEIT^ITA
riT*/r»?m "i 1T V
». * <-• a ,* ii .• 1
c?i\sc':AEL"" : ;}??^ :•
•iO?" ' "
' - '. "1 ' * "
„ f^ ,~,
!:0?:.-' ! : Q p -, • ^
GET EEE::TEY DATS For ?ILH oe CCHBEIIT B F F O B E PZJCIIIIIIG K A T!I
H0?n 1 ! ! 0?C- ' -'•
I I O P l I :.
CALL 3DAT2{IDATZ,!:D2)
CALL X Y C 0 2 D { L O C , X 2 , Y 2 )
CALL
ij^rtr, •» *
f:wl w -
k6^-?r.
DATZ(JEE)
K H i ^ B f O C 911) inn JTJP
911 F O O H A T C OUT 0? C O U S T E Y F P O X * , ! ? *
K= K- 1
GO TO
1
!!CP 0 1 110? 0"? '•
HOP 01"
1
T O , 17)
ncpTi "
550
HOP 2 1"
C
100^
1 V# W v
c
C
C
*T O *1 ^ * "
T: ^t> ".">";
i **t - J !
1
ISS= 10000*IDA?E {1} +1 O O ^ I D A T E {2} + T D A I " ( 3 )
E E A D { 05, 906) I , D A T E f L C C
C
J
;!3? 1* j
HOP" 1 "
IIOI'O 1 '
1
I1T w w i / * t * V i ^ = Y 1
1
M irf Of"
UQT5 -1 1 ~
ULOC ( 2 , i ; ) = Y l
ALL D A T A FOP THIS TISIT H A S ESHi; i S T E ? E D
•
'
1050 eniTE ( 1 2 , 9 1 2 ) , t ! > A T E , I D A T E
912 PORK AT { 3 X , » S T A ? . T " D A T E = f , 13 , 1H/,I2 ,1 H / , I 2 , '
112 1 !!/ 12)
y p T « w i39*"^-| 2) JHA""1" I D A T F *
BRITS{12,908)
GO TO 1900
nor" i "
HOP^I:;
HOPG 1
MOPT1"
= * , 13, 1 !!/, HOP;) 1 "
LAST DAT"
HOP01,
HO P C I .
noT»o v
HOP01-HOPOIs-.
C
1100
HOP 011,
WRITE (06, 91 3)
'! *
"*
r,
, ,,,,,,^ TT , n
1
�. F I L E ; HOP?
FGETBO
PI
CES V E E S X C ' f 3.3
28 J O L Y 1976
F O R M A T {« LAST F I L E S ItECOHD DOES JiCI C G M & I N ELA!IX LDCATIO'1 1 }
.
HOP'H
HOPHl-
c
IK?KO?ER LAS? sroY - IT W I L L ?,r. con si DEE ED T H E LAST DAY 1:1
HCPOI
C
COOS T H Y - THE L O C A T I O N 1ISIED SILL A P P E A R C S L Y Cll THAT D A Y
P-0?Ot'
GO TO
f!C?OV
HO? 3 1 '
913
C
c
c
c
c
c
c
noror
-
*
1050
1203 W
91 £» F O R M A T (9H 65/03/02,* = DATE C? j I T S T T P F A T KISSIGN, E A T L I F B tin I
1ATES K I L L :,*CT BE C O H S I D E H E D . ')
.
U H S f ! 1'AELY U H I T DATES AF.* IISTE", T H E F E C G F A 3 ICCT5 "OF -THE 7 Hi 37
i:oi:-EASLY D A T E K I I I L E E O L M I t G THE ITIH EJ! 4T E l Y P5*!CSSDII«G ' L C C 1
BHICH W i l l 3E DSHD AS TEE 0!'IT LCC CS 65/03/02, T H E E J 2 S T '1ISSICN
!.'= 1
1300 U L O C { 1 , 1 ) = X 1
3LOC ( 2 , 1 ) = Y 1
E S A D { 0 5 , S 0 6 , E S D = 1 3 0 0 ) I DATE, IOC
CALL SDA1S{IDAT^,::D2)
I? (LCC {1}."Q,I3 .OR. L O C ( 1 J , - E Q . I E ) GO TO 1 H D O
CALL X Y C O T . D ( L O C , X 2 , Y 2 )
J?(SD2.G7. 1)50 70 633
•
!:C? A 1
HO!»D1
HOP 01
X1-X2
H-Y2
GO TO 1300
"
'
WO IE (I D2.GT, 1)50 1:3 600
JF (LOC (1). EQ. 13) GO TO 1500
X1=9999.
Y1=9939,
GO TO 1300
1500
BEITE{12,903)
915 POB:i&T(2l,I2,1H/ f l2,1!!A T2, »
1BAY M
= I AST U?IIT BXT
c
C
c
-
GO TO 20 DO
.
!!-?-* 0
0
1500 K E I T E { 1 2 / ) 0 3 )
S?,ITE(12 919)
319 POBI1AT ( 3 X » ' U l I I T DATES A B E HOT IK A S C F M D I i l G C T D E ^ 1 }
GC TO' 2000
1700
FSITE{12,903)
916 r O B M A 7 ( 2 X , T 2 f 1 K / , I 2 , 1 H / f T 2 , » = F i n s ? H S T I *)«TE — MCEF. T H A U
UH A F T E R LA5T S P 2 A I HI3SIC'! — HO C A l C I I i A T IOIIS M A D E " )
•
: YEKOPO"
:
H0»02
c
HOP 02
C
C
fill 0!IE Y E A S CHT Of" CAtI BE E X T E N D E D BY I N C P F A S I K G T O E 216? J K l?iE110?02
!!0?02
M A T i l l X U L O C { 2 » 2 1 6 7 ) , A T A D D R E S S E S «'7r- A K D 650 A K O IS T I M D I S
�FILE:'HOP?
FQHTOAM
Pi
C!1S V"Bf.IO!I 3.3
?R JDLY 1976
*
c
HOP:
1750 17 (LOG ( 1 ) - H O , IB) GO TO 2000
r
H E A D (Q i, 913) L O C ( 1 )
HOPC
KQp:
• •
^ "> *"*5 1 ^
GO TO 1750
C
1800 K I ! I T E ( O f » , 9 1 7 )
917 F O R M A T {9!! 71/07/07,» = OSS YEA!* A F T F E LAS? S P 3 A Y M I S S I O N A N D 15 T
1S LAST U N I T D A T E FCH U H I C H C ALCJI. ATIO*:." fiZUS K A D Z ' )
HD2=2167 C
C
C
SEE LAS? COMMENTS
' '
1830 IF [LOC(1),FQ, IB) GO TO 1900
BEAD (05, 91 8} LCC(I)
918 FQ!u!AT(125:f A1)
GO TO 1850
f
C
1900 CALL TIMDIS (ND1,*II)2)
2000 COKTIKUE
STOP
END
SOBEOUTINS IYCOED{I!!,X,Y)
C
C
C
C
UTX COOEDIIIATES 1*1 2 V S ' A A I I I I I I 1 I - F A D AS ( 2 A 1,213)
E Z C T A K G U L A 8 COCIDI!!AT?3 FIT!! OEGIH AT » ¥ < 2 3 0 0 G D D t
IK ['4) - •
X,Y -
n » T '.
jJrtijl
11
I
^
Iff
L.
TT/ Jf
A A/ '' '1
f
I'M/
u
f
' V * f * it * f * .* * f t L *f
V
V
V
¥
1Y / t I 1
/ / JA/
A
I ^5 1
^
^
^
f p f /
U
1L I/ / f ± !V / » •±i" . • , f,*-. 1
•?
T /
'
« t
•} V /1 •• 1
/ / U */
..
»
l»-t
.»
r
1p*
i.
f
Ic 1
~t t
* r> I
-c
»
I ,
. —I
int
,
_,
<
»
•• T' t
let
...
f
ITi
• »
IT|
^
f
1 f
•• 3 1
!
tM
•
DATA NIX/-1000,0, 1 000, 20§0, 3 D33, ^00D/,!.TI Y/C, 1 CCC,2 C-OG, ?,000f U
2 0 , 6 0 0 0 , 7 0 0 3 , 8 0 0 3 , 9 COO/
c
nor'jrv
COH?EESICN TO E E C T I K G O L A S COOE3INATFS IS C O H P I I C A T E D BY TIE SPLIT I!0?"Z r ^
HA? PROJECTIONS T H A T C O ¥ 2 B E V N - IX 0 s JX () DETE?::!!,*:-:
THE POINT IS ON A K D ESTABLISH THE KOP.I70NTAI r>IGTA!!C7 TO T H E UT.1
G E I D 5QUA2E - IY {) OR JY J) CAN T H E N 3E OSFD TO GET OF Y E m C A L
DISTANCE - ?ALin ONLY FCB SOUTH VIET!,*?. II - SCI'IE D I 3 T C E T I C N IS
INT20D3CED FOE POINTS Ifl THE T I G H T P F O J R C T I C N , SEE COrHiFir PELG!!
C
C
C
C
C
C
C
DO 10 1=1,6
Hcr3? ;
n=i
c
Z F ( I K { 1 ) . S Q . I X ( I ) ) GO TO 20
10 CONTINUE
GO TO 50
'
.
.
20 X = F L O A T ( N I X ( H } +IN (3) ) / 1 0 .
DO 30 .1=1,10
•
30
C
t t O Y « F L O A T { M I Y ( I I ) +IH (*») ) / 1 0 .
HOPO:-'
HO?"):HOPO* 1 :
'
U=i
I F C I N { 2 ) .Sp. IY ( I ) ) G O TO HQ
CONTIKOH
GO TO 100
-
HOF3"*-'
HCt'O:HC?D3i
' •
-
HOPO?"
If0pa3"
HOP02'*;:
HOP02
�JLE: 'HOP?
FOr.TKAH
PI
HETURN
50 DO 60 1=1,9
- II=I
.
I F { I H { 2 ) . E Q . J Y ( I ) } GO TO 70
60 CGi'TINTJE
GO TO 100
CSS VESSIOS 3.3
.
28 JTJLY 1976
PQP027?
HOP02?. 3
'"}*")27"
F'O^lPTj
POP12B1
.
,
.
Y=FLOAT{!?Y)/13.
DO 80 1=1,3
11=1
IF (IN (1),. EQ, JX {!)) GO TO 90
80 COIITIIIHE -.
GO TO
100
"
*
G 2 I D 5 Q U A 2 E 3 B O R D E R I N G THE PROJECTION f,?LTT ME TEA P Z r . O I D A I
THE S C U A - I O S 3E10B IS A B O U G H ADJ'JS' :'" I? FCr. T H E HCr.I"C rTA I
H a G H I T U D " OF T H E V E R T I C A L DISTC"TIO:
•'A?. THE S:LIT j~, TZLA:!'/::]
FLIGHT P A T H LOCATIONS ALSO EIGOROJS SC3UTISY BUT I N T F E T
&KD NOT ABSOLUTE LOCATIONS KM, TEE SAXIMU3 EBBOR SKOHID
SCBIT USED SHOULD BE 0.5 Kii
THIS T?CH .'ICUS CCULC *JCT '/IT'iSTAND
IS TO BETEIU'lISE SPUTIYE L C C A T I O V 3
F03 » C I S T A K C i C E I T E F I A * LESS THA!' 23
EF 0 . 2 ' K S - COIIVZ3SELY, T H E KIKI.VJ3
S2TUEII
V-
100 H R I T E ( 0 9 , 9 1 S ) I N
914 P O E H A T C I N V A L I D IJ7H COORD F O R X Y C O S D CALC « , 2 A 1 , 2 i : - )
W R I T E ( 0 6 , 9 1 J t ) IN
^-, G 1 3 -.
I':^011'r^->Q??c,
Y=9999E'W
SUBROUTINE' TI8DIS{XD1,XD2)
-M^O^o"
::2^029J^D297
HOP0290
u-->nin-"
HCP03^
TT?03
,
THIS D S T E H H I N E S PH02INITY PERIODS FOD STECIFIEP. T I ^ E A " D D I S T A N C E
CEITEEIA - EFFECTIVE FLIGHT PATHS AEE I D E N T I F I E D £ LISTED
COMHO!,* ULOC{2,2167) , ! T A X E { 1 6 ) ,IC?,I?(6) , D C E I T (C) , P (K f 6 6 2 e » ) , IP (662'•]
DIHSUSIOS I D A Y { 2 1 6 7 ) f L O C ? ( 6 G 2 5 ) ,1?ATH ( 5 , 6 6 2 5 ) , N D A Y ( 2 , 3 0 0 )
'
1UTEGSE P I ) A 7 S { 6 5 2 5 ) , P L D ( 1 P 0 1 )
DATA 1ITIHE/0/, H/0/
,
HL*6
IF (iITIME,GT.O)<30 TO 200
'
NTME=1
DO 100 J = 1 , 6 C 2 5
1DO K E A O ( 1 0 , 9 1 5 ) { I P A T H { I , J ) , I = 1 , 5 ) , T ? ( J ) , ? n A T 7 ( J ) , { P < I , . 7 ) , T = 1,'») .
91 5 F O H M A T (9 X, 16 , 2 { VX f 2A«) , I X , A1 1 I C, U {1X, F6, 1) )
FILE 10 - FLIGHT PATH DATA EOF. l i E ^ B I C i n - C H A N G E SISSICHS
X?AT11(I;J) - D A T E C UTS LOCATION OF P A T H ( O U T P U T fOE",)
(HOT IISF.D "CR C A L C U i A l I C X S )
. IP(»1)
- FLAG FOR POi:!T S P R A Y HISSICNS
PDATC(J} - R2QOENTIAL D A T E OF BISHICJ!
•
'
i:'j^.-)31"
TOP011!'Qf>0.1T r
HO? 031HOP031 "
HCP0320'
IIOP012T
H'ir»f)i22
:i.:?0323:
!! OP03 2'4 :
;?opo32' : '-':
HOP032»'
HOP.1327:
HQP032 C >
HOP032 C K
HOPOIIC'
�'ItS: HOPP
:
....
PQifEAM
P(X,J)
-
P1
Cf.S
VETSTOH 3,3
2? J U L Y 137?)
XI,11,12,¥2 C e t P M ' f A f Z S OF F L I G H T P A T H
.
I!C?01!1
KOPTP 1
J;OP-r>1.1-'.
BEAD(10,916)PLD
916 F O M A T ( 1 6 I 5 )
11 r\
PLD{I) - LOCATES FIHST HISS10I! OH OH AFTES THE ITH DAY
WHITE (09,9 17)
917 . FOPHA? { PATH LOCATIONS FILED 1 }
'
200 DO 2100 ID=1,6
I? (DC? 17 (ID), 2Q.3. 0}GO TO 2200
DO 2000 IC=1,6
IF (ICR1T ( I C J . Z Q . O ) GO TO 2100
» B I T E ( 0 9 ,918)DC2IT (ID) , ICHIt (1C)
918 F O K ^ A T C 1 DCEIT = 1 » F 5 , 1 » '
ICEIT =',13}
I1IITIALJZ3
DO 300
"OPO?
;'*)n-J" i
H^r- "J.r3
'
.
•
"
1 = 1,6625 ' *
300
DO «00 1=1,2167
400 I D A Y { I ) = 0
MO 1 " 13 31
HO? 1352
«
•
•
'
KD1 - FIItST 0:iIT DATE
*
500 u=:i + i
*
"
"j '^
.
HQ=!l-ICai? | I C ) + 1
"c:-^
"
I"^7 •
IJQ - ?I5S? DAI I" TEE S E A 5 C H IJIT^r.Yr.L i'HICH "JILL COVES T H T O K I T
' D A T E A!ID THE ?EHCESDI!IG !1-1 D A Y " - v J H Z T Z I'1—ICriT V f t L H Z
r
IF (NQ.LT.1) 50 TO 1800
IP{NQ. GT. 1801) GO TO 1900
H0?,r
HOP 3
'
C?"
H'JT"-'
HOP016-:
HOP03.'?
HOP016-
1PI - THE FIHST UISSI08 O C C D R R I K G III THE SEARCH I N T E R V A L
SEAECH 1!ITERVAL STOPS OS THE OKIT DATE
HOF03t n
HCPC37C
HOP3371
flOP03?:
HOPOJ73
CALL DIST(S,IP1,D)
HOP3.175
IFCD.GT, DCSITCID}) GO TO 600
HOP 3 37*'
HOP 0^7 1
??.*:> 1?7;<
600 I?L=I?L+1
IF {I PL. 31. 6625) GO 10 700
I? (PDATE (IPL).GT,S)GO TO 700
'
-
IDAY {!-,') - COV3P.S THE P3FIOD FEO« THE FIRST XTSSICJ1 TILL C»?F TEAR
AFTEF T:IK LAST *i:isic:i - «H?:;: t TH3 P K C X I H I T Y o i i f p , i \ - is HOP :)'•''<
MET, THE A P P r O P H T A T E D A T E 1 5 / L A G G E D
L O C P { I ) - M A R K IDSS1ITY (I?L) OF M I S S I O N S EFFECT I SG THS U K I T
IDAY(N)=1
LOCP(I?L) =1
GO TO COO
MOPO^-?:
IIOPOJ-U
IIOP0312
'
-
!!OPOl n
�»1
FILE: HOPF,
CHS VKHSTOy 3,3
28 J"LY
"C
700
c
c
c
IF (Ii'.LE. !!D2)GO TO *JOO
t| ^ rj ^ -» -:
, * „ , , ? _ •J , 3
1102 - L A S T US IT D A T E
HCP-J3"
800
c
c
c
c
c
i: C?01 -'
n
IGO=0
!I?=0
H0 33'
D^irHJlTl.'E ?P.02i:*ITY P ' P I C D S , r O I O D S W I T H IDA! F L A G G E D
UP ~ T»!E NU"i?E»-. G» t'f. 4; iOD
!JL - H'JMBSR OF P R I K T K D IIKES CH H O E ? r.SFOPT
'! -n -\i/
*. \s i
DO 1000 I = N D 1 , K D 2
I F ( I D A Y {IJ.oQ. 0 ) 5 0 TO 900
IF (IGO.EQ, 1) GO TO 1000
ISTAST=I
GO TO 1000
900 IF {IGO.EQ. 0) GO TO 1000
IGO=0
CALL DATE (1START)
KD'IY (1,N?) =IS?/\ET
UDAY {2, II?} =I3TO?
C
C
c
: J D A Y { I » J ) - ?ILH O F P R O X I M I T Y P"HIC3S F C 3 P3INTO T IT
1000
.
I ? ( A D S ( ? L O A T ( U L - 5 3 ) ) . L 7 . 7 . 1 ) G O TO 1*703
C
C •
C
STJtP.T HEV PRINTOUT PAGE '-'HSU SEAR THE BOTTOH C? A ?AG
1100 NL=1IL*3
HOITE{12,919)
919 F O U M A T ( I X )
H H I T 3 { 1 2 f 9 2 0 ) DCSIT(ID) ,TC?I? {1C)
DISTANCE C H I T Z F I a = ' , F 5 . I , 1 KX
920 FOSHI-T
1VAL = » * X 3 , ' D A Y S ',10 ( * * ' ) )
TOIT3{12,9iq)
IF (II?. E O . D ) GO "0 1600
C
C
c
M L = N L + 5 t {NP/5. 1)
i R I T E C 12,922)
922 FORMA?{11Xf10{»- * ) » * ?^OXIHIfY PERIODS
KBITS { 1 2 , 9 2 3 ) { ( K D A Y (I, J) , 1= 1 1 2) , J* 1, HP)
923 FORMAT {5 ( 3 X f !«'»,»-'.16))
I
WRITE (12,924)
92Q FORMAT (1 1:<,9(«- ») , ' SPFECTIf E
11-0
FLIGHT
-'))
Sr?»?.CH i:
�PILE:.
FORTBO
PI
" CMS VEESIOM 3,3
28 J3LY 1976
12=0
C
C
HOI
HOI
HO'
02TSi!1I!,'K 8 A P K 2 D FLIGHT PATHS
'
c
r
flQ:
00 1100 I = 1 , 6 G 2 >
IF {LGC? ( ) "Q,0) GO TO 1U03
I.
IF (Xl.GT.O) GO TO 1200
HO!
«r
GO TO 1«00
C
1210 IF ( I 2 - G T . O ) HO TO 1300
12=1
GO TO mt)3
'
-
c.
C
i!-?i,
S3ITS TKES OUT I!' G H O O P S 0? KlI-^S ( S A V E S LOIS)
c
1300
HO^C-V
!!C?^'
K g I 7 E { 1 2 , 9 2 5 ) ( I P A 7 H ( J , 1 1 ) , J = 1 , 5 ) / (I P A T H (:'.,I2) ^^l,^) , (TP.'rH (I , 1 ) »L^:^r
p
h
i
*
"
i
*
- - - U
9 ^ ^»,,#C " ti rWA* T^>i iM |^~ ^r !J* A |?pl- *l-Y £^*r* ' " j »I" ^ -^>^ * ' ^ £
w
:
s
J
I — 1 f * t?*j% li j r * "1T1 / *-"^ • * \
^
.-*^
-• Y/
11=0
12=0
1^00 COIITIXyH
IF (II. EQ.O) GO TO 2000
C
j',_"_"-*
HC?':>U.
!!C~04
HCi-O^i!0
"'?;*
.
PICK UP ANY I2FT 0?EE FECH THE GSOOP O F T,!:!^? K!?ITi:'G
,
c
ML=KL+1
.
"G:"^--' '"v
HOT'I-.
HC''"-
nc
*
T w O LZFT 0¥EB
•
'
BP.ITE{12,926) ( I P A T K { J , H ) ,J=1 ,5) » {IPATH ( K , I 2 ) , K = 1 , 5 )
92G F O R M A T (2 {1 X , T 5 , 1 X , 2AU f '- • , 2A U , I X ) )
GO TO 2000
C
C
C
O N E LKF? 0¥EH
'
,
1500 H R I T E ( 1 2 , 9 2 7 ) ( I ? A ? I ! ( J , I 1 ) , J = 1 , S )
927 F O ^ S A T ( U , I 6 , 1 X , 2 A a , l - ' , 2 A U )
GO TO 2000
C
'
1600 B R I T E { 1 2 , 9 2 8 )
928
c
C
^
no-r:
HP" ' .
IF (12. ED,-3) GO TO 1 5 0 0 '
C
C
C
HCP'^i-
'
"O n -3"-*
HOPO'."
i!0?^'.'
HO?:--"
HO?') • HO^^';HO^?-;'
F O R M A T (1 I X , 5 { ' - • ) » » NO F L I G H T S K F E 1 T H I S P P O T I r i T T Y C P T T P RT A • , r '( * -:!3?C:;.'
nTs-Mr*"*
GO TO ^2000
.
TOP 0? CO;!TIM"J?,TIo:i P A G E
1700 W R I T E ( 1 2 , 9 2 9 )
9 2 9 F O B K A T { « 1' ,71 ( • * ' ) )
UHITS(12,919)
jmiTE(12,930) HAHE
930 Fona/i7{» HOIIE DATA OH «,16M)
%
'
!iC?-T- ;
nop^'i'
n
no 3u
JIH^O^^
,, ,.
liOPOV
HOPO';
HOPO-I
�uiiCLfis:;! 7 I rtl)
-FIL": !JO?P
FORTSAS
Pi
C**S V F K S I C N 3,1
2ft J U L Y 1 9 7 5
io?<vr-
WRITS (12,919)
NL=it
GO TO 1100
C
C
SEARCH I N T E R V A L E X T E N D E D I N T O N E G A T I V E T I K E , I.E., B E F O E E THE
FIHST MISSION - STAET HITH THE FIHST M I S S I O H
c
c
1800 IPL-0
GO TO 600
HOPOS:
C
c
c
01IIT D A T E (N) IK
BF.YOED R A N G E OF MISSION DATA
1900 CALL D A T Z ( S ) '
W R I T S ( 0 6 , 932) M , ICE IT (1C)
932 FORMAT (I7,' 1 M I N O S 1 , I« » f
D A Y S -IS GSEAT3R T H A N L A S T F L I G H T ' )
GO TO 800
C
2000 J ? R I T E ( 1 2 , 9 1 9 ) _
2100 CO !J TIN US
2200 EsiosN
HOP050
HOPOS 3
HOPOS 0
HO POSC
HC?Q^ *
HOPOS 1
HCPD51
;,: n r> o "-, i
J;C r> 0 5 1
HOP 05 1
' ,
HOPOS 1
HOP 05 1
;- T f;p35 1
END
S U B R O U T I N E DIST ( I I U , "?,!))
C
i OF 0^9
HOP 0*1^
HOPOy 5
!!OP050
HOP 050
HOP 050
HOP050
HOP 050
CALCULATES D I S T A N C E (D) ""02 U N I T L C C A T I C " , 11LOC {!,!:«} TC THE PA TI: i-:.-;pO"-i
:!0"*" '" r
P ( I , U ? 3 F1TH V'I=Ti:iT DAT3 A S S N P - P A T " I D r K T T I ?
. *'^PO = . 2
r
CCMHOX f J L C C { 2 f 2 16?) , i : A * 2 { 1 ' 3 ) » ICT.I" [•'•) , D C H I T (C ) > ? ( : i , c C 2 " ) , IP ( 6 5 2 ) :;:PO-"Z
:*/:':• po^r.
.DATA I3/ 1 */
C
c
c
c
:J ' P 0 ' T
c
c
H'^P ;1\ 2
!r 0? 0 ~ ~
X 1 , T 1 - UNIT LOCATION
HO? or- 2
X 1=0 LOC ( 1* - ir J)
T
'OP05~
t1=t!LGC(2,tn)
X2,Y2 -
c
c
c
:i3?o r >:
HOP05-
OSE END OF THE FLIGHT PATH
p;J^
t,'QP^)"
jinT>f) r, "^
Y2=?(2*5!?)
I12=X1-X2
f12=Y1-Y2
I F ( I P ( N ? ) . E Q . I B ) G O TO 10
c
c
c
I P C « ' P ) = 1 P t FOE POINTS (GO TO 10 IS
T-T f~\ f} *\ ^ °*
no? 05^
t j n n r j ', l
UOPO'"- 7
ii f\ Y$ r^ -> ~",
fOF. S E G K A T J T S )
TI /^ 75 r^ *", " '
D « X12*X12 + Y12*Y12
D = S2ET(D)
c
c
1J A t> A *" "*
PYTHAGORAS
c
c
c
c
c
RETUKM
X3,Y3 10
'
'
THE 07117.3 EHD OF T H 3 PATH piCtf B C 3 K I K G W I T H A U S E
SBIG^EIIT, A LEG OF A M I S S I O N )
POP05',
I! OP 05-',
HOPOS?!
HO?OS<j
HO^O'i^
i!OPO f >i"
HOP05'i
HOP05?i
�j=TL3: HOP?
FOSTRAU
Pi
CSS VH3SIO!! 3 - 3
Y3 = ? { U , N P }
3M3=X1-X3
«3=x2-o
1976
.
Y13=Y1-Y3
Y23=Y2-Y3 •
X23S-2-X23*X23 •
Y23f»Q=121*Y23
2fl J f J l Y
'
_'
-
TO THE L I K 3 C? 7K2 5L1GI11 P A T H
{ T l i F C a G I ? ~J,3 ?CI!IT3 07 I"")
i10''1]-
A = { X 3 * Y 2 3 3 Q *• : < 1 * X 2 3 3 Q + Y 1 3 * Y 2 3 * X 2 3 } / D S I I C X
I = { Y3*X23SQ * Y 1 * Y 2 3 S O * X13*X2.1*Y23 } / - D F K C . 1 .
HO-"?"-'
IIOP304'
D E T E R ^ I H E LOCATIO" 0? II*Tj!nCHPT K I T H F"SP^CT TO 1HZ 7,"~ P O I ^ I T S ,
I.E., IS T H 2 IST2P.C2P7 CK TH2 LEG 02 B ! Y C " D THE E I I D 20I!CTS
m?^'-.f
J^^Tl
X5=X3
IF ( X 4 . G £ . X 5 ) G O TO 20
H
-
X5=X2
20 IF (Xa.LT.S) GO TO 30
IF IXS.r-T. X) GOTO M
!1C?0-"
°??rC
KOP057
HO.O s7
HOP15?
Y5=Y3
IF (Y4.GS. Y 5 J G O TO 30
Y5=Y2
30 IF (YS.LT. Y ) G O TO -40
IF (1S.GT. 1 * ) G O ' T O «l3
C
C
C
c
-
IKTE3CEPT IS OK T H E LEG - DTSIAEC2 Fill 3Z T K E r2!>?"%'DICULAr DIST
F20H TIO OKI? LCCA7IOU TO THE FLIGHT P A T H
•
.
HOPXX1=X-X1
•
"3 —
"r
HOP"'
•
P n ;;
••-"HO?"'
I N T T R C F P T IS B3Y011D TI1~ Siin POi:!T1 - D I S I A ' X E V I I L P^ TI'H D T f T \!lC"l!or "!'
PEO« TK1 U'JIT L O C A T I O N TO THE SHAF.EST USD FCI'^T
YY1=Y-Y1
D = XS1**\Al * YY1*YY1
D=SQRT(D)
EHTOIJ'J
H0?
-
i|0 X13F,Q=:<13*X13
Y13S2=Y13*Y13
Ol=X13S2*Yl3f.Q
Y125Q=Y12*Y12.
D2=X12SQ+Y12SQ
" " ^
-
D=D1
IF
(D2.LT, D) D-D2
J>=SQHT (3)
HI: TOR!:
.
•.
!!0?0:
HOPO--
HOPOf
nopof
l!OP:1f
�fit": HOP?
Fortran PI
ens VHSSTON 3.3 20 JULY 1975
EffD
SUEEOOII'IE :,'DAT2{ID,IDA)
~
tO¥EHf
:!OP050*
!!OP3f>(V
'
YE/Mr/DA DA12 IHTO A SZQ-JT57IAI, DATE
DIM2HSIO!: I I > { 3 ) , I X ( 1 2 )
DATA 1:1/0, 3 1, 5 9 f 0 0 , 1 2 0 , 151, 1 8 1 ,2 1 2 , 2 U 3 , 273, 301,33«/
I^POAOH On 36 1H0?36r
!'-?06 V
IOA=355* ( I D { 1 ) -6 r >) +IS (ID (2) ) *ID ( 3 J - 2 1 3
I" (IDA-9'12) 4 0 , 2 0 , 3 0
^
'iOPIt'r
"a?06r
i
c
c
C
ACCOOilTH FOI? IT!1? 7 S A H 29
:c*'')5i'
F H S 68
23 I? ( I D C 2 } - H : 2 , 1 ) 00 TO 30
GO TO (40
.
"0?061
.
*
MOP051'
:i .")-"> 0-3 2
aO EETOEH
50 I D A = - 1
E21IIS:!
'
"OTO->,":.
"r-;?')'2-'
I*ap052
HC7062
C
C01.TEST A SE2*J72fTIAL D A T E IIITC A Y R / S 1 I / D A C A T 2
c
DII1EN510!! I:! ( 1 2 )
DATA i : V 3 3 « / 3 - ) ^ , 2 7 3 , 2 ^ 3 , 2 1 2 , 1 6 1 , 1 ' 1 , 1 2 0 , 9 0 , 5 9 , 3 1 / 0 /
ID=ID+213
IF (in-952) 33,1 0, 20
:iO?062
HO ? 0 - 5 2 '
*:irOc 3
C
C
ACCOUNTS FOR L E A ? YE31E 29
?EB
6S
C
10 13=680229
EI310R1!
20 ID-ID-1
30 I=ID/365
'
•
1=1 + 65
'
DO »IO JJ = 1,12
. J=JJ
I P { I D . 3 T . I H ( J J ) ) G O ID 50
WO COSTING
50 K=ID-I!1(J)
J-13-J
10 = 10000*1 * 103*J + K
BE73S3
EJD
•
"OPO-,,
HOPO-'HOP06HOP06-'
HOPO-V*
:H)?3r4
HOP064.
HOPOt)-;
IlOPO^n^
!
*"^ er
�
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
017
Folder
The folder containing the original item.
0183
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Creator
An entity primarily responsible for making the resource
Chapman, R.W.
Description
An account of the resource
<strong>Corporate Author: </strong>DCA-CCTC-C312, Washington, D.C.
Date
A point or period of time associated with an event in the lifecycle of the resource
July 28 1976
Title
A name given to the resource
Herbicide Orange Proximity Program (HOPP)
Subject
The topic of the resource
Ranch Hand
herbicide application
human exposure
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/fdb812cbd07a84da42eb93379b661ed7.pdf
72b624434fbabe9f784e1883036edfff
PDF Text
Text
Item ID Number:
00139
Author
CorpOPatB Author
Department o* the Ar-ny, O".ce of the Ad.utarit Genera
Alexandria, VA
ROpOrt/ArtJClO Title
' atjl°
MACV hxed
'VinS Aircra r t Herbicide Incidents. 15 October 1981
Journal/Book Title
Year
k00^
Month/Day
Color
Number of Images
14
DeSCrlpton NOtOS
Includes two payus of handwritten summary of data
Friday, janufi-y 05. ^001
Page i89 of 19-:
�OF
Office of the Adjutant General
Alexandria,
October 1981
*ACV FIXED WIN T G fl.IRCRPFT HP
g IVCIDRNTS
altitude
Incident Code
>T
"orbs Taoe
Abort List (1972)
A l t i t u d e at tirne
of
J - Jettison of Herbicide
DOT - DUTID on Target
WT - Krone: Target (Herbicide
snrayed-not Jettisoned)
CWL - Crash With Load
30Q - Soill on Ground
At'B - Abort No DUIID
Total of Aircraft
on mission
M
Tntrv is listed
on 197? list
of Aborts
r. Aircraft
ission is
vertifiod as
on Merbs Tane
.":"•..• IT 10 >! A L t'ACTS: In addition to this listing there is evidence of R Aircraft crashes durin<? thn v;ar, but, onlv one can bG docu^onted at this
ti~e. Also there is evidence of 12, not oreviouslv reoorted , aborted missions in 196^ which are nondin.7 validation.
�liERRICIDR
MACV FIXRD Wire
JATK
MISSION NO.
LOCATION
OJi'M)
ALTITUDE
INCIDRNT
CODE
AGENT
GAL.
Wr/ACRFT
HRRPS TAPi?
107?
N'RW in SCO VERY
*F.<;.HKS
AFCRT LIST
1Q6H
I'fiK
U»K
J
L'"K
U^'K
?
V
0
"^
Y=;.S
1966
6s- >">31 ? '-'•737
CROUOOTn
!]"K
J
UMK
1.1 IK
?
vn
'10
Yfi1^1
10^1 jalloTs/Mission
56071?
XSH5H230
L'MK
J
0
UVK
"JO
y [ i ^i
j
?000 3allons/Mission
101-1 Gallons/Mission
Over Water
f>'l1Q13
T?_1Q_iq
JFL
1965
'-^23
•>ni8l2
^-'-<335
J»::<
UMK
J
i:»t
100
^
?
5S')730
u-if
XS235870
U.K
WT
u^
UNK
UNK
vo
YES
^ppi
•>-70f,H
XT-^3?5
UNK
-!
UM"<
UMK
.'4
V:"1
Y^
Ovnr rubber Plantation
.60829
UNK
XS3I«5809-
»»
WT
^
U,K
»"
MO
YKS
i(inO/Gal Ions/Mission
66090?
JNK
WR 170399095325
UMK
WT
UNK
U«K
3
*iO
YES
661001
1-Q?f>9
UMK
U^K
DOT
UN'K
UMK
Jl
NO
YKS
B'^n Gallons/Mission
NO
YRS
?700 Gallons/Mission
YF.S *?
WO
1300 Gallons/Mission
Wrt
YKS
T
•570111
1-2095
UMK
UNK
DOT
0
UMK
3
670 1 1 2
1-730*
II «K
U,K
AND
n
UKK
1
.
�"I&CV FIXED WTN'G AIPCRftFT HK^PICTDR T"IUCENTS
-inf.
K
.-,7,,,.,
1-^,
0?o/2'l-27/*l 1
6-K.a
J
-7013 1
V<
XD320330
Ut.K
^702*9
2-^1-
x'r a ' if > i!'3'-;9001:36.
Li M r <
-'TS.Sir>' NO.
LOCATION
.LTITM.OE
(ijTM }
TMCIDEMT
CODE
UKHR.S TAP"1--"
f
.v>' I;ISCOV»RY
107?
flhOKT LI.ST
PKr'S^KS
GAL.
"r/AC^PT
0
'INK
3
"•'!
Y-S
1°.o" G3llons/'-"is3ion
CVL
0
UNK
3
'•"0
V H1 '-^
.700 qallons/'Sission
wr
T
27no
T
\ (i7 T^
'-TOT " • j i l u f i s / -ii :::>i'jri
flGEHT
I
"
907111:3
0
700
5
"'0
Y-!S
U»X
j
,JT
0
IJVK
'1
•^
YES
Past Enl of Target
2^00 Gallons/mission
Ur:<
UNK
DOT
p
250
3
VO
TRS
1500 Gallons/mission
3 .c ?7 r,
BO")?0-77T1
^0 Feet
DOT
0
(INK
3
\s
YES
?7HO Gallons/Xission
•I-P71*
PTO 370-0 7 7 "
Um
J
UNK
1000
fi
-0
YKS
570 in 6 *4-3<.'i3
U'JK
L'VK
WT
p.
U"K
?
M
0
YES
P-ist End of Target
1500 Gallons/Mission
•.''7'.> 4? 3
!)_-, 1 7 J
YD&024-6426
U.K
J
B
aoo
3
NO
YES
1%!"> Gallons/Mission
'-70S-',
r, _ ;< i| .1
U.K
UN !C
DOT
W
UWK
^
•JO
YES
5510 Gallor.s/Vission
•'705^5
l-K
YT690U40-
UNK
,T
w
aoo
U,K
'"70'- 10
f , _ 1 -r '-; v
UN'K
U^K
WT
0
U"K
3
-7-301
3-r?
XT C 175^65
'JMK
:y.'i^'-
--•r,--
()•:-<
07031°;
,- 3 1 oo
'-.yc;-*^
•'70 '-12
1
YES
VO
YES
O f f End of I'nr^ot
P?50 da lions/Mission
�•-'ACV FIX^D '.JP-rO ATRCHfl.FT M.SR
'-.".Tr!
•-.s-'-ioti ::o.
LOCATION
ALTIT'JDP:
IMCIDRMT
AGENT
GAL.
"p/'C^FT
HV^V-.BY
H«%R-^ T.flP^
ftPQivr LIST
(UTM)
fS7!~)fiOri
,,
,
7CW«,
son
j
W
,on
,.,-<
f": 707 "ft
7-HVi
U'X
Utr<
nor
0
P.O
-.73711
u-:<
BHlt
j
0
R no
i
,,
.
X?oa3 7
•:0
YF,
;-o
YK?
,-,-,
YRS
Ions/fission
21Q'
/* f tor
I'/n-Off
T V/ c
XT9S15
YT0113
"""
6v«, 3
r.70317
7-61 ?7
u«
u».
«i
"
-i j^7 y
1
"0
Y'-'S
Off
i
-
'-»«
1U3/23-3V
C!i5n
UNK
j
R
UWK
«-!»«
= TO 8 80
3^0
J
p
1000
3
vo
'
Y-:S
Y^ '-"I
00 Gallons/Mission
I •
YKS
115 0 flallons/i-'isaion
MO
Ove Sea-3 ^liles
Over
'•las of DsNanst
st,
r
l^ :
:0 Gallons/Mission
17
:':70S.17
U'iK
IJNK
"-««
j
B
200
3
YES
YKS ^i|
MO
itiles Northeast
It
u-Lai
(
Gallons/Mission
1S )
T
Of
r
07.90.
0-13114
iJ^'K
UMK
AND
0
[WK
r,
«719«
9-7-.W
u«
UNK
«T
0
UMK
•J
r-70<!2f,
9-7??2
(,X
,,<
AMD
"
UNK
'
YKS
YFS *«5
MO
NO
YKS
YRS
Y'vS fff>
-0
3r50
3^'^ Gallons/Mission
Off
O f f Knfl of Target
2q f j <*!*Lions/fission
?60
Gallons/mission
�FIX^D WINC- A r R C R f l F T
;A->-
MI? "TOP NO.
LOCATION
(UTM)
"
AGRMT
.LTITUiJS
G.ftL.
Mr/.CRPT
[JG]5^H<^ yflpc;
CO PR
107?
flP'lRT f,T8T
,70927
,.*«,
U-<
U,K
W
0
UMK
,
YF:?!
Y^'.S #S
•TO
-00 ^llona/'1laf
670957
}-7'S5
UHf
.;NK
A-D
w
U'-'K
3
Y»S
r-s ^7
r-)
PHOT '.IallonR/"isf
-S71QP8
;-T=°-
Uv<
UMK
• VD
0
UMK
^
Y^S
Y--S «
i"i
i«sn ^non.s/Mi,,
'- 3?I -
U T
a«
VT
p
™
^
,.->
YR,
O f f r-in'i of . r ar-?et
"•^ o o i n 3 1 1 o *"i s / ^ i sc
«TC«9
5-r? 15
UMK
UNK
AND
R
•J...K
3
Y-S
MO
?DOO Gal Ions/Vis;
' '"<HO
Ij_fl«11
im
UMK
AND
P.
UW
?
YRS
•,-7 -,029
'
'• T "9jO
','--iJT°.
UNK
UNK
DOT
UNK
UMK
3
r;1pn2
10-55*
U-K
i T M IT
Af'D
P
UMK
3
'•n-»
10.-^
UNK
I T\T f
AMD
P
UNK
£ 7 1 00";
10-12S3
UI:K
UNK
AMD
•>
<-,7m6
IP-1^6
UNK
UVK
J
'vi^i
n-1^4
LINK
UKK
• .'V^rt
n-?i7P
•INK
S7inio
n-,-.is
n--:v»?
.' i ' ' 1 ',
Y ^ S HI
?nOT Gallons/Mss
'
vo
YRS
Poundrifis of
Proj. 3-2-1-65
YPS
Y?.S «12
SO
3001 Gallons/Misf
3
Y-vS
Y.S 'M,
MO
?0m Gallons/Miss
UMK
^
IBS
YRS #14
MO
193^ Gallons/Mis."
R
^T
3
vo
YKS
Dunned in RiT MQJ
1700 Gallons/Miss
A-'D
P
iJMK
1
YRS
YFS f11
ro
1fllr> Gallona/Miss
' U^
r,Nn
0
UMK
*
YKS
Y : 'S -*17
r-O
-.000
UNK
urK
a-n
n
.»pr
u
YRS
Y!-'S ff 1 ^
NO
?«no ".aiion^Mi.,,
u««c
IHK
;«n
'••'
I»«K
1
YR,
Y ••<: '( in
M
n
n,Uon,/'-!l«
�TNCID^KTS
y!/V_QV F'lXRD _WI!>'G A I R C R A F T
^•i>:
^TSSTO" NO.
LOCATION
(UTM)
•LTITUns
AORMT
HAL.
Ir/AC^T
pp5p<5 T A P S
1Q7P
^000 Clallons/^ission
PO
3000 Gal lons/^ission
fp^ ft??
-0
?7r?r| Gq lions/fission
Y^-S
Y K S '*23
NO
?Qnn :>.!lons/'(ission
YI-.S
Y^S f p q
MO
?301 •,lr3llons/':ission
MO
YKS
Y^
yp.s *?5
MO
3-^00 -n^l lons/Xission
u
YES
YKS .»2fi
MO
3000 "allons/'-'issioi
H
v,,
Y-.S "27
wo
P^ r >o riallons/V.ission
Y.S
YF;S .''29
MO
3000 0^1 Ions/Mission
Y"S
Y-'S ^0
VO
it^O .^llonn/Misslon
NO
YES
Sprayed Off
Opoosite Luon<y r?oa
3900 Gallons/Mission
YES # 3 1
NO
2150 Gallons/mission
NO
YKS
Very tyear Bien !1oa
(Map)
YKS '/3?
NO
f>00 Gallons/Mission
10-M372
UNK
U»K
AND
V
IU1K
^
Y^S
Y K S "20
571017
10-^538
UNK
•JVK
AND
w
UMK
/a
Y^S
™ *"
571021
1C-5?aq
UNK
UVK
«»D
V
UW
'«
YPS
571026
10-7*57
Ur<
UMK
AND
0
vx*
U
VM'^7
10-7012
"JVK
'JMK
AMD
'• •
UMK
a
'71029
^-575
L'f'K
2500
J
w
1000
UV<
S711P2
11-^
UPK
UMK
AMD
'J
'JMK
6711^1
11-S36
u-::<
UMK
AND
n
UNK
?.71inS
I1-iq^3
u-
| | » | rr
AMD
0
IJK'K
671H7
ll-<^5
UNK
i T^^ y
AMD
571117
11-53?*)
UVK
\ \ V 6T
AND
0
urK
"
7
571 iifl
11-5633
UNK
UK-<
WT
w
UMK
1
£
11-6120
UNK
UNK
AND
o
J
II VK
,W
AND
0
UNK
"
UMK
'
*
UNK
-=71122
11-5973
UNK
'""
•10
571016
.71 120
>'»•••? O T ^ C O V - R Y
A PORT LIST
CODE
ri »T j*
Li iv i\
3
3
YFS
YES
�F I X F D V.'IT-'y a r ? C P a F T ^
IMCIOEMT
PATV
-issioM NO.
LOCATION
-/1 123
11- -693
:iv<
UVK
AND
n
U"K
11
^71130
II-CW
,ir,
r."<
AND
0
U'-'K
^
•5V 11 30
11-9r:70
UKK
U"K
V-T
n
UMK
*Y1^!|
5^8
XS3S5*)?
3T)o
DOT
U^<
IJMK
IJMV
071233
12-2097
M
UMK
AMD
w
UMK
•5
•' 7 1 :? 1 0
RI.-S5S
1-T133591
12-30
J
UMK
Uf-'K
UM'<
•371211
12-2*03
JN'lf
UN'K
AND
0
UNK
3
571P13
12-^196
UliK
U-K
AND
rt
UMK
^
*71 ? ? S
i?-?w
y«K
UV.T
i-'T
0
UMK
UNK
3^00
J
0
—
1-^173
UMK
UN'<
AVD
l-3'4?7
UMK
UNK
''80105
;'}^O1 1 £>
0*0113
ALTITUDK
MBIT
GAL.
Mr/«PR*T
HPBPSTA"
". (17?
f1'1'7'/ | > l^f"OV^' l *Y
yro;
Y- n^
rc
y,.
v ';- q;
T--.vfirf<3
!"•>
j} -^ Ji
2000 Oall3n=/»lr,Rion
ii,-
Y^
vn
Y^
Y'rS "3S
NO
30CP C-?llons/".ission
-o
yrs
Over yjuter
YRS
Y-3S R7
MO
nso Sallona/^isslon
YE5,
Y^.S . 3 R
T!0
2000 Gallons/Mission
3
».n
YS.S
Off ''Ind of Tar~ct
?30 n Gallons/Mission
1000
UMK
HO
T,,
DonT f'ai River
15 TTI East of Siaron
n
UMK
3
YES
YRS -HP
NO
1650 Gallons/Mission
AMD
i
UfTK
YW
YW tin
NO
17m Gallons/mission
^
*
V,,
Snrav Drifts'1
? 0 ?• 0 G a 1 1 on s / '•"• i s ." i c n
^01?3
1-6^12
UN-<
UMK
ftVD
n
UNK
••
YES
YE "3 /"I11
,0
3000 ..lallonS/MiMIon
5502"?
P-2P2
UVK
U\'K
AMD
0
u»»
3
Y-S
YKS MS
NO
1 f 300 Gallons/Mission
-0,02
;>-?•>•-;
UNK
CN.
M>D
-1
UN'K
s
YFS
V« ..<
MO
'JOOO ';.^1 lons/"-!lnsion
�•'ACV F I X 50 WIMP, a i R C R A F T 1'FR g ICTD F
MK
-issioa •:<!.
LOCATION
(UTM)
ALTITUDE
ACRNT
GAL.
"r/.C-FT
HRPRS T,P.
CO DP
107P
, m =,11on=/.-i.,,ton 7
,
MO
„,
So! 11 v/hilo on Ground
•TO
V 17 '3
YK^ fll: 7
'"0
^^0 '.'i :: illO!!lS/ - '^S53iOn
'•0
Y'..--.
?vcr Water
17'!0 r,»nons/^ission
Y^ *U«
vo
?QOO Gallons/'lission
YPS
.?•"):< N'orth of Siaeon
(Cu'on^ C i t v )
YRS *ri1
"0
^000 Gallons/Mission
Y^S »^
MO
5000 Gallons/Mission
?iO
ytvs
Defoliation of Pase
Caro Area
3000 Gallons/mission
YRS
YFS .'/55
NO
4500 Gallons/Mission
YUS
Y K S #5 f t
NO
5000 "allons/'lission
YES S57
h
C
YF070570-
•rriOS
5-33*0
„.,
UK,
SOG
0
™
c;
*nW
UN'K
•JN'K
,000
DOT
W
,nnn
Uf'K
:-/M09
J..3P77
•JNX
•J«K
AND
V
(JMK
^
roan
a.ii}75
UKK
I:KK
J
0
IJMK
?
'.can,
«-5 en?
UN'K
UNK
AND
0
UNK
3
YFS
<:Oi!2S
U-1257?
USK
f!5on
J
0
100^
6
YRS
.0.30
4-14202
UNK
L'^-'K
AMD
W
UNK
6
YES
^' ' j \) 1
5-363
UFK
UNK
AND
R
UNK
6
YKS
SO 50?
5-V5M
'JHK
UVK
WT
W
UNK
,
"Ml 2
5-S033
UNK
UNK
AMD
'•i
UNK
6
305 1 5 5-697'J
UNK
.:MK
AND
W
UNK
6
H n c, i ^ ^ 7?63
I(f
|I"V
\J * "•
AND
rt 1 4 1 /
W
MM IT
1 J 1 *\
c
)
,500
DOT
ST1.I.KS
,,
,
-K*.
•V~'<?0>1
up;-.! HT-'COVKRY
;. ->T^r MST
W
UV'-r
^
-
YRS
V
i000 M.T! Ions/Mission
�MfH:'V
'•:
LOCATION
(UTM)
j AT^CPflF'T H^
ALTITfJDS
,0,»T
dflL.
M
AP") = T LLST
,
5?6
5-11763
*.<
UMK
*MD
W
UM,
527
5-^6
UN'K
5onn
J
W
noo
V30
5-1~7 2 ?
U*K
UNK
W
w
UHK
,
c':n6
S,_i;p(j
U»<
60T)
DOT
MW
UFK
500
£, _ ~ 0 7
Ynnr^n
«soo
,i
rv
IJMIf
7
YRS
y^s
!-T0
'i^OO n3 lions/ '-Ms? ion
y-.s
*'-' South of
Xinn Loc
yv s *5Q
:J '"*
vm"1 "qllors/^issinn
-T
^
y., «q
'•'1
m
1
,', (5 ni
.™,.w
r/«CRFT
CODE
Y ^ =;
^ c c id f?n tfj 1 Ou~nD
,
Y-,
''tf^'S
',' n C* f
-*i ^
XA
r ' i J '•"
1^00 CJallois/yission
nil
<-*&3
L'N-K
UWK
DOT
0
U«1T
P,
616
6-^1?
li'jr
U.K
OOT
w
UMST
619
IE-W
L'-.'K
7500
J
w
U','K
^V-501P
f,SOT
J
«-?•.!*
UKK
UN^
UVK
YS140510
f.p-^
'..-.^.;
n29
w•>«
M "1
YRS
foil Gallons/Mission
^
"0
Y'S
-^ ^llcni./vtMlon
moo
^
ro
YKS
?DOO ;:-allons/Missicn
l!MK
liHK
UMK
«-,
YRS
DOT
n
ON«C
,
10
Y^S
?ot;Q Gallons/Xission
2500
VT
p
'JNK
urx
K-O
YRS
Runir Sqt Zone and
Over Water
JN'K
u?."c
DOT
w
UNK
5
NO
Y^;S
5000 Gallons/mission
UNK
UVK
J
0
mm
1 ^
1
vo
YKS
YFS
»
709
--12
7-7^1
INK
�M
OATK
•1I3SIO!" NO.
LOCATION
(UTM)
ACV FTX3D WING AIRCRAFT MERPICIDR P'CIDF'*TTS
.' LTITUOE
AGR«T
GAL.
Mr/ftCRFT
HI5RRS T.ftPl=:
107P
N'KW DISCOVERY
!---:-i«pscs
ft PORT LISTS
CODE
™
PMUOC ftK Village
f'O
Y-S
Over Mour.tain POH*!
3
MO
YRS
2000 3allons/"!i?slon
UN'K
fi
MO
Y^
57^0 Gill.-.ns/yission
UN'K
UMK
U^K
"0
YFS
,1
UNK
IR'K
UMK
'0
'
YRS
4200
DOT
UN:<
U«K
UK<
VO
Y
YT5177-5453
5^00
J
UNK
UNK
11 WK
MO
YES
6711
UNK
1000
J
p
UMK
?
N'C
YES
T-miediately After Take
Off and then return to
RIEN HO A
2000 Gallons/Mission
631 119
6705
UNK
UNK
DOT
B
UNK
3
MO
YES
2000 Gallons/Mission
5*1121
UN'K
UNK
500
B
UNK
UNK
MO
Y-7S
On Take Off FPOTJ
HI'-JN HO A
5H.1P01
L'V.K
UN'K
1SOO
0
UMK
UMK
ro
5?OB?1
3-1725
BP220920RP220890BP 100 840-
U«K
DOT
R
1000
3
"°
630S26
UNK
BP6359P"
4000
J
UNK
UNK
UNK
6 SO 331
9-2391
UKK
UMK
DOT
B
UNK
-0922
017
.^
UN'K
WK
DOT
n
6*1929
U"K
XS403800
4700
DOT
W929
UN'K
YTH40930
7500
531107
UN'K
YT21538QYTOR0230
5*1107
LTK
fi«1119
•'
J
"
5 Tiiles South West
RTF.M HO A Runway
�:iflt:v VIXFD WIMG AIRCRAFT
>A?rf
XISSJON TO.
LOCATION
(UTM)
ALTITUDE
I"CIDEMT
CODF
AGWT
OAL.
«p/«CRFT
„,
, ,
- ,
S81221
6701
UN-K
UMK
AND
VJ
UNK
1
iv^
UN<
7500
WT
0
-JMK
\ 9 '. ) 1 P o n-v
»"•"'
pono
J
V
n,K
C,K
DOT
i-K
WT
107?
t:*CW DISCOVRHY
PKMftRKS
A n O R T LISTS
*™
,<
,
HPRPS TAPH
••'
•T)
^
.-,
30TO 'j-illons/'-'ission
Y-S «0
•n
n^
^
y^s
Over PIM'j T!'Y
UNK
..MK
\:o
Y-:S
^nir FI-1W MO A
'.'J
UMK
•j
-n
YF ^
1003 CtalloWlwl:*
,T
0
UM,
3
NO
Y C1 ^
'/'roi^-T V^illev
Y-S
1Q6Q
? ••* '1 ? 0 P
6701
:<P306
6 '? OS
983571S Q 2 3 2 "?
UNK
JN-
3^00
J
0
U«K
.IVK
MO
Y^
i 90 It 11
U::K
YC9010
70no
J
UN'K
•IMK
WK
MO
YKS
Over ''ountains
59^1?
6700
uXK
UMK
DOT
0
UNK
s
NO
YES
Hi«rh Winds 3000 (Jal due
to Abort 2nd Pun but
1 Plane DOT
3Q0112
6703
UN'K
IW
DOT
^
UNK
s
r:o
Y^S
j O f) i \?
|
,,
,
U?,'K
2000
DOT
0
I) MIC
UK"?
r*o
YK.
Possibly sane as above
j 0 'T i) 2 2
UN<
HTHS23
^no
•,T
UVK
UNK
UNK
wo
Y-;S
Me?ir TAri KY
r 7
•J»IK
1JMK
DOT
0
IW
3
VO
YKS
300H G-I lions/fission
^O.'12't
' °' t
�'•i'Cv FIXED wj"i AIRCRAFT K^PPTCTDF: TvicijjfZI3.
uppt^cj T A P ^
1Q7?
ePOF'T Ll.Si'S
PJCIDEK1!
CODR
AG^T
OflL.
nir/ACRFT
UN'K
[JOT
UMK
iriK
-
r;O
i-
lion GHllon^LasiO,,
U'JK
L'Mlf
WT
n
UMK
c
^:0
YF,r,
Sprp.ved outside tsr-'et
^000 r.lallons/''!issior
U'JK
u::<
UI--3C
wr
0
UMK
UMV
NO
o
Y n.*
'*j
LONfl PTfHi Villgse
5 7" 7
'.'-
JHK
J
-JVC
u«
Vfl
Y«
iJUTin Valve .activated
70^210
67^1
U">'V
yi:r<
v'T
0
;JN'K
x:
0
Y"S
Soravnl Lite
2200 'Jallonn/Missio.'.
7.10110
ST«
am
J
B
UMK
NO
Y'iS
5700 Gallons/mission
UVK
AMD
p
K'O
1050 Gallons/Mis? ion
OATH;
XI S3 ION NO.
LOCATION
(UTM)
'ju-'VlU
6r*
7, Vl 30 110ZV173131*
<':Q0710
67Tt
^909 —
S91319
1970
701216
6793
F
r** cf oC.c^.j!i Q
Tvi' ^j
ur.'K
ULTIT'JDK
^
^
7
NKW DISOOV^RY
R5MARKS
�O-io
t
O- lo
5
t
U
�CT'
3
p
-f
s
(TJ
UJ
J?
1
�
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
017
Folder
The folder containing the original item.
0189
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Description
An account of the resource
<strong>Corporate Author: </strong>Department of the Army, Office of the Adjutant General, Alexandria, VA
Title
A name given to the resource
Table: MACV Fixed Wing Aircraft Herbicide Incidents, 15 October 1981
Subject
The topic of the resource
HERBS database
Ranch Hand aircraft
herbicide application
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/4add1471606266da07270d34132a966f.pdf
18d963859085ea24a26bf603f01acbda
PDF Text
Text
P:
AuttlOT
00190
Young, Alvin L.
Report/Article Title Typescript: The Military Use of Herbicides in South Vietnam, 1962-1971, 16 May
1983
Journal/Book Title
Year
Color
Number of Images
000
°
u
2
Summary of history of herbicide use, including types and amounts, in Vietnam,
Friday, January 05, 2001
Page 190 of 194
�THE MILITARY USE OF HERBICIDES IN SOOTH VIETNAM, 1962-1971.
Research and development on phenoxy herbicides began in the early 1940s,
when nost of the initial phytotoxic screening programs and the development
of explication technologies were sponsored by the DoD. The herbicide,
2,4,5-T, was first commercially produced in the United States in 1947.
During the years from 1961 through 1969, the DoD procured 53 million
pounds of this herbicide (approximately 34 percent of the total US
production) for use in the Republic of Vietnam (SMN). However, 8.9
million pounds of that amount were not sprayed in Vietnam, but were
destroyed by at-sea incineration in 1977. The first sustained DoD
operational use of herbicides was initiated during the Vietnam Conflict
(Operation RMICB HMO) and the first shipment of herbicides used in KftNCH
HAND was received at Tan Son Nhut Mr Base, (RVN), on 9 January 1962. The
use of these compounds was intended to accoaplish two objectives: (1) the
defoliation of vegetation to improve visibility and thus decrease the risk
of ambush, and (2) the destruction of enemy crops.
Four 2,4,5-T containing herbicides were used by the military during the
period 1962-1970. These four included:
(1) Herbicide Purple (used from 1962 through 1964)
n-butyl
n-butyl
iso-butyl
2,4-D
2,4,5-T
2,4,5-T
50%
30%
20%
(2) Herbicide Pink (used from 1962 through 1964)
n-butyl
iso-butyl
2,4,5-T
2,4,5-T
60%
40%
(3) Herbicide Green (used from 1962 through 1964)
n-butyl
2,4,5-T
100%
(4) Herbicide Grange (used from early 1965 through 15 April 1970)
n-butyl
n-butyl
2,4-D
2,4,5-T
50%
50%
Analyses of archived samples of Herbicides in 1972 suggested that the mean
concentration of TCDD may have been approximately 33 ppm (Range: 17 to 47
ppm TCDD) for Herbicide Purple while archived samples of Herbicide Orange
had a mean concentration of approximately 2 ppn (Range: <0.02 to 15 ppm
TCDD).
In addition, two other herbicides were widely used in KVN. These were
Herbicide Blue, an organic arsenical formulated fron the sodium salt of
cacodylic acid, and Herbicide Wiite, a water soluble triisopropanolamine
salt formulation of 2,4-D and picloram. The amounts of the various
herbicides used in RVN from January 1962 through February 1972 are shown
in Table 1.
�Table 1.
QUANTITIES OP
AM) TCDD
IN EMS, JAN 1962-PEB 1972
CHEMICAL
2,4-D
2,4, 5-T
TCDD
55,940,150
44,232,600
368
Picloram
Cacodylic Acid
Herbicide Total
3 , 04 1 , 800
3,548,710
106,763,260
Ninety-six percent of the 2,4,5-T disseminated in RVN was contained in
Herbicide Orange; the remaining 4 percent in Herbicides Green, Pink, and
Purple. However, Herbicides Green, Pink and Purple contained
approximately 40 percent of the estimated amount of TCDD disseminated in
WN. Green, Pink and Purple were sprayed as defoliants on less than
90,000 acres from 1962 through 1964, a period when only a small force of
U.S. military personnel were in WM. Ninety percent of all the Herbicide
Orange (containing 38.3 million pounds of 2,4,5-T and 203 Ib of TCDD} was
used in defoliation operations on 2.9 million acres of inland forests and
mangrove forests of 8VN.
Most of the herbicide used in RVN was sprayed from aircraft. RANCH HAND
aircraft, the C-123, disseminated 88 percent of all herbicide.
Helicopters and ground application equipnent used by personnel from all
branches of the U.S. Armed Forces applied the remaining 12 percent,
primarly Herbicide Blue, to maintain visibility around base perimeters.
Concurrent with the change to Herbicide Orange, the scope of aerial use
shifted from four aircrews on temporary assignments, to 36 permanently
assigned aircrews, and additional support personnel. Following the
announcement in October 1969 that the administration of 2,4,5-T to
pregnant rodents caused an increase in the rate of congenital
abnormalities, the DoD confined Herbicide Orange spray operations to
nonpopulated areas and in April 1970, all uses of the 2,4,5-T containing
herbicides were halted. Other non-2,4,5-T herbicides continued to be used
until June 1971 and Operation BANCH HAND was officially deactivated in
October 1971. In March 1972, all remaining stocks of 2,4,5-T containing
herbicides were removed from IWN, and transported to Johnston Island,
Pacific Ocean, for open storage (Project PACER IVY), and Environmental
Protection Agency (EPA) suspended many uses of herbicides containing
2,4,5-T because an epidemiologie study in the United States attributed
abortogenic (miscarriage) effects to its use.
�
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
017
Folder
The folder containing the original item.
0190
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Creator
An entity primarily responsible for making the resource
Young, Alvin L.
Title
A name given to the resource
Typescript: The Military Use of Herbicides in South Vietnam, 1962-1971, 16 May 1983
Subject
The topic of the resource
Ranch Hand
dioxin
herbicide application
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/471d7083ad383802b5903b6eadf0fbec.pdf
4223a7930cb9ecb9cc5da02099f70aec
PDF Text
Text
Item ID Number:
00191
Author
Young, Alvin L.
Report/Article Title Typescript: Chapter 2: The Military Use of Herbicides in Vietnam, "Massive
Quantities of Herbicides Were Applied by the United States in a Tactical Operation
Designed to Reduce Ambushes and Disrupt Enemy Tactics"
Journal/Book Title
oooo
Month/lay
Number of Images
23
Typescript for Chapter 2 in A.L. Young and G.M. Regigani, eds., Agent Orange and
Its Associated Dioxin: Assessment of a Controversy (Amsterdam: Elsevier, 1988}
Friday, January 05, 2001
Page 191 of 194
�CHAPTER 2
"MASSIVE QUANTITIES OF HERBICIDES WERE APPLIED
BY THE UNITED STATES IN A TACTICAL OPERATION DESIGNED
TO REDUCE AMBUSHES AND DISRUPT ENEMY TACTICS"
THE MILITARY USE OF HERBICIDES IN VIETNAM
A. L. YOUNG
The introduction of herbicides in 1962 into the armed conflict in
Vietnam represented an application of a new technique for modern warfare.
Their use in a defensive role was for defoliation.
roles was for crop denial.
Their use in offensive
Today, fifteen years after the last spray
mission, these herbicides are at the center of intense scientific debate
involving not only medical but also legal, political and ecological issues.
This chapter reviews the historical and operational concepts and some
potential human exposure considerations
involving
the military use of
herbicides in the Southeast Asian Conflict.
Herbicides Used in South Vietnam
Synthesis technology, efficacy data, and field application techniques
were developed for the two major phenoxy herbicides 2,4-dichlorophenoxyacetic acid (2,4-D) and 2,4-5-trichlorophenoxyacetic acid (2,4,5-T) during
World War II at Fort Detrick, Frederick, Maryland (12).
II,
the commercial use
of these two
revolutionized American agriculture.
"synthetic"
Following World War
organic herbicides
In 1950, more than 4.5 million
kilograms (kg) of these materials were used annually for weed and brush
control in the United States.
used (13).
By 1960, in excess of 16 million kg were
�In May 1961, the Office of the Secretary of Defense requested the Fort
Detrick personnel to determine the technical feasibility of defoliating
jungle vegetation in the Republic of Vietnam ( )
7.
By early Fall, 1961, 18
different aerial spray test 8 (defoliation and anticrop) had been conducted
with various formulations of commercially-available herbicides.
The choice
of these herbicides was based upon the chemicals that had had considerable
research, proven performance, and practical background at that period in
time ( )
4.
Also, such factors as availability
in large quantity, costs and
known or accepted safety in regard to their toxicity to humans and animals
were
considered
(12).
The
defoliation and anticrop
mixtures of herbicides.
results
of these
tests were
effects could be obtained
with two
significant
different
The first was a mixture of the n-butyl esters of
2,4-D and 2,4,5-T and the iso-butyl ester of 2,4,5-T.
code-named "Purple."
that
This mixture was
The second "military herbicide was code-named "Blue"
and consisted of the acid and sodium salt of cacodylic acid.
The colored
bands which were painted around the center of the 208-liter drums served as
aid to the identification by support personnel ( )
1.
The first shipment of Herbicides Purple and Blue was received at Tan
Son Nhut Air Base, Republic of Vietnam, on 9 January 1962. These were the
first military herbicides
used in
Operation
RANCH HAND, the tactical
military project for the aerial spraying of herbicides in South Vietnam ( )
1.
Two additional phenoxy herbicide
formulations
were received in limited
quantities in South Vietnam and evaluated during the first two years of
Operation RANCH HAND.
These were code-named Pink and Green.
By January
1965, two additional military herbicides, code-named Orange and White, had
been evaluated
and brought
into the spray program.
Herbicide Orange
replaced all uses of Purple, Pink, or Green, and eventually became the most
widely used military herbicide in South Vietnam (7).
The composition of
the three major herbicides in South Vietnam were as follows:
�1. Herbicide Orange
Orange was a reddish-brown to tan colored liquid soluble in diesel fuel
and organic solvents, but insoluble
in water (15).
One liter of Orange
theoretically contained 510 grams of the active ingredient of 2,4-D and 530
grams of the active ingredient of 2,4,5-T.
Orange was formulated to contain
a 50:50 mixture of the n-butyl esters of 2,4-D and 2,4,5-T. The percentages
of the formulation typically were:
n-butyl ester of 2,4-D
free acid of 2,4-D
n-butyl ester of 2,4,5-T
free acid of 2,4,5-T
inert ingredients (e.g.,
butyl alcohol and ester
moieties)
49.49
0.13
48.75
1.00
0.62
2. Herbicide White
White was a dark brown viscous liquid that was soluble in water but
insoluble in organic solvents and diesel fuel (15).
One liter of white
contained
of
65
grams
of
the
active
ingredient
4-amino-3,5,6-
trichloropicolinic acid (picloram) and 240 grams of the active ingredient of
2,4-D.
White
was
formulated
to
contain
triisopropanopamine salts of picloram and 2,4-D.
a
1:4
mixture
of
the
The percentages of the
formulation were:
triisopropanolamine salt of picloram
triisopropanolamine salt of 2,4-D
inert ingredient (primarily the
solvent triisopropanolamine)
3.
10.2
39.6
50.2
Herbicide Blue
Blue was a clear yellowish-tan liquid that was soluble in water, but
insoluble in organic solvents and diesel fuel (15).
One liter of Blue
contained 370 grams of the active ingredient hydroxydimethyarsine oxide
(cacodylic acid).
Blue was formulated to contain cacodylic acid (as the
free acid) and the sodium salt of cacodylic acid (sodium cacodylate).
The
�percentages of the formulation were:
cacodylic acid
sodium cacodylate
surfactant
sodium chloride
water
antifoam agent
4.7
26.4
3.4
5.5
59.5
0.5
As previously noted, not all of the herbicides used in South Vietnam
were used throughout the entire 10 years (1962-1971) encompassed by the
Department
of
Defense
defoliation
program.
In
addition,
2,4,5-T
formulations used early in the program are believed to have contained higher
levels of the toxic contaminant TCDD (2,3,7,8-tetrachlorodibenzo-p-dioxin
the time periods shown in Table 1 can be differentiated on the basis of
specific herbicides used and the mean dioxin content (15).
TABLE 1 - THE DIFFERENTIATION OF THE THREE TIME PERIODS DURING THE
US MILITARY DEFOLIATION PROGRAM IN SOUTH VIETNAM AND MEAN DIOXIN CONTENT
PERIOD
HERBICIDES USED
MEAN DIOXIN CONTENT*
January 1962 June 1965
Purple, Pink, Green
Blue
32**
0
July 1965 June 1970
Orange
White, Blue
2+
0
July 1970
October 1971
White, Blue
0
*Found only in 2,4,5-T containing formulations,
**Value based on analyses of five samples.
+Value based on the analyses of 488 samples.
Herbicide Orange was the most extensively used herbicide in South
Vietnam (5). Orange accounted for approximately 40.5 million liters of the
67 million liters of herbicide used (Table 2).
June 1970.
It was used from mid-1965 to
However, as noted in Table 2, Orange was not the only 2,4,5-T
containing herbicide used in the defoliation program ( )
6.
of Purple, Pink, and Green, all containing
through mid-1965 (5,15).
Small quantities
2,4,5-T were used from 1962
In subsequent sections of this document, the term
"Herbicide Orange" will refer to all of the 2,4,5-T containing herbicides
�used in Vietnam (Purple, Pink, Green, and Orange).
TABLE 2 - NUMBER OF LITERS OF MILITARY HERBICIDE PROCURED BY
THE US DEPARTMENT OF DEFENSE AND DISSEMINATED IN SOUTH VIETNAM
DURING JANUARY 1962 - OCTOBER 1971(+)
Code Name
Herbicide
Quantity
Period of Use
Orange
2 ,4-D; 2,4,5-T
40,295 ,000
1965 -1970*
White
2 ,4-D; Picloram
21,321 ,000
1965 -1971**
Blue
Cacodylic Acid
4,353 ,000
1962 -1971**
Purple
2 ,4-D; 2,4,5-T
549 ,000
1962 -1965
Pink
2 , 4,5-T
46 ,600
1962 -1965
Green
2 , 4,5-T
31 .400
1962 -1965
Total
67,015 ,400
+Source: Craig ( )
6.
*Last fixed-wing mission of Orange 16 April 1970; last helicopter mission of
Orange 6 June 1970.
**Last fixed-wing mission 9 January 1971; all herbicides under US control
stopped 31 October 1971.
The data in Table 2 were obtained by Craig (6) in 1975 from examination of
procurement records maintained by the San Antonio Air Logistic Center, Kelly
Air Force Base, Texas.
The completeness of the records is unknown.
A log
of herbicide applications was maintained by the United States Military
Assistance Command, Vietnam, and these "paper records" became the source
documents for the National Academy of Sciences (NAS) 1972-74 study of the
effects of herbicides in South Vietnam (5).
records into the HERBS Tape.
6,100
herbicide
71,672,760
The HERBS Tape contained data on approximately
missions with
liters.
As
procurement documents
The NAS computerized these
noted
an estimated
in Table 2,
herbicide
expenditure
Craig could only
on 67,015,400 liters.
account
of
for
The National Academy of
Sciences (5) estimated that their record searches and/or incomplete records
accounted for 86% of the RANCH HAND missions.
In 1985, the United States
Army and Joint Services Environmental Support Group, a joint (Army, Air
Force and Navy) military group of military record specialists completed an
�exhaustive search of the military records of the Vietnam era.
This unit
constructed a data base of 2,394 additional military herbicide missions in
Vietnam that were either improperly/incompletely documented in the HERBS
Tape or were missions unrecorded.
An additional 557 RANCH HAND fixed-wing
missions were identified/verified.
Tape contain
spraying.
Of significance, the SERVICES HERBS
data on helicopter, backpack
and other types of ground
When the two tapes (HERBS and SERVICES HERBS) were combined,
8,930 missions were identified and 72,740,400 liters of herbicide were
reported (Table 3).
TABLE 3 - HERBICIDE MISSION DATA FROM COMBINING
HERBS TAPE (1974) AND THE SERVICES HERBS TAPE (1985), 1961 - 1971 *
Herbicide
Number of
Missions
Total Number of
Liters
Orange
4,698
44,953,560
White
2,194
20,616,860
Blue
981
4,712,920
Unknown**
965
2,339,460
92
117,600
8,930
72,740,400
Other (Purple,
Green, etc)
Total
*Data combine all fixed-wing, helicopter, and ground application missions .
**Records document herbicide mission but do not identify specific herbicide.
Use Patterns of Individual Herbicides
Each of the three major herbicides
specific uses.
(Orange, White, and Blue) had
About 90 percent of Herbicide White was applied in
defoliation missions.
It was not recommended for use on crops because of
the persistence of picloram in soils.
Because the herbicidal action on
woody plants was usually slow, full defoliation did not occur for several
months after
spray application.
Thus, it was an ideal herbicide for use in
the inland forests in areas where defoliation was not immediately required,
�with Orange or Blue.
Herbicide Blue was the herbicide
missions involving cereal or grain crops.
of choice
for crop destruction
Approximately 50 percent of all
Blue was used in crop destruction missions in remote or enemy controlled
areas with the remainder being used as a contact herbicide for control of
grasses around base perimeters (9).
Approximately 85 percent of all Herbicide Orange was used for forest
defoliation and it was especially effective in defoliating mangrove forests.
Eight percent of Herbicide Orange was used in the destruction of broadleaf
crops (bean, peanuts, ramie, and root or tuber crops).
percent was used around
The remaining 7
base perimeters, cache sites, waterways, and
communication lines.
Table 4 shows the number of hectares sprayed with herbicides in South
Vietnam within the three major vegetational categories.
TABLE 4 - THE NUMBER OF HECTARES TREATED
IN SOUTH VIETNAM, 1962-1971, WITH MILITARY HERBICIDES
WITHIN THE THREE MAJOR VEGETATIONAL CATEGORIES*
Vegetational Category
Hectares Treated**
Inland forest
1,080,970
Mangrove forests
127,750
Cultivated crops
105.260
Total
1,313,980
*Source: National Academy of Sciences, 1974 (5).
**Areas receiving single or multiple coverage.
Certain portions of South Vietnam were more likely
subjected to defoliation.
Herbicide
expenditures for the four Combat
Tactical Zones of South Vietnam are shown in Table 5.
obtained from HERBS Tape.
to have been
These data were
The distribution of defoliation missions was
mapped by the National Academy of Sciences (5) and is shown in Figure 1.
Figure 2 is a map of Vietnam identifying the provinces and major cities.
�TABLE 5 - HERBICIDES EXPENDITURES IN SOUTH VIETNAM,
1965-1971: A BREAKDOWN BY COMBAT TACTICAL ZONE*
Herbicide Expenditure
(liters)
Orange
White
Blue
Combat Tactical Zones
CTZ I
8,516,360
1,374,000
1,127,900
CTZ II
9,534,400
2,759,300
1,790,300
CTZ III
20,094,600
14,076,400
1,112,800
4.644.200
1.646.500
234.700
(includes Saigon)
CTZ IV
42,789,500
Subtotals
19,856,200
Grand Total
*Source:
4,265,700
66.911.400
HERBS Tape
In addition to the herbicides, numerous other chemicals were shipped to
South Vietnam in 208-liter drums.
These included selected fuel additives,
cleaning solvents, cooking oils, and a variety of other pesticides.
The
insecticide malathion was widely used for control of mosquitoes and at least
1,514,000 liters of it was used from 1966 through 1970.
smaller
quantities
of lindane and DDT were used
throughout the war in Southeast Asia.
In addition, much
in ground
operations
The distribution of the herbicides
within Vietnam after their arrival did not occur randomly.
About 65 percent
was shipped to the 20th Ordnance Storage Depot, Saigon, and 35 percent was
shipped to the 511th Ordnance depot, Da Nang.
Military Aircraft and Vehicles Used in the Dissemination of Herbicides
Numerous aircraft were used in the air war in Vietnam, but only a few
of these aircraft were used for aerial dissemination of herbicides.
"work horse" of
aircraft was
carriage.
Operation RANCH HAND was the C-123, "Provider."
adapted
to
receive a modular
spray
system
The
This cargo
for
internal
The module (the A/A 45 Y-l) consisted of a 3,785 liter tank pump,
and engine which were all mounted on a frame pallet.
An operator's console
�was an integral part of the unit, but was not mounted on the pallet.
booms
(3.8 cm in diameter and 6.7 m in length)
engine nacelles toward the wing tips.
Wing
extended from outboard
A short tail boom (7.6 cm in
diameter, 6.1 m in length) was positioned centrally near the aft cargo door.
Each aircraft normally had a crew of three men:
the pilot, co-pilot
(navigator), and flight engineer (console operator).
During the peak
activity of RANCH HAND operations (1968-1969), approximately 30 UC-123K
aircraft were employed.
However, many other squadrons of non-RANCH HAND C-
123 aircraft were routinely used throughout
South Vietnam in transport
operations.
The control of malaria and other mosquito-borne diseases in South
Vietnam necessitated an extensive aerial insecticide application program in
order to control these vector insects.
from 1966 through 1972, three C-123
aircraft were used to spray malathion, an organophosphate
insecticide.
These aircraft could be distinguished from the herbicide-spraying aircraft
because they were not camouflaged.
These aircraft routinely
sprayed
insecticide adjacent to military and civilian installations, as well as in
areas where military operations were in progress, or about to commence.
Approximately 10 to 12 percent of all herbicides used in South Vietnam
was disseminated by helicopter or ground application equipment.
Generally,
helicopter crews were not assigned to herbicide spray duties on a full-time
basis and rotated the spraying duties with other mission requirements.
The
military UH-1 series of helicopters, deployed by the Air Force, the Army,
and Navy units, generally sprayed the herbicides.
The most common spray
systems used were the H1DAL and AGRINAUTIGS units.
These units were
installed in or removed from the aircraft in a matter of minutes because
they were "tied down" to installed cargo shackles and aircraft modifications
were not required for their use.
Each unit consisted of a 760-liter tank
and a collapsible 9.8 m spray boom.
The unit was operated by manual
controls to control the flow valve and a windmill brake.
helicopter had three crew members.
Generally, each
�A summary of the aircraft used in herbicide and insecticide operations
is shown in Table 6.
TABLE 6 - MILITARY AIRCRAFT USED IN THE DISSEMINATION
OF HERBICIDES AND INSECTICIDES IN SOUTH VIETNAM
Aircraft
Camouflaged
Chemical Disseminated
UC-123/UC-123K
Yes
All Herbicides
UC-123K
No
Malathion
Helicopter
Air Force UH-1
"*\
Army UH-1B/UH-1D.H-34Y Yes
Navy H-19
Orange, Blue
J
Various ground delivery systems were also used in South Vietnam for
control of vegetation in limited areas.
mounted on vehicles.
turbine.
One unit that was routinely used was the buffalo
It developed a wind blast with a velocity up to 240 km/h at 280
m^/minute volume.
essentially
Most of these units were towed or
When the herbicide was injected into the air blast, it was
"shot" at the foliage.
The buffalo turbine was useful for
roadside spraying and applications of perimeter defenses.
The herbicides of
choice in these operations were Blue and Orange.
Mission Concepts
The objectives of the defoliation and anticrop programs in South
Vietnam have been thoroughly reviewed by Huddle (11) and others (2,3,5,7).
It is the objective of this section to elaborate only on the background and
mechanics of a "typical" herbicide mission that would have influenced the
degree of exposure to herbicides by aircrew and/or ground personnel.
The
following scenario of events or "standard operating procedures" has been
compiled from the literature and interviews by Young et al (15), and is
captured in photographs in Figures 3 through 2%.
10
�1. Each of the 11
different companies that manufactured military
herbicides packed them in new ICC 17C 208-liter 18 gauge steel drums for
shipment to Southeast Asia.
shipment of Blue.
Until 1967, lined drums were used only for
However, because of the results of compatibility tests,
lined drums were also used to ship White beginning in 1967.
2. Each herbicide drum was
marked with a 7.6 cm color-coded band
around the center to identify the specific military herbicide.
This marking
was initially a 30 cm band, but was changed to a 7.6 cm band in March 1966.
3. Shipping time from the
arrival of the herbicide at a US port
until it arrived in South Vietnam varied from 47 to 52 days.
4. About 10 out of every
damaged or defective state.
10,000 drums shipped were received in a
This represented a damage rate of 0.1 percent.
About 50 percent of these damaged drums leaked as a result of punctures or
split seams.
These were caused by improper loading and defective drums.
Forklifts operated by stevedores also caused punctures.
Redrumming was
accomplished at the ports.
5. About 65 percent of the
herbicide was shipped to the 20th
Ordnance Storage Depot, Saigon, and 35 percent was shipped to the 511th
Ordnance Storage Depot, Da Nang.
Under the normal handling procedures,
drums were unloaded at Da Kang and Saigon from the cargo vessel directly
into semi-trailers and were placed in an upright position.
were driven
to the various
units
The trailers
of the 12th Air Commando
Squadron
(primarily at the bases of Da Nang, Phu Cat, or Bien Hoa) for disposition.
6. Normally the contents of the
drums were transferred into
blocked F-6 trailer tanks through a suction tube without removing the full
drums from the semi-trailers.
78 drums of herbicide.
the
total
inventory,
Each F-6 trailer held 16,300 liters or about
If blocked F-6 trailer tanks could not accomodate
the drums were stacked in pyramidal
needed.
11
style
until
�7.
The transfer of the herbicides from the 208-liter steel drums
to storage tanks or aircraft tanks required some precautionary measures.
Personnel charged with the supervisory responsibilities of handling the
herbicides were indoctrinated in appropriate safety precautions including
the use of gloves and face shields as needed.
Personnel handling the
chemicals were encouraged to "take normal sanitary precautions and to
maintain personal cleanliness and to avoid skin and eye contact with the
material.
Contaminated clothing were to be washed before re-use. Spillage
on the skin or in the eyes was to be rinsed copiously with clean water.
8. When the herbicide was
pumped from the drums into the F-6
trailers about 2 to 5 liters remained in the drum.
Hence the drum was
placed on a drain rack and the "drippings" were collected from many drums in
a pan-type receptacle and used for spraying base perimeter areas.
9.
Empty drums were generally given to the
military forces
(Vietnam, U.S. and Free World Military Assistance Forces) for use as
barriers in defensive positions.
The drums were filled with sand or
concrete and used in the construction of bunkers or in foundations for
runways and barbed wire perimeters.
10. Surface areas contaminated by
spillage of the herbicides
were flushed with diesel fuel or water with diversion of the drainage into
settling basins or pits for incorporation into the soil.
11.
The F-6 trailers were tied to plumbing and pumps so that the
herbicide could be delivered to the aircraft without moving the trailers.
12. As previously noted,
Blue and White were not.
a gummy substance formed.
Orange was insoluble in water, while
When Orange was mixed with either Blue or White,
The F-6 trailers were therefore color-coded to
correspond to the drum color-codes and used exclusively for the herbicide
to which the code applied.
13. The aircraft spray tanks,
positioned in the center of the
airplane, and the spray system were purged before the type of herbicide
carried was changed.
Particular attention had to be given to sequences
12
�involving Blue and White.
A mixture of these two herbicides resulted in
the formation of a precipitate consisting of the sodium salt of 2,4-D.
14. Most of the personnel involved in the actual handling of the
herbicide drums were Vietnamese.
However, a USAF flight mechanic or crew
chief was responsible for insuring that the aircraft was properly loaded
and the spray system functional.
operator for the spray unit.
A flight mechanic was also the console
The pilot and co-pilot were officers while
the flight mechanics, crew chiefs and other ground support personnel were
enlisted men.
15. For record keeping purposes a herbicide "mission" consisted
of several aircraft; if only one aircraft was used the operation was termed
a sortie. All missions within a target formed a project.
16. Aircraft takeoffs were
normally before sunrise.
From a
tactical point of view, the arrival of the aircraft at the target area just
prior to sunrise permitted the aircraft to approach the target from the
direction of the rising sun.
enemy ground fire.
This afforded some degree of protection from
From the standpoint of herbicidal action, application
by aerial spray was most effective if accomplished prior to 0800 hours
while inversion conditions existed, in the absence of precipitation, and
while the wind was calm or not exceeding a velocity of 8 knots.
This
insured the proper settling of the spray on the target area.
17. Within the aircrafts,
it was not uncommon to have herbicide
leakage from around the numerous hose connections joining the spray tank
and pumps with the wing and aft spray booms.
In hot weather, the odor of
herbicide within the aircraft was decidedly noticeable.
Periodically, the
spray tank and console were removed (especially with the portable A/A 45Y-1
system) and the interior flushed with surfactant or soap and with water.
Because of the corrosive nature of some herbicides, it was necessary for
the aircraft to also be repainted periodically.
18. In the 1966 through 1968
day was often co'mmon.
period, more than one sortie per
For example, during the first six months of 1968,
13
�the 24 UC-123B aircraft assigned to RANCH HAND averaged approximately 39
sorties per day.
Exposure Considerations: Applications and Environmental Parameters
There were relatively few military operations that involved the
handling of herbicides by military personnel.
A review of operations
involving Herbicide Orange in South Vietnam from January 1962 to April 1970
revealed that there were essentially three groups of military personnel
potentially
exposed
contaminant.
to
Herbicide
Orange
and
its
associated
dioxin
These three groups were:
1. "OPERATION RANCH HAND"
defoliation program.
personnel actively involved in the
This group included aircrew members and maintenance
and support personnel directly assigned to the RANCH HAND squadrons.
2.
Personnel assigned to
selected support functions that may
have resulted in exposure to Herbicide Orange.
This group included, for
example, personnel who sprayed herbicides, using helicopters or ground
application equipment; personnel who may have delivered the herbicides to
the units performing the defoliation missions; aircraft mechanics who were
specialized and occasionally provided support to RANCH HAND aircraft; or,
personnel who may have flown contaminated C-123 aircraft, but were not
assigned to RANCH HAND (e.g., during the Tet Offensive, all RANCH HAND
aircraft were reconfigured to transport supplies and equipment, and were
assigned to non-RANCH HAND squadrons).
3. Ground personnel who may have
been inadvertently sprayed by
defoliation aircraft or who, during combat operations, may have entered an
area previously sprayed with Herbicide Orange.
The total number of US military personnel exposed to Herbicide Orange
is not known.
Approximately
1,250 RANCH HAND personnel were exposed in
direct support of the defoliation operations; however, there are no data on
the number of non-RANCH HAND personnel who may have been exposed.
The
actual number of people may be in the thousands since at least 100
helicopter spray equipment units were used in South Vietnam, and most
14
�military bases had vehicle-mounted and
backpack spray units available for
use in routine vegetation control programs.
The number of military ground
personnel who may have inadvertently been sprayed with Herbicide Orange
during combat operations is not known.
Approximately 10 percent of South
Vietnam was sprayed with herbicides, and most of this area was contested
and/or controlled by enemy forces.
unpopulated and forested ( 4 .
1)
Most areas sprayed were remote,
Because of the dense canopy cover, the
target of the defoliation operation, the amount of herbicide penetrating to
the forest floor would have been small.
The exposure of personnel could
have occurred by essentially three routes:
1.
Percutaneous absorption and inhalation of vapors/aerosols by direct
exposure to sprays.
2. Percutaneous absoprtion and inhalation of
vapors by exposure to
treated areas following spray application, and
3.
Ingestion of foods contaminated with the material.
The chemical and physical characteristics of Herbicide Orange and the
spray, as it would have occurred following dissemination from a C-123, are
important factors in assessing relative exposure to the herbicides and TCDD.
Table 7 reviews the pertinent chemical and physical characteristics of
Herbicide Orange.
Table 8 reviews both the application parameters of the
spray system used in the UC-123K aircraft and the characteristics of the
spray itself.
Generally, herbicides were sprayed in the early morning or
late afternoon, so as to minimize the effects of air movement on particle
dispersion.
15
�TABLE 7 - PERf INENT CHEMICAL AND PHYSICAL
CHARACTERISTICS OF HERBICIDE ORANGE+
Formulation Concentrated
1 Kg ai/liter*
Water Insoluble
Density - 1.28
Vapor Pressure
3.6 x 10"4 mm Hg at 30 °C
NBE** 2,4-D
:
1.2 x 10"4
NBE 2,4,5-T
:
0.4 x 1 '
04
TCDD
:
4.68x 10"7
Viscous
40 centipoises at 20°C
Noncorrosive to metal
Deleterious to paints, rubber, neoprene
Long Shelf life
+Source:Young et al, (15,16)
*Kilograms active ingredient (2,4-D and 2,4,5-T) per liter.
**NBE - Normal Butyl ester.
TABLE 8 - APPLICATION PARAMETERS AND SPRAY
CHARACTERISTICS OF THE C-123 MODULAR INTERNAL SPRAY SYSTEM
Aircraft speed
130 KIAS*
Aircraft altitude
50 m
Tank volume
3,785 liters
Spray time
3.5-4 minutes
Particle size:
100 microns:
1.9%
100-500 microns:
500 microns:
76.2%
21.9%
87% impacted within 1 minute
13% drifted or volatilized
Mean particle volume
0.61 microliters
Spray swath
80+6 meters
Mean deposition
28 liters/hectare
Total area/tank
130 hectares
Source: Darrow et al, (8) and Harrigan
*Knots indicated air speed
16
(10)
�Ground combat forces normally would not have been expected to have
entered a previously treated area for several weeks after treatment, during
which time numerous environmental factors would have reduced the potential
for exposure to military personnel.
An indepth review of the environmental
fate of Herbicide Orange and TCDD concluded that the vast majority of the
phenoxy herbicides
(15).
would have impacted forest
canopy, the
intended target
The proposed scenario was as follows:
Rapid uptake (e.g., within a few hours) of the ester formulations
of 2,4-D and 2,4,5-T would have occurred following aerial application.
Most
of the herbicide probably would have undergone rapid degradation (weeks)
within
the cellular
matrix
of
the vegetation.
However,
some of the
herbicide may have remained uniaetabolized and would have been deposited on
the forest floor at the time of leaf fall.
action would
Soil microbial and/or chemical
likely have completed the degradation process.
Herbicide
droplets that impacted directly on soil or water would have hydrolyzed
rapidly (within hours).
Biological and nonbiological degradative processes
would have further occurred to significantly reduce these residues.
Some
volatilization of the esters of 2,4-D and 2,4,5-T would have occurred during
and immediately after application.
The volatile material most likely would
have dissipated within the foliage of the target area.
Photodecomposition
of TCDD would have minimized the amount of biologically active volatile
residues moving downwind of the target area.
Accumulation of phenoxy herbicides in animals may have occurred
following
ingestion
of
treated
vegetation.
The
magnitude
of
this
accumulation would have rapidly declined after withdrawal from treated feed.
Most
TCDD
sprayed
into
the
environment
during
defoliation
operations would have probably photodegraded within 24 hours of application.
The TCDD that escaped photodegradation would probably have entered the soilorganic complex on the forest floor following leaf fall.
processes would
residues.
have
further
reduced
the bioavailability
Soil chemical
of
the TCDD
Bioconcentration of the remaining minute levels of TCDD may have
17
�occurred in liver and fat of animals ingesting contaminated vegetation or
soil.
However, there are no field data available that indicate that the
levels of TCDD likely to have accumulated in these animals would have had a
biological effect.
Report on Exposure Assessment by the Agent Orange Working Group
In 1981, the President of the United States established the White House
Agent Orange Working Group (AOWG).
While the AOWG does not conduct any
research, it is charged with being the overall coordinator, clearinghouse,
and evaluator of the Federal research effort.
In January 1986, the AOWG
directed its Science Panel (a panel of senior scientists from ten Federal
agencies)
Orange
to review pertinent
and/or
information
its associated dioxin,
on veteran exposure
to Agent
to examine additional pilot
data
developed by the U.S. Army and Joint Services Environmental Support Group,
and to evaluate the feasibility
of a scientifically valid epidemiologic
study where the cohorts were selected on the basis of military records.
The
conclusions of the AOWG Science Panel were reported (16), and are quoted
below:
The Science Panel concluded that the U.S. Army's Environmental
Support Group has sought and obtained all military records
pertinent to the use of herbicides in Vietnam. The environmental
Support Group staff is trained and qualified to have expertly
reviewed and abstracted the records appropriate to exposure
assessment.
From a thorough review of these military records, it appears that
considerable misclassification of the individual's exposure status
is possible; i.e., we found no way, based on military records, to
verify an individual's exposure to herbicide or dioxin.
Two
issues were specifically recognized as influencing the degree of
misclassification:
a.
Unit Dispersion - On a substantial number of days,
personnel in combat units eligible for the Agent Orange Study were
not located together as a unit, rather they were dispersed
geographically up to 20 kilometers on the same day.
b.
Incomplete Records - The most complete records for
herbicide applications in Vietnam are the "HERBS TAPES," records
of the missions of OPERATION RANCH HAND. These tapes, originally
computerized by the National Academy of Sciences in the early
1970s, were 'supplemented recently by the SERVICES HERBS TAPES
which provide additional data on perimeter applications (including
18
�helicopter and ground application missions).
Expert opinion
suggested that an unknown, but apparently large proportion of
firebase perimeter spray operations were never recorded.
The
degree to which these "unrecorded" operations may have influenced
exposure is unknown.
After extensive review of military records during the past two
years, it was apparent that the majority of veterans had never
been within two kilometers of a sprayed area within a week of
herbicide application. Additional pilot data reviewed at this
time confirmed this finding, and the paucity of clearly exposed
combat veterans makes it questionable whether a sufficient number
can be assembled to conduct an epidemiological study of the type
originally designed.
It is clear from the available data that health studies designed
to assess the effects of Agent Orange and its associated dioxin
can be done on more appropriate populations than those identified
through military records; e.g., industrial workers and commercial
herbicide applicators.
Recent advances in analytical chemistry may make it feasible to
identify chemical (e.g., 2,3,7,8-TCDD) or biological (DNA adducts)
markers that will permit a more reliable exposure assessment.
RECOMMENDATION: This Science Panel recommends that any study of
ground troops, which is dependent upon military records for the
assessment of exposure to herbicides, not be conducted without an
additional method to verify exposure.
Conclusions
The documentation on the use of herbicides in the military conflict in
Southeast Asia from 1962 through 1971 is extensive.
Nevertheless, the
records were never intended to serve as the basis for health studies or
litigation activities.
Health studies of the effects of the phenoxy
herbicides are difficult enough under conditions of normal agricultural
use, but they become more complex when conducted with cohorts briefly
exposed more than two decades ago under conditions of war in a tropical
environment.
19
�References
1. Brown, J.W. 1962. Vegetational spray tests in South Vietnam. U.S.
Army Chemical Corps Biological Laboratories, Fort Detrick, Frederick,
Maryland. 119 p. Available from the defense Documentation Center,
Defense Logistics Agency, Cameron Station, Alexandria, Virginia, DDC
Number AD 476961.
2.
Buckingham, W.A. Jr 1982. Operation Ranchhand: The Air Force and
Herbicides in Southeast Asia, 1961-1971. Office of Air Force History,
Washington, D.C. 253 p.
3.
Cecil, P.F. 1984. The Air Force Ranch Hand Project in Southeast Asia:
Operations and Consequences.
Ph.D. Dissertation, Texas A&M
University, College Station, Texas. 327 p.
4. Coates, J.H., L.M. Sharpe, and H. Pollack. 1962. The Present Status
of Chemical Control of Vegetation in Relation to Military Needs.
Technical Notes 62-68. Institute for Defense Analyses, Department of
Defense, Washington, D.C. 30 p.
5.
Committee on the Effects of Herbicides in South Vietnam. 1974. Part
A. Summary and conclusions. National Academy of Science, Washington,
D.C. 398 p.
6.
Craig, D.A. 1975. Use of Herbicides in Southeast Asia. Historical
Report.
San Antonio Air Logistics Center, Directorate of Energy
Management, Kelly AFB, Texas. 58 p.
7. Darrow, R.A., K.R. Irish, and C.E. Minarik. 1969. Herbicides Used in
Southeast Asia. Technical Report SAOQ-TR-69-11078. Directorate of
Air Force Aerospace Fuels, Kelly AFB, Texas. 60 p.
8.
Darrow, R.A., G.B. Truchelut, and C.M. Bartlett.
1966.
OCONUS
Defoliation Test Program. Technical Report 79. Crops Department,
Biological Sciences Laboratory, U.S. Army Biological Center, Fort
-Detrick, Frederick, Maryland. 126 p.
9.
Fox, Roger P. 1979. Air Base Defense in the Republic of Vietnam,
1961-1973. Office of Air Force History, Washington, D.C., pp 55-78.
10. Harrigan, E.T. 1970. Calibration Test of the UC-123K/A/A45Y-1 Spray
System.
Technical Report ADTC-TR-70-36. Armament Development and
Test Center, Eglin AFB, Florida. 160 p.
11. Huddle, F.P. 1969. A Technology Assessment of the Vietnam Defoliant
Matter - A Case History.
Report to the Subcommittee on Science
Research and Development of the Committee on Science and Astronautics.
U.S. House of Representatives, Ninety-first Congress. Prepared by the
Science Policy Research Division, Legislative Reference Service,
Library of Congress, Washington, D.C. 73 p.
12. Irish, K.R., R.A. Darrow and C.E. Minarik. 1969. Information Manual
for Vegetation Control in Southeast Asia.
Miscl. Public. 33.
Department of the Army, Fort Detrick, Frederick, Maryland. 71 p.
13. Peterson, G.E. 1967.
Hist. 41:243-253.
The discovery and development of 2,4-D.
Agr.
14. Tschirley, F.H.
1969.
Defoliation in Vietnam
- The ecological
consequences of the defoliation program in Vietnam are assessed.
Science 163:779-786.
20
�15.
Young, A.L., J.A. Calcagni, C.E. Thalken and J.W. Tremblay.
1978.
The toxicology, environmental fate, and human risk of Herbicide Orange
and its associated dioxin.
Technical Report OEHL-TR-78-92.
USAF
Occupational and Environmental Health Laboratory, Brooks AFB, Texas.
247 p.
Available from National Technical Information Center,
Springfield, Virginia.
16.
Young, A.L. (Chairman), 1986.
Report of the Agent Orange Work Group
Science Subpanel on Exposure Assessment. Domestic Policy Council Agent
Orange Work Group, Department of Health and Human Services, Washington,
DC, 350 p.
21
�LIST OF FIGURES
Figure 1.
The 1974 National Academy of Sciences Computerized
Map of Vietnam Showing Defoliation Missions, 19651971.
Figure 2.
A 1972 Map of South Vietnam Showing Provinces and
Major Cities.
Figure 3.
Slide 1. Standard Military Transportation labelling
of a 208-liter drum of Herbicide
Figure 4.
Slide 2. Agent Orange was procurred from eight different chemical companies and was shipped by railroad
from the manufacturer to the ports at Mobile or Gulfport,
Mississippi.
Figure 5.
Slide 3. Generally, it took 50 days for the herbicide
to be shipped by sea from the United States to the ports
at Saigon or DaNang, Republic of Vietnam. Orange II,
produced in the late 1960's contained the isoctyl ester
of 2,4,5-T in place of the n-butyl ester.
Figure 6.
Slide 4. At the docks in Vietnam, the herbicide drums
were transferred to military cargo trailers for transport to the RANCH HAND Squadrons.
Figure 7.
Slide 5. Normally the contents of the drums were transferred to holding tanks (F-6 trailers or other storage
tanks) or transferred directly to the aircraft.
Figure 8.
Slide 6. Typically, 3-5 liters of herbicide remained
in the drums after pumping. This was recovered through
the use of drain tanks. The residual herbicide was
frequently sprayed aroung base perimeters.
Figure 9.
Slide 7. Empty drums were frequently discarded to a
"drum dump" until disposal was accomplished. The dump
at Bien Hoa, 1968, is shown in the photograph.
Figure 10. Slide 8. Although most empty drums were destroyed and
used in the construction of runways and bunkers, it was
not uncommon to see drums used for other purposes. The
photograph shows the construction of a portable shower
made from 208-L drums.
Figure 11. Slide 9. The "work horse" of Operation RANCH HAND was
the C-123 aircraft. The photograph is of "Patches" an
aircraft that survived hundreds of herbicide or insecticide missions during its seven years of service during
in Vietnam.
�-2Figure 12. Slide 10. The A/A 45Y-1 Internal Defoliant Dispenser
was a moduler spray system for internal carriage in
the C-123 aircraft. The module consisted of a 3.785liter tank, pump, and engine mounted on a frame pallet.
An operator's console was an integral part of the unit
but was not mounted on the pallet.
Figure 13. Slide 11. The RANCH HAND C-123 aircraft had spray booms
mounted under each wing and behind the cargo door. Each
wing boom was 6.5m in length and mounted with 16 nozzles.
Figure 14. Slide 12. A typical RANCH HAND Crew consisted of a pilot
and Co-pilot (officers) and a flight mechanic (enlisted)
who served as a console operator for the spray unit.
Figure 15. Slide 13.
aircraft.
A typical RANCH HAND mission consisted of 3-5
Figure 16. Slide 14. RANCH HAND Aircraft timed the arrival of the
aircraft at a target site just prior to sunrise, thus,
permitting the aircraft to approach the target from the
direction of the rising sun. This afforded some degree
of protection from enemy ground fire.
Figure 17. Slide 15. Defoliation missions along canals and roadways
wre common targets. The photograph shows a defoliated
area associated with a canal.
Figure 18. Slide 16. The inland forests of Vietnam were defoliation
mission targets aimed at dislocating enemy forces. This
"swath" was defoliated by at least a five-aircraft
formation spraying a distance of almost 13 Km. The
herbicides of choice for such an operation were either
White or Orange.
Figure 19. Slide 17. The U.S. Army's UH-1 helicopter was ideal for
base perimeter spraying of herbicides.
Figure 20. Slide 18. The typical spray system for helicopters consisted of a 750-liter tank, spray boom and windmill pump.
Figure 21. Slide 19. Helicopter spraying Agent Blue on the tall
elephant grass on a base perimeter.
Figure 22. Slide 20. Military personnel in a area defoliated by
herbicides. Typically, personnel did not enter a
defoliated area until the effects of defoliation were
apparent and visibility within the area was significantly
enhanced.
�
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
017
Folder
The folder containing the original item.
0191
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Creator
An entity primarily responsible for making the resource
Young, Alvin L.
Title
A name given to the resource
Manuscript: Chapter 2: The Military Use of Herbicides in Vietnam, "Massive Quantities of Herbicides Were Applied by the United States in a Tactical Operation Designed to Reduce Ambushes and Disrupt Enemy Tactics"
Subject
The topic of the resource
Ranch Hand
herbicide application
dioxin
-
https://www.nal.usda.gov/exhibits/speccoll/files/original/ff92de4f031d81dace41f7b0f7a8f3cb.pdf
7f711b5c03c46f1803ca57f02fc2d6b7
PDF Text
Text
Item ID Number
00231
Author
Sholdt, L Lance
Corporate Author
Nav
V Disease Vector Ecology and Control Center, Jacks
Report/Article Title Memorandum: Pesticide Usage by Seabee and Marine
Corps Units in RVN, from L. Lance Sholdt to R.V.
Peterson, 26 July 1972
Journal/Book Title
Year
000
°
Month/Day
Color
Number of Images
n
'
Descripton Notes
Monday, January 22, 2001
Page 243 of 341
�NAVY DISEASE VECTOR ECOLOGY
AND
CONTROL CENTER
BOX
43
' N A V A l - AIR STATION
J A C K S O N V I L L E , FLORIDA 32212
TEL
'
9
°'*-772-2424
A U T O V O N 942-2424
IN REPLY REFER TO:
DVECC:01:fm
6250
26 July 1979
From:
To:
Officer in Charge
CDR R. V. Peterson, MSC, USN, Disease Vector Control Section (MED 31412),
Bureau of Medicine and Surgery, Washington, DC 20372
Subj : Pesticide usage by Seabee and Marine Corps units in RVN
1. The following information is provided regarding telephone communications
with Seabee personnel regarding pesticide usage in RVN; specifically Agent
Orange (AO) :
a. 20 July 1979, CDR Davis, Chief of Staff, 351 NCR, SEABEEPAC, Port
Kuenetae (360-5641). No records of pesticides used; no personal knowledge
of AO being used by Seabees in RVN.
b. 21 July 1979, UTCM Carrol E. Simmons (Code 09M12A) , Staff Assistant
for Plans, Policy and Training, SEABEES at NAVFAC headquarters (221-8545).
No records of pesticides used in RVN. No personal knowledge of AO being used
in RVN.
c. 23 July 1979, YM1 Cope, Chief of Staff Office, 20th NCR, Gulfport
(794-2650). No records of pesticides used with RVN.
d. 23 July 1979, LCDR Howard Holcomb, QIC, Navy Dispensary, Gulfport
(363-2806). USAF stored AO in Gulfport during post RVN. No personal knowledge
of AO being used in RVN.
e. 23 July 1979, CDR McCallister, CO, Supply Center, Gulfport (363-2204).
No records kept on types and amounts of pesticides used in RVN by Seabee units.
No personal knowledge of AO being used (or 2,4,5-T).
f. 25 July 1979, CDR McCallister (return call). Checked with civil engineering support office, inventory control, at Port Hueneme where master records
are stored. Ho information kept or available on types or amounts of pesticides
and herbicides supplied to or used by Seabee units in RVN.
2. LCDR Tim Dickens reported that he had no knowledge of AO or of herbiciding
compounds containing Dioxin being used by Marine Corps units during his tour
in RVN. He was also unaware of any records being kept on the types and amounts
of pesticides applied by USMC units in RVN. I can report the same from my own
personal experience in RVN.
L. TANCE SHOLDT
�
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Title
A name given to the resource
Alvin L. Young Collection on Agent Orange
Description
An account of the resource
<p style="margin-top: -1em; line-height: 1.2em;">The Alvin L. Young Collection on Agent Orange comprises 120 linear feet and spans the late 1800s to 2005; however, the bulk of the coverage is from the 1960s to the 1980s and there are many undated items. The collection was donated to Special Collections of the National Agricultural Library in 1985 by Dr. Alvin L. Young (1942- ). Dr. Young developed the collection as he conducted extensive research on the military defoliant Agent Orange. The collection is in good condition and includes letters, memoranda, books, reports, press releases, journal and newspaper clippings, field logs and notebooks, newsletters, maps, booklets and pamphlets, photographs, memorabilia, and audiotapes of an interview with Dr. Young.</p>
<p>For more about this collection, <a href="/exhibits/speccoll/exhibits/show/alvin-l--young-collection-on-a">view the Agent Orange Exhibit.</a></p>
Text
A resource consisting primarily of words for reading. Examples include books, letters, dissertations, poems, newspapers, articles, archives of mailing lists. Note that facsimiles or images of texts are still of the genre Text.
Box
The box containing the original item.
019
Folder
The folder containing the original item.
0231
Series
The series number of the original item.
Series II
Dublin Core
The Dublin Core metadata element set is common to all Omeka records, including items, files, and collections. For more information see, http://dublincore.org/documents/dces/.
Creator
An entity primarily responsible for making the resource
Sholdt, L. Lance
Description
An account of the resource
<strong>Corporate Author: </strong>Navy Disease Vector Ecology and Control Center, Jacksonville, Florida
Title
A name given to the resource
Memorandum: Pesticide Usage by Seabee and Marine Corps Units in RVN, from L. Lance Sholdt to R.V. Peterson, 26 July 1972
Subject
The topic of the resource
pesticide application
herbicide application