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1
1
DCTM_
ARP.
xls
;
placeholder01
page
1
of
48
6/
29/
2006
species
stagege.
sequencesurvival.
bystage.
fraction
nat.
mort.
m
fish.
mort.
fn.
vulnerable
notes.
survivaltes.
nat.
mort
notes.
fish.
mort
nerable
dummy
dummy
­
999
­
999
­
999
­
999
­
999
dummy
dummy
dummydummy
bay.
anchovy.
gulf
egg
1
0.14370395
1.94
0
0ing
Se
=
exp
(­(
m+
f))
[
26554]
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
bay.
anchovy.
gulf
prolarvae
2
0.20887903
1.566
0
0ing
Se
=
exp
(­(
m+
f))
];
appendix
LBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
bay.
anchovy.
gulf
postlarvae
3
0.002198456
6.12
0
0ing
Se
=
exp
(­(
m+
f))
];
appendix
LBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
bay.
anchovy.
gulf
juv
4
0.274734528
1.292
0
0dix
F,
Attachment
F.
exp
(­(
m+
f))
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
bay.
anchovy.
gulf
age01
5
0.197059414
1.62425
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
bay.
anchovy.
gulf
age02
6
0.197059414
1.62425
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
bay.
anchovy.
gulf
age03
7
0.197059414
1.62425
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
blue.
crab.
gulf
zoeae
1
0.000001
13.816
0
0
2
for
zoae
and
juv1
exp
(­(
m+
f))
hment
12;
Table
10­
2/
Cheasapeake
Bay
mean,
1999
blue.
crab.
gulf
megalops
2
0.273837066
1.295
0
0f
"
Survival
(
per
mm)"
exp
(­(
m+
f))
hment
12;
Table
10­
2/
Cheasapeake
Bay
mean,
1999
blue.
crab.
gulf
juv1
3
0.110208858
1.725
0.48
0.5f
"
Survival
(
per
mm)"
exp
(­(
m+
f))
hment
12;
Table
10­
2/
Cheasapeake
Bay
mean,
1999
blue.
crab.
gulf
age01
4
0.13533528
1
1
1th.
increment^
0.9656
=
exp
(­
m+
f)
target
level
of
fishing
mortality.
P24
[
27982],
1999
blue.
crab.
gulf
age02
5
0.13533528
1
1
1th.
increment^
0.9656
=
exp
(­
m+
f)
target
level
of
fishing
mortality.
P24
[
27982],
1999
blue.
crab.
gulf
age03
6
0.13533528
1
1
1th.
increment^
0.9656
=
exp
(­
m+
f)
target
level
of
fishing
mortality.
P24
[
27982],
1999
pink.
shrimp
egg
1
0.04
3.218875825
0
0
[
21805].
Pg.
5.2­
8
exp
(­(
m+
f))
Bielsa
et
al.,
1983.
.,
1983.
pink.
shrimp
prolarvae
2
0.182683524
1.7
0
0ing
Se
=
exp
(­(
m+
f))
s
postlarvae)
Bielsa
et
al.,
1983.
.,
1983.
pink.
shrimp
postlarvae
3
0.182683524
1.7
0
0ing
Se
=
exp
(­(
m+
f))
s
postlarvae)
Bielsa
et
al.,
1983.
.,
1983.
pink.
shrimp
juv
4
0.755783741
0.14
0.14
1ing
Se
=
exp
(­(
m+
f))
was
fishing.)
r
fishing
mortality
and
50%
of
total
was
fishing.)
.,
1983.
pink.
shrimp
age01
5
0.755783741
0.14
0.14
1ing
Se
=
exp
(­(
m+
f))
was
fishing.)
r
fishing
mortality
and
50%
of
total
was
fishing.)
.,
1983.
pink.
shrimp2
egg
1
0.04
3.218875825
0
0
[
21805].
Pg.
5.2­
8
exp
(­(
m+
f))
Bielsa
et
al.,
1983.
.,
1983.
pink.
shrimp2
larvae
2
0.03337327
3.4
0
0ing
Se
=
exp
(­(
m+
f))
s
postlarvae)
Bielsa
et
al.,
1983.
.,
1983.
pink.
shrimp2
juv
3
0.755783741
0.14
0.14
1ing
Se
=
exp
(­(
m+
f))
was
fishing.)
r
fishing
mortality
and
50%
of
total
was
fishing.)
.,
1983.
pink.
shrimp2
age01
4
0.755783741
0.14
0.14
1ing
Se
=
exp
(­(
m+
f))
was
fishing.)
r
fishing
mortality
and
50%
of
total
was
fishing.)
.,
1983.
silver.
perch.
gulf
egg
1
0.063696542
2.753625
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
F6
email:
mike.
murphy@
fwc.
state.
fl.
us);
1/
23/
02on
size.
silver.
perch.
gulf
prolarvae
2
0.122701586
2.098
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
F6
email:
mike.
murphy@
fwc.
state.
fl.
us);
1/
23/
02on
size.
silver.
perch.
gulf
postlarvae
3
0.037897126
3.27288
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
F6
email:
mike.
murphy@
fwc.
state.
fl.
us);
1/
23/
02on
size.
silver.
perch.
gulf
juv
4
0.181463817
1.706699
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
F6
email:
mike.
murphy@
fwc.
state.
fl.
us);
1/
23/
02on
size.
silver.
perch.
gulf
age01
5
0.021493601
3.84
0
0ing
Se
=
exp
(­(
m+
f))
01.
(
Growth)
6
email:
mike.
murphy@
fwc.
state.
fl.
us);
1/
23/
02on
size.
silver.
perch.
gulf
age02
6
0.019448215
3.84
0.1
0.5ing
Se
=
exp
(­(
m+
f))
01.
(
Growth)
6
email:
mike.
murphy@
fwc.
state.
fl.
us);
1/
23/
02on
size.
silver.
perch.
gulf
age03
7
0.019448215
3.84
0.1
1ing
Se
=
exp
(­(
m+
f))
01.
(
Growth)
6
email:
mike.
murphy@
fwc.
state.
fl.
us);
1/
23/
02on
size.
black.
drum
egg
1
0.10331218
2.27
0
0ing
Se
=
exp
(­(
m+
f))
med
10
daysBased
on
fishery
landings
data
(
NOAA,
2003).
rposes)
black.
drum
prolarvae
2
0.046677175
3.0645
0
0ing
Se
=
exp
(­(
m+
f))
med
27daysBased
on
fishery
landings
data
(
NOAA,
2003).
rposes)
black.
drum
postlarvae
3
0.046677175
3.0645
0
0ing
Se
=
exp
(­(
m+
f))
med
27daysBased
on
fishery
landings
data
(
NOAA,
2003).
rposes)
black.
drum
juv
4
0.273077402
1.148
0.15
0.5ing
Se
=
exp
(­(
m+
f))
and
fish
mort
p­
a.
pdf;
divided
between
nat.
mort
and
fish
mort
rposes)
black.
drum
age01
5
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age02
6
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age03
7
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age04
8
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age05
9
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age06
10
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age07
11
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age08
12
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age09
13
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age10
14
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age11
15
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age12
16
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age13
17
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age14
18
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age15
19
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age16
20
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age17
21
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age18
22
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age19
23
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age20
24
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age21
25
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age22
26
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age23
27
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age24
28
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age25
29
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age26
30
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age27
31
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age28
32
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age29
33
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age30
34
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age31
35
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age32
36
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age33
37
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age34
38
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age35
39
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age36
40
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age37
41
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age38
42
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age39
43
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum
age40
44
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
pinfish
egg
1
0.1
2.302585093
0
0
assumed
by
AGreted
by
AGret
Assumed
by
A.
Gage.
ssumed
pinfish
larvae
2
0.000614573
7.394583055
0
0
see
output
file
exp
(­(
m+
f))
Assumed
by
A.
Gage.
ssumed
pinfish
juv
3
0.14793238
1.911
0
0ing
Se
=
exp
(­(
m+
f))
=
31,
jun=
30)
Assumed
by
A.
Gage.
ssumed
pinfish
age01
4
0.506616992
0.34
0.34
0.5ing
Se
=
exp
(­(
m+
f))
f
fish
half
nat
Assumed
to
be
equal
to
natural
mortality
ssumed
pinfish
age02
5
0.506616992
0.34
0.34
1ing
Se
=
exp
(­(
m+
f))
f
fish
half
nat
Assumed
to
be
equal
to
natural
mortality
ssumed
stone.
crab
stage.
1
1
0.1389495
1.973644721
0
0om
Lindberg,
1984))
exp
(­(
m+
f))
nal
Park,
Florida.
Bull.
Mar.
Sci.
46(
2):
311­
323.
vesting.
stone.
crab
stage.
2
2
0.1389495
1.973644721
0
0om
Lindberg,
1984))
exp
(­(
m+
f))
nal
Park,
Florida.
Bull.
Mar.
Sci.
46(
2):
311­
323.
vesting.
stone.
crab
stage.
3
3
0.1389495
1.973644721
0
0om
Lindberg,
1984))
exp
(­(
m+
f))
nal
Park,
Florida.
Bull.
Mar.
Sci.
46(
2):
311­
323.
vesting.
stone.
crab
stage.
4
4
0.1389495
1.973644721
0
0om
Lindberg,
1984))
exp
(­(
m+
f))
nal
Park,
Florida.
Bull.
Mar.
Sci.
46(
2):
311­
323.
vesting.
stone.
crab
stage.
5
5
0.1389495
1.973644721
0
0om
Lindberg,
1984))
exp
(­(
m+
f))
nal
Park,
Florida.
Bull.
Mar.
Sci.
46(
2):
311­
323.
vesting.
stone.
crab
megalops
6
0.1389495
1.973644721
0
0om
Lindberg,
1984))
exp
(­(
m+
f))
nal
Park,
Florida.
Bull.
Mar.
Sci.
46(
2):
311­
323.
vesting.
stone.
crab
juv
7
0.1389495
1.973644721
0
0om
Lindberg,
1984))
exp
(­(
m+
f))
nal
Park,
Florida.
Bull.
Mar.
Sci.
46(
2):
311­
323.
vesting.
stone.
crab
age01
8
0.184519524
0.939
0.751
0.5ing
Se
=
exp
(­(
m+
f))
(
2):
311­
323.
nal
Park,
Florida.
Bull.
Mar.
Sci.
46(
2):
311­
323.
vesting.
stone.
crab
age02
9
0.184519524
0.939
0.751
1ing
Se
=
exp
(­(
m+
f))
(
2):
311­
323.
nal
Park,
Florida.
Bull.
Mar.
Sci.
46(
2):
311­
323.
vesting.
stone.
crab
age03
10
0.184519524
0.939
0.751
1ing
Se
=
exp
(­(
m+
f))
(
2):
311­
323.
nal
Park,
Florida.
Bull.
Mar.
Sci.
46(
2):
311­
323.
vesting.
stone.
crab
age04
11
0.184519524
0.939
0.751
1ing
Se
=
exp
(­(
m+
f))
(
2):
311­
323.
nal
Park,
Florida.
Bull.
Mar.
Sci.
46(
2):
311­
323.
vesting.
scaled.
sardine
egg
1
0.12
2.120263536
0
0
lower
survival
rate.)
exp
(­(
m+
f))
Based
on
fishery
landings
data
(
NOAA,
2003).
ssumed
scaled.
sardine
prolarvae
2
0.571209064
0.56
0
0ing
Se
=
exp
(­(
m+
f))
=
2d
[
21805]
Based
on
fishery
landings
data
(
NOAA,
2003).
ssumed
scaled.
sardine
postlarvae
3
0.003647515
6.53
0
0ing
Se
=
exp
(­(
m+
f))
see
outputBased
on
fishery
landings
data
(
NOAA,
2003).
ssumed
scaled.
sardine
juvenile
4
0.4
0.916290732
0
0ssumed
(
D.
Cacela)
exp
(­(
m+
f))
Based
on
fishery
landings
data
(
NOAA,
2003).
ssumed
scaled.
sardine
age01
5
0.36059494
1.02
0
0ing
Se
=
exp
(­(
m+
f))
g.
Key
facts.
Based
on
fishery
landings
data
(
NOAA,
2003).
ssumed
spotted.
seatrout
egg
1
0.1
2.302585093
0
0
[
21805];
p.
7.2­
20
exp
(­(
m+
f))
Assumed
by
A.
Gage.
ssumed
spotted.
seatrout
prolarvae
2
0.22313016
1.5
0
0ing
Se
=
exp
(­(
m+
f))
d
on
[
21805]
01
in
Norhteast
and
F0.1
from
Murphy's
e­
mail
inches.
spotted.
seatrout
postlarvae
3
0.000985462
6.9224
0
0ing
Se
=
exp
(­(
m+
f))
see
output01
in
Norhteast
and
F0.1
from
Murphy's
e­
mail
inches.
spotted.
seatrout
juv
4
0.58
0.2724
0.2724
0.5thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout
age01
5
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout
age02
6
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout
age03
7
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout
age04
8
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout
age05
9
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout
age06
10
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout
age07
11
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout
age08
12
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
tidewater.
silverside
egg
1
0.10000000
2.302585093
0
0f
10
becomes
larva)
exp
(­(
m+
f))
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
tidewater.
silverside
prolarvae
2
0.23398700
1.452489721
0
0
pro
and
postlarvae)
exp
(­(
m+
f))
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
tidewater.
silverside
postlarvae
3
0.23398700
1.452489721
0
0
pro
and
postlarvae)
exp
(­(
m+
f))
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
tidewater.
silverside
juvenile
4
0.40000000
0.916290732
0
0ssumed
(
D.
Cacela)
exp
(­(
m+
f))
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
tidewater.
silverside
age01
5
0.122456428
2.1
0
0ing
Se
=
exp
(­(
m+
f))
.
1694.
41
p.
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
tidewater.
silverside
age02
6
0.122456428
2.1
0
0ing
Se
=
exp
(­(
m+
f))
.
1694.
41
p.
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
hogchoker
egg
1
0.106
2.244316185
0
0p.
I.
34/
BMt.
Hope
Bay
exp
(­(
m+
f))
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
hogchoker
larvae
2
0.00119
6.73079203
0
0
see
output
file
exp
(­(
m+
f))
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
hogchoker
juvenile
3
0.40000
0.916290732
0
0ssumed
(
D.
Cacela)
exp
(­(
m+
f))
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
hogchoker
age01
4
0.778800783
0.25
0
0ing
Se
=
exp
(­(
m+
f))
fish,
half
nat.
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
hogchoker
age02
5
0.778800783
0.25
0
0ing
Se
=
exp
(­(
m+
f))
fish,
half
nat.
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
hogchoker
age03
6
0.778800783
0.25
0
0ing
Se
=
exp
(­(
m+
f))
fish,
half
nat.
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
hogchoker
age04
7
0.778800783
0.25
0
0ing
Se
=
exp
(­(
m+
f))
fish,
half
nat.
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
hogchoker
age05
8
0.778800783
0.25
0
0ing
Se
=
exp
(­(
m+
f))
fish,
half
nat.
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
hogchoker
age06
9
0.778800783
0.25
0
0ing
Se
=
exp
(­(
m+
f))
fish,
half
nat.
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
menhaden.
spp
egg
1
0.12500000
2.079441542
0
0
p.
66/
Pilgrim
station
exp
(­(
m+
f))
rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
menhaden.
spp
larvae
2
0.00331649
5.708847403
0
0
provided
by
Entergy
exp
(­(
m+
f))
rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
menhaden.
spp
juv
3
0.05758900
2.854423702
0
0
provided
by
Entergy
exp
(­(
m+
f))
rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
menhaden.
spp
age01
4
0.637628152
0.45
0
0ing
Se
=
exp
(­(
m+
f))
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
menhaden.
spp
age02
5
0.286504797
0.45
0.8
0.5ing
Se
=
exp
(­(
m+
f))
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
menhaden.
spp
age03
6
0.286504797
0.45
0.8
1ing
Se
=
exp
(­(
m+
f))
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
menhaden.
spp
age04
7
0.286504797
0.45
0.8
1ing
Se
=
exp
(­(
m+
f))
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
menhaden.
spp
age05
8
0.286504797
0.45
0.8
1ing
Se
=
exp
(­(
m+
f))
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
menhaden.
spp
age06
9
0.286504797
0.45
0.8
1ing
Se
=
exp
(­(
m+
f))
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
chain.
pipefish
egg
1
0.10000000
2.302585093
0
0f
10
becomes
larva)
exp
(­(
m+
f))
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
chain.
pipefish
larvae
2
0.09113
2.395519779
0
0
output
fileSeabrook
exp
(­(
m+
f))
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
chain.
pipefish
juvenile
3
0.40000
0.916290732
0
0ssumed
(
D.
Cacela)
exp
(­(
m+
f))
Assumed
by
A.
Gage.
ssumed
chain.
pipefish
age01
4
0.47236655
0.75
0
0sing
Se
=
exp
(­
m+
f)
00/
Baltic
seaBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
chain.
pipefish
age02
5
0.472366553
0.75
0
0ing
Se
=
exp
(­(
m+
f))
00/
Baltic
seaBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
chain.
pipefish
age03
6
0.472366553
0.75
0
0ing
Se
=
exp
(­(
m+
f))
00/
Baltic
seaBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
chain.
pipefish
age04
7
0.472366553
0.75
0
0ing
Se
=
exp
(­(
m+
f))
00/
Baltic
seaBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
chain.
pipefish
age05
8
0.472366553
0.75
0
0ing
Se
=
exp
(­(
m+
f))
00/
Baltic
seaBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
searobin.
gulf
egg
1
0.1000
2.3026
0
0
assumed
by
AGret
exp
(­(
m+
f))
Based
on
hake
Saila
et
al.,
1997y
Agret
searobin.
gulf
larvae
2
0.0258
3.6570
0
0
by
juv
survival
(
0.4).
exp
(­(
m+
f))
Based
on
hake
Saila
et
al.,
1997l.,
1997
searobin.
gulf
juvenile
3
0.4000
0.9163
0
0ssumed
(
D.
Cacela)
exp
(­(
m+
f))
Based
on
hake
Saila
et
al.,
1997l.,
1997
searobin.
gulf
age01
4
0.5945
0.4200
0.1
0.5ing
Se
=
exp
(­(
m+
f))
ne
11,
2001.
Based
on
hake
Saila
et
al.,
1997l.,
1997
searobin.
gulf
age02
5
0.5945
0.4200
0.1
1ing
Se
=
exp
(­(
m+
f))
ne
11,
2001.
Based
on
hake
Saila
et
al.,
1997l.,
1997
searobin.
gulf
age03
6
0.5945
0.4200
0.1
1ing
Se
=
exp
(­(
m+
f))
ne
11,
2001.
Based
on
hake
Saila
et
al.,
1997l.,
1997
searobin.
gulf
age04
7
0.5945
0.4200
0.1
1ing
Se
=
exp
(­(
m+
f))
ne
11,
2001.
Based
on
hake
Saila
et
al.,
1997l.,
1997
searobin.
gulf
age05
8
0.5945
0.4200
0.1
1ing
Se
=
exp
(­(
m+
f))
ne
11,
2001.
Based
on
hake
Saila
et
al.,
1997l.,
1997
searobin.
gulf
age06
9
0.5945
0.4200
0.1
1ing
Se
=
exp
(­(
m+
f))
ne
11,
2001.
Based
on
hake
Saila
et
al.,
1997l.,
1997
searobin.
gulf
age07
10
0.5945
0.4200
0.1
1ing
Se
=
exp
(­(
m+
f))
ne
11,
2001.
Based
on
hake
Saila
et
al.,
1997l.,
1997
searobin.
gulf
age08
11
0.5945
0.4200
0.1
1ing
Se
=
exp
(­(
m+
f))
ne
11,
2001.
Based
on
hake
Saila
et
al.,
1997l.,
1997
gulf.
killifish
egg
1
0.1
2.302585093
0
0f
10
becomes
larva)
exp
(­(
m+
f))
ional
d'Histoire
Naturelle,
Paris,
France,
399
p.
gulf.
killifish
larvae
2
0.05
2.995732274
0
0
egg
to
larvae
of
0.1
exp
(­(
m+
f))
ional
d'Histoire
Naturelle,
Paris,
France,
399
p.
gulf.
killifish
juvenile
3
0.4
0.916290732
0
0ssumed
(
D.
Cacela)
exp
(­(
m+
f))
ional
d'Histoire
Naturelle,
Paris,
France,
399
p.
gulf.
killifish
age01
4
0.46
0.776528789
0
0979
#
23208),
mean
exp
(­(
m+
f))
ional
d'Histoire
Naturelle,
Paris,
France,
399
p.
gulf.
killifish
age02
5
0.46
0.776528789
0
0979
#
23208),
mean
exp
(­(
m+
f))
ional
d'Histoire
Naturelle,
Paris,
France,
399
p.
gulf.
killifish
age03
6
0.46
0.776528789
0
0979
#
23208),
mean
exp
(­(
m+
f))
ional
d'Histoire
Naturelle,
Paris,
France,
399
p.
gulf.
killifish
age04
7
0.46
0.776528789
0
0979
#
23208),
mean
exp
(­(
m+
f))
ional
d'Histoire
Naturelle,
Paris,
France,
399
p.
gulf.
killifish
age05
8
0.46
0.776528789
0
0979
#
23208),
mean
exp
(­(
m+
f))
ional
d'Histoire
Naturelle,
Paris,
France,
399
p.
gulf.
killifish
age06
9
0.46
0.776528789
0
0979
#
23208),
mean
exp
(­(
m+
f))
ional
d'Histoire
Naturelle,
Paris,
France,
399
p.
gulf.
killifish
age07
10
0.46
0.776528789
0
0979
#
23208),
mean
exp
(­(
m+
f))
ional
d'Histoire
Naturelle,
Paris,
France,
399
p.
leatherjacket
egg
1
0.441811
0.816872
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
F
Assumed
by
D.
Cacela.
Cacela.
leatherjacket
larvae
2
0.000183
8.608552396
0
0ed
by
0.4
(
juv
surv).
exp
(­(
m+
f))
Assumed
by
D.
Cacela.
Cacela.
leatherjacket
juvenile
3
0.4
0.916290732
0
0ssumed
(
D.
Cacela)
exp
(­(
m+
f))
Assumed
by
D.
Cacela.
Cacela.
leatherjacket
age01
4
0.554327285
0.34
0.25
0.5ing
Se
=
exp
(­(
m+
f))
eatherjacket.
://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
Cacela)
leatherjacket
age02
5
0.554327285
0.34
0.25
1ing
Se
=
exp
(­(
m+
f))
eatherjacket.
://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
Cacela)
leatherjacket
age03
6
0.554327285
0.34
0.25
1ing
Se
=
exp
(­(
m+
f))
eatherjacket.
://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
Cacela)
leatherjacket
age04
7
0.554327285
0.34
0.25
1ing
Se
=
exp
(­(
m+
f))
eatherjacket.
://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
Cacela)
sheepshead
egg
1
0.1
2.302585093
0
0f
10
becomes
larva)
exp
(­(
m+
f))
Assumed
by
A.
Gage.
[
27982]
sheepshead
larvae
2
0.000614573
7.394583055
0
0
see
output
file
exp
(­(
m+
f))
Assumed
by
A.
Gage.
[
27982]
sheepshead
juv
3
0.14793238
1.911
0
0ing
Se
=
exp
(­(
m+
f))
=
31,
jun=
30)
Assumed
by
A.
Gage.
[
27982]
sheepshead
age01
4
0.138069237
1.98
0
0ing
Se
=
exp
(­(
m+
f))
bream
M
(
l/
y)
Assumed
by
A.
Gage.
[
27982]
sheepshead
age02
5
0.138069237
1.98
0
0ing
Se
=
exp
(­(
m+
f))
bream
M
(
l/
y)
Assumed
by
A.
Gage.
[
27982]
sheepshead
age03
6
0.088036833
1.98
0.45
0.5ing
Se
=
exp
(­(
m+
f))
bream
M
(
l/
y)
Assumed
by
A.
Gage.
[
27982]
sheepshead
age04
7
0.088036833
1.98
0.45
1ing
Se
=
exp
(­(
m+
f))
bream
M
(
l/
y)
Assumed
by
A.
Gage.
[
27982]
sheepshead
age05
8
0.088036833
1.98
0.45
1ing
Se
=
exp
(­(
m+
f))
bream
M
(
l/
y)
Assumed
by
A.
Gage.
[
27982]
sheepshead
age06
9
0.088036833
1.98
0.45
1ing
Se
=
exp
(­(
m+
f))
half
natural.
head
in
Florida
(
Murphy)
Murphy's
e­
mail
F0.1[
27982]
sheepshead
age07
10
0.088036833
1.98
0.45
1ing
Se
=
exp
(­(
m+
f))
half
natural.
head
in
Florida
(
Murphy)
Murphy's
e­
mail
F0.1[
27982]
sheepshead
age08
11
0.088036833
1.98
0.45
1ing
Se
=
exp
(­(
m+
f))
half
natural.
head
in
Florida
(
Murphy)
Murphy's
e­
mail
F0.1[
27982]
sheepshead
age09
12
0.088036833
1.98
0.45
1ing
Se
=
exp
(­(
m+
f))
half
natural.
head
in
Florida
(
Murphy)
Murphy's
e­
mail
F0.1[
27982]
sheepshead
age10
13
0.088036833
1.98
0.45
1ing
Se
=
exp
(­(
m+
f))
half
natural.
head
in
Florida
(
Murphy)
Murphy's
e­
mail
F0.1[
27982]
sheepshead
age11
14
0.088036833
1.98
0.45
1ing
Se
=
exp
(­(
m+
f))
half
natural.
head
in
Florida
(
Murphy)
Murphy's
e­
mail
F0.1[
27982]
sheepshead
age12
15
0.088036833
1.98
0.45
1ing
Se
=
exp
(­(
m+
f))
half
natural.
head
in
Florida
(
Murphy)
Murphy's
e­
mail
F0.1[
27982]
sheepshead
age13
16
0.088036833
1.98
0.45
1ing
Se
=
exp
(­(
m+
f))
half
natural.
head
in
Florida
(
Murphy)
Murphy's
e­
mail
F0.1[
27982]
sheepshead
age14
17
0.088036833
1.98
0.45
1ing
Se
=
exp
(­(
m+
f))
half
natural.
head
in
Florida
(
Murphy)
Murphy's
e­
mail
F0.1[
27982]
sheepshead
age15
18
0.088036833
1.98
0.45
1ing
Se
=
exp
(­(
m+
f))
half
natural.
head
in
Florida
(
Murphy)
Murphy's
e­
mail
F0.1[
27982]
sheepshead
age16
19
0.088036833
1.98
0.45
1ing
Se
=
exp
(­(
m+
f))
half
natural.
head
in
Florida
(
Murphy)
Murphy's
e­
mail
F0.1[
27982]
goby.
spp
egg
1
0.750001554
0.28768
0
0ing
Se
=
exp
(­(
m+
f))
ge
duration.
#
28558,
Appendix
F­
126x
F­
126
goby.
spp
larvae
2
0.016666743
4.09434
0
0ing
Se
=
exp
(­(
m+
f))
ge
duration.
#
28558,
Appendix
F­
126x
F­
126
goby.
spp
juv
3
0.09998451
2.30274
0
0ing
Se
=
exp
(­(
m+
f))
ge
duration.
#
28558,
Appendix
F­
126x
F­
126
goby.
spp
age01
4
0.078318612
2.54697
0
0ing
Se
=
exp
(­(
m+
f))
ge
duration.
#
28558,
Appendix
F­
126rposes
bay.
anchovy.
gulf2
egg
1
0.14370395
1.94
0
0ing
Se
=
exp
(­(
m+
f))
[
26554]
Based
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
bay.
anchovy.
gulf2
larvae
2
0.000452827
7.7
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
bay.
anchovy.
gulf2
juv1
3
0.921073907
0.082215
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
bay.
anchovy.
gulf2
juv2
4
0.917474952
0.08613
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
bay.
anchovy.
gulf2
juv3
5
0.878802582
0.129195
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
bay.
anchovy.
gulf2
juv4
6
0.369941646
0.99441
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
bay.
anchovy.
gulf2
age01
7
0.197059414
1.62425
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
bay.
anchovy.
gulf2
age02
8
0.197059414
1.62425
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
bay.
anchovy.
gulf2
age03
9
0.197059414
1.62425
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FBased
on
fishery
landings
data
(
NOAA,
2003).
,
2003).
silver.
perch2
egg
1
0.063696542
2.753625
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
F6
email:
mike.
murphy@
fwc.
state.
fl.
us);
1/
23/
02on
size.
silver.
perch2
larvae
2
0.004650037
5.37088
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
F6
email:
mike.
murphy@
fwc.
state.
fl.
us);
1/
23/
02on
size.
silver.
perch2
juv
3
0.181463817
1.706699
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
F6
email:
mike.
murphy@
fwc.
state.
fl.
us);
1/
23/
02on
size.
silver.
perch2
age01
4
0.021493601
3.84
0
0ing
Se
=
exp
(­(
m+
f))
01.
(
Growth)
6
email:
mike.
murphy@
fwc.
state.
fl.
us);
1/
23/
02on
size.
silver.
perch2
age02
5
0.019448215
3.84
0.1
0.5ing
Se
=
exp
(­(
m+
f))
01.
(
Growth)
6
email:
mike.
murphy@
fwc.
state.
fl.
us);
1/
23/
02on
size.
silver.
perch2
age03
6
0.019448215
3.84
0.1
1ing
Se
=
exp
(­(
m+
f))
01.
(
Growth)
6
email:
mike.
murphy@
fwc.
state.
fl.
us);
1/
23/
02on
size.
striped.
mullet
egg
1
0.150
1.897119985
0
0ies
in
this
ecosystem
exp
(­(
m+
f))
RM#
34713.
Collins,
1985.,
1985.
striped.
mullet
larvae
2
0.01
4.605170186
0
0­
age1*
Sage1­
age2
exp
(­(
m+
f))
RM#
34713.
Collins,
1985.,
1985.
striped.
mullet
juv
3
0.4
0.916290732
0
0
sumed
by
D.
Cacela.
exp
(­(
m+
f))
RM#
34713.
Collins,
1985.,
1985.
striped.
mullet
age01
4
0.58860497
0.23
0.3
0.5ing
Se
=
exp
(­(
m+
f))
temp
of
23.6ed
to
represent
modest
fishing,
lower
than
spot,
1985.
striped.
mullet
age02
5
0.58860497
0.23
0.3
1ing
Se
=
exp
(­(
m+
f))
temp
of
23.6ed
to
represent
modest
fishing,
lower
than
spot,
1985.
striped.
mullet
age03
6
0.58860497
0.23
0.3
1ing
Se
=
exp
(­(
m+
f))
temp
of
23.6ed
to
represent
modest
fishing,
lower
than
spot,
1985.
striped.
mullet
age04
7
0.58860497
0.23
0.3
1ing
Se
=
exp
(­(
m+
f))
temp
of
23.6ed
to
represent
modest
fishing,
lower
than
spot,
1985.
striped.
mullet
age05
8
0.58860497
0.23
0.3
1ing
Se
=
exp
(­(
m+
f))
temp
of
23.6ed
to
represent
modest
fishing,
lower
than
spot,
1985.
striped.
mullet
age06
9
0.58860497
0.23
0.3
1ing
Se
=
exp
(­(
m+
f))
temp
of
23.6ed
to
represent
modest
fishing,
lower
than
spot,
1985.
spot
egg
1
0.438359469
0.824716
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
prolarvae
2
0.03692509
3.298864
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
postlarvae
3
0.016186463
4.12358
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
juv
4
0.076535545
2.57
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age01
5
0.421799583
0.463185
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age02
6
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age03
7
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age04
8
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age05
9
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age06
10
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age07
11
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age08
12
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age09
13
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age10
14
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age11
15
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age12
16
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age13
17
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age14
18
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot
age15
19
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
sea.
basses
egg
1
0.75
0.287682072
0
0
rockfish
and
sculpin
and
sculpin
Assumed
by
A.
Gage.
Gage
sea.
basses
larvae
2
0.002478752
6
0
0
rockfish
and
sculpin
and
sculpin
Assumed
by
A.
Gage.
Gage
sea.
basses
juvenile
3
0.826959134
0.19
0
0ing
Se
=
exp
(­(
m+
f))
p.
of
13.0
C
Assumed
by
A.
Gage.
Gage
sea.
basses
age01
4
0.826959134
0.19
0
0ing
Se
=
exp
(­(
m+
f))
p.
of
13.0
C
Assumed
by
M.
Barron.
classes
sea.
basses
age02
5
0.826959134
0.19
0
0ing
Se
=
exp
(­(
m+
f))
p.
of
13.0
C
Assumed
by
M.
Barron.
classes
sea.
basses
age03
6
0.826959134
0.19
0
0ing
Se
=
exp
(­(
m+
f))
p.
of
13.0
C
Assumed
by
M.
Barron.
classes
sea.
basses
age04
7
0.826959134
0.19
0
0ing
Se
=
exp
(­(
m+
f))
p.
of
13.0
C
Assumed
by
M.
Barron.
classes
sea.
basses
age05
8
0.639543908
0.19
0.257
0.5ing
Se
=
exp
(­(
m+
f))
p.
of
13.0
C
Assumed
by
M.
Barron.
classes
sea.
basses
age06
9
0.639543908
0.19
0.257
1ing
Se
=
exp
(­(
m+
f))
p.
of
13.0
C
Assumed
by
M.
Barron.
classes
sea.
basses
age07
10
0.580421915
0.287
0.257
1ing
Se
=
exp
(­(
m+
f))
n
ages
3­
12.544
based
on
ages
3­
12;
Calculated
F=(
M
­
Z)
classes
sea.
basses
age08
11
0.580421915
0.287
0.257
1ing
Se
=
exp
(­(
m+
f))
n
ages
3­
12.544
based
on
ages
3­
12;
Calculated
F=(
M
­
Z)
classes
sea.
basses
age09
12
0.580421915
0.287
0.257
1ing
Se
=
exp
(­(
m+
f))
n
ages
3­
12.544
based
on
ages
3­
12;
Calculated
F=(
M
­
Z)
classes
sea.
basses
age10
13
0.580421915
0.287
0.257
1ing
Se
=
exp
(­(
m+
f))
n
ages
3­
12.544
based
on
ages
3­
12;
Calculated
F=(
M
­
Z)
classes
mackerels
egg
1
0.09143000
2.392181627
0
0
p.
64/
Pilgrim
station
exp
(­(
m+
f))
Assumed
by
A
Gret.
ckerel.
mackerels
larvae
2
0.00002505
10.59451698
0
0
p.
64/
Pilgrim
station
exp
(­(
m+
f))
Assumed
by
A
Gret.
ckerel.
mackerels
juvenile
3
0.40000000
0.916290732
0
0ssumed
(
D.
Cacela)
exp
(­(
m+
f))
Assumed
by
A
Gret.
ckerel.
mackerels
age01
4
0.594520548
0.52
0
0ing
Se
=
exp
(­(
m+
f))
west
Atlantic
Assumed
by
A
Gret.
ckerel.
mackerels
age02
5
0.537944438
0.37
0.25
0.5ing
Se
=
exp
(­(
m+
f))
west
Atlantic://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
ckerel.
mackerels
age03
6
0.537944438
0.37
0.25
1ing
Se
=
exp
(­(
m+
f))
west
Atlantic://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
ckerel.
mackerels
age04
7
0.537944438
0.37
0.25
1ing
Se
=
exp
(­(
m+
f))
west
Atlantic://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
ckerel.
mackerels
age05
8
0.537944438
0.37
0.25
1ing
Se
=
exp
(­(
m+
f))
west
Atlantic://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
ckerel.
mackerels
age06
9
0.537944438
0.37
0.25
1ing
Se
=
exp
(­(
m+
f))
west
Atlantic://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
ckerel.
mackerels
age07
10
0.537944438
0.37
0.25
1ing
Se
=
exp
(­(
m+
f))
west
Atlantic://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
ckerel.
mackerels
age08
11
0.537944438
0.37
0.25
1ing
Se
=
exp
(­(
m+
f))
west
Atlantic://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
ckerel.
mackerels
age09
12
0.537944438
0.37
0.25
1ing
Se
=
exp
(­(
m+
f))
west
Atlantic://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
ckerel.
mackerels
age10
13
0.537944438
0.37
0.25
1ing
Se
=
exp
(­(
m+
f))
west
Atlantic://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
ckerel.
mackerels
age11
14
0.537944438
0.37
0.25
1ing
Se
=
exp
(­(
m+
f))
west
Atlantic://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
ckerel.
mackerels
age12
15
0.537944438
0.37
0.25
1ing
Se
=
exp
(­(
m+
f))
west
Atlantic://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
ckerel.
mackerels
age13
16
0.537944438
0.37
0.25
1ing
Se
=
exp
(­(
m+
f))
west
Atlantic://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
ckerel.
mackerels
age14
17
0.537944438
0.37
0.25
1ing
Se
=
exp
(­(
m+
f))
west
Atlantic://
www.
wh.
whoi.
edu/
sos/
.
Accessed
Jan,
2002)
ckerel.
black.
drum2
egg
1
0.10331218
2.27
0
0ing
Se
=
exp
(­(
m+
f))
med
10
daysBased
on
fishery
landings
data
(
NOAA,
2003).
rposes)
black.
drum2
larvae
2
0.002178759
6.129
0
0o
and
post
sac
larve
exp
(­(
m+
f))
based
on
black
drumk
drum
black.
drum2
juv
3
0.273077402
1.148
0.15
0.5ing
Se
=
exp
(­(
m+
f))
and
fish
mort
p­
a.
pdf;
divided
between
nat.
mort
and
fish
mort
rposes)
black.
drum2
age01
4
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age02
5
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age03
6
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age04
7
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age05
8
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age06
9
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age07
10
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age08
11
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age09
12
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age10
13
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age11
14
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age12
15
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age13
16
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age14
17
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age15
18
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age16
19
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age17
20
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age18
21
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age19
22
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age20
23
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age21
24
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age22
25
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age23
26
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age24
27
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age25
28
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age26
29
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age27
30
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age28
31
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age29
32
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age30
33
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age31
34
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age32
35
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age33
36
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age34
37
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age35
38
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age36
39
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age37
40
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age38
41
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age39
42
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
black.
drum2
age40
43
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
spotted.
seatrout2
egg
1
0.1
2.302585093
0
0
[
21805];
p.
7.2­
20
exp
(­(
m+
f))
Assumed
by
A.
Gage.
inches.
spotted.
seatrout2
larvae
2
0.000219886
8.4224
0
0ing
Se
=
exp
(­(
m+
f))
post
larvae.
Based
on
spotted.
seatrout
pro
&
post
larvae.
inches.
spotted.
seatrout2
juv
3
0.58
0.2724
0.2724
0.5thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout2
age01
4
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout2
age02
5
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout2
age03
6
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout2
age04
7
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout2
age05
8
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout2
age06
9
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout2
age07
10
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spotted.
seatrout2
age08
11
0.58
0.2724
0.2724
1thus
survival
is
58%.
and
set
M=
Fces.
Decision:
set
survival
to
0.58
and
set
M=
F
inches.
spot2
egg
1
0.438359469
0.824716
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
larvae
2
0.000597687
7.422444
0
0ing
Se
=
exp
(­(
m+
f))
&
post
larvaeSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
juv
3
0.076535545
2.57
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age01
4
0.421799583
0.463185
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age02
5
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age03
6
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age04
7
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age05
8
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age06
9
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age07
10
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age08
11
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age09
12
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age10
13
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age11
14
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age12
15
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age13
16
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age14
17
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
spot2
age15
18
0.449293019
0.40004
0.40004
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
red.
drum
egg
1
0.10331218
2.27
0
0ing
Se
=
exp
(­(
m+
f))
med
10
daysBased
on
fishery
landings
data
(
NOAA,
2003).
rposes)
red.
drum
prolarvae
2
0.046677175
3.0645
0
0ing
Se
=
exp
(­(
m+
f))
med
27daysBased
on
fishery
landings
data
(
NOAA,
2003).
rposes)
red.
drum
postlarvae
3
0.046677175
3.0645
0
0ing
Se
=
exp
(­(
m+
f))
med
27daysBased
on
fishery
landings
data
(
NOAA,
2003).
rposes)
red.
drum
juv
4
0.273077402
1.148
0.15
0.5ing
Se
=
exp
(­(
m+
f))
and
fish
mort
p­
a.
pdf;
divided
between
nat.
mort
and
fish
mort
rposes)
red.
drum
age01
5
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age02
6
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age03
7
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age04
8
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age05
9
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age06
10
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age07
11
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age08
12
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age09
13
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age10
14
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age11
15
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age12
16
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age13
17
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age14
18
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age15
19
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age16
20
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age17
21
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age18
22
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age19
23
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age20
24
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age21
25
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age22
26
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age23
27
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age24
28
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age25
29
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age26
30
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age27
31
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age28
32
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age29
33
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age30
34
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age31
35
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age32
36
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age33
37
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age34
38
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age35
39
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age36
40
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age37
41
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age38
42
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age39
43
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
red.
drum
age40
44
0.780620107
0.0977
0.15
1ing
Se
=
exp
(­(
m+
f))
of
45,
p.
9­
3.
mike
murphy's
e­
mail
F0.1ail
F0.1
atlantic.
croaker.
gulf
egg
1
0.441811482
0.816872
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
atlantic.
croaker.
gulf
larvae
2
0.000303539
8.1
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
atlantic.
croaker.
gulf
juv
3
0.034047455
3.38
0
0ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
atlantic.
croaker.
gulf
age01
4
0.248278296
1.093175
0.30003
0.5ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
atlantic.
croaker.
gulf
age02
5
0.548778708
0.30003
0.30003
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
atlantic.
croaker.
gulf
age03
6
0.548778708
0.30003
0.30003
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
atlantic.
croaker.
gulf
age04
7
0.548778708
0.30003
0.30003
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
atlantic.
croaker.
gulf
age05
8
0.548778708
0.30003
0.30003
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
atlantic.
croaker.
gulf
age06
9
0.548778708
0.30003
0.30003
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
atlantic.
croaker.
gulf
age07
10
0.548778708
0.30003
0.30003
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
atlantic.
croaker.
gulf
age08
11
0.548778708
0.30003
0.30003
1ing
Se
=
exp
(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
non.
ris.
com
egg
1
0.12500000
2.079441542
0
0
p.
66/
Pilgrim
station
exp
(­(
m+
f))
rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
com
larvae
2
0.00331649
5.708847403
0
0
Calculated
based
o
exp
(­(
m+
f))
rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
F;
p.
14
non.
ris.
com
juv
3
0.05758900
2.854423702
0
0
provided
by
Entergy
exp
(­(
m+
f))
rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
com
age01
4
0.63762815
0.45
0
0
Calculated
using
Se
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
com
age02
5
0.28650480
0.45
0.8
0.5
Calculated
using
Se
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
com
age03
6
0.28650480
0.45
0.8
1
Calculated
using
Se
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
com
age04
7
0.28650480
0.45
0.8
1
Calculated
using
Se
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
com
age05
8
0.28650480
0.45
0.8
1
Calculated
using
Se
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
com
age06
9
0.28650480
0.45
0.8
1
Calculated
using
Se
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
rec
egg
1
0.12500000
2.079441542
0
0
p.
66/
Pilgrim
station
exp
(­(
m+
f))
rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
rec
larvae
2
0.00331649
5.708847403
0
0
Calculated
based
o
exp
(­(
m+
f))
rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
F;
p.
14
non.
ris.
rec
juv
3
0.05758900
2.854423702
0
0
provided
by
Entergy
exp
(­(
m+
f))
rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
rec
age01
4
0.63762815
0.45
0
0
Calculated
using
Se
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
rec
age02
5
0.28650480
0.45
0.8
0.5
Calculated
using
Se
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
rec
age03
6
0.28650480
0.45
0.8
1
Calculated
using
Se
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
rec
age04
7
0.28650480
0.45
0.8
1
Calculated
using
Se
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
rec
age05
8
0.28650480
0.45
0.8
1
Calculated
using
Se
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
rec
age06
9
0.28650480
0.45
0.8
1
Calculated
using
Se
ssed
3/
19/
01rragansett
Bay
(
Durbin
et
al.;
1983)
(#
26382).
y
Agret
non.
ris.
forage
egg
1
0.35204369
1.044
0
0ing
Se
=
exp(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
non.
ris.
forage
larvae
2
0.00045283
7.70000000
0
0ing
Se
=
exp(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
non.
ris.
forage
juv
3
0.27527078
1.29000000
0
0ing
Se
=
exp(­(
m+
f))
on
juv1­
juv4SEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
non.
ris.
forage
age01
4
0.19705941
1.62425
0
0ing
Se
=
exp(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
non.
ris.
forage
age02
5
0.19705941
1.62425
0
0ing
Se
=
exp(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
non.
ris.
forage
age03
6
0.19705941
1.62425
0
0ing
Se
=
exp(­(
m+
f))
ttachment
FSEG;
1999
[
26046];
appendix
F;
Attachment
Fment
F
species
alpha.
cm.
to.
gm
alpha.
mm.
to.
gm
beta.
mm.
to.
gm
notes
egg.
diameter.
mm
dummy
­
999
­
999
­
999
dummy
­
999
bay.
anchovy.
gulf
.
1.0
1.0
Weights
are
given,
L:
W
.
bay.
anchovy.
gulf2
.
1.0
1.0
Weights
are
given,
L:
W
.
black.
drum
0.0114
1.01603E­
05
3.05
Fishbase,
2003
0.9
blue.
crab.
gulf
.
1.0
1.0
Weights
are
given,
L:
W
.
chain.
pipefish
.
0.00000941
2.66000
Sargassum
pipefish
(
a
0.9
goby.
spp
.
1.0
1.0
Weights
are
given,
L:
W
1.20
gulf.
killifish
.
0.00002600
2.96
Striped
killifish.
Carlan
2.5
hogchoker
.
1.0
1.0
Weights
are
given,
L:
W
0.75
leatherjacket
0.009496619
9.49662E­
06
3
leatherjacket.
Fishbase
1
menhaden.
spp
.
1.0
1.0
Weights
are
given,
L:
W
.
pinfish
0.0103
0.000005792
3.25
Froese
&
Pauly,
2001.
0.975
pink.
shrimp
.
0.000006247
3.2896
Bielsa
et
al.,
1983.
Sp
0.28
pink.
shrimp2
.
0.000006247
3.2896
Bielsa
et
al.,
1983.
Sp
0.28
scaled.
sardine
0.0112
0.000006595
3.23
Mean
of
3
L­
W
equatio
1.67
searobin.
gulf
.
0.00000978
3.00350
http://
fwie.
fw.
vt.
edu/
W
1.045
sheepshead
.
0.00004247
2.907
RM#
28822.
0.8
silver.
perch.
gulf
0.0251
0.000026833
2.971
Froese
&
Pauly,
2001.
0.77
spotted.
seatrout
0.0091
0.000009442
2.984
Assumed
to
be
similar
0.9
stone.
crab
.
0.003000000
3.016
[
26570]
pg.
5
.
tidewater.
silverside
.
0.00000569
3.02300
Froese,
R.
and
D.
Pau
0.75
silver.
perch2
0.0251
0.000026833
2.971
Froese
&
Pauly,
2001.
0.77
striped.
mullet
.
1.0
1.0
Weights
are
given,
L:
W
0.775
spot
.
1.0
1.0
Weights
are
given,
L:
W
1.05
sea.
basses
.
1.0
1.0
Weights
are
given,
L:
W
0.955
mackerels
.
0.000003039
3.18
Used
values
from
atlan
1.15
spotted.
seatrout2
0.0091
0.000009442
2.984
Johnson
&
Seaman,
1
0.9
spot2
.
1.0
1.0
Weights
are
given,
L:
W
1.05
black.
drum2
0.0114
1.01603E­
05
3.05
Fishbase,
2003
0.9
red.
drum
0.0114
1.01603E­
05
3.05
Fishbase,
2003
0.9
atlantic.
croaker.
gulf
.
1.0
1.0
Weights
are
given,
L:
W
0.34
non.
ris.
com
.
1.0
1.0
Weights
are
given,
L:
W
.
non.
ris.
rec
.
1.0
1.0
Weights
are
given,
L:
W
.
non.
ris.
forage
.
1.0
1.0
Weights
are
given,
L:
W
.
weight.
g
virtual.
egg.
length
notes.
egg.
diameter
­
999
­
999
dummy
0.0000084
0.0000084
PSEG,
1999
[
26046];
appendix
F,
Attachment
F
0.0000084
0.0000084
PSEG,
1999
[
26046];
appendix
F,
Attachment
F
0.000381704
3.283483606
Sutter
et
al.,
1986,
Species
Profiles:
Black
Drum.
TR
EL­
82­
4.
.
..
0.000381704
4.023539252
northern.
pipefish
Scott
and
Scott
(
1988);
#
26762;
p.
350
0.000904779
0.000904779
Assumed
to
be
similar
to
naked
goby.
Fishbase,
2003.
0.008181231
6.980180538
striped.
killifish.
Able
and
Fahay,
1998;
#
25580;
p.
110
0.000221
0.000221
Froese
&
Pauly,
2003.
avg.
of
min
&
max.
0.000523599
3.806067936
assumed
by
AGRET
0.000325
0.000325
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
relationship
for
early
life
stages
calculated
from
PSE
0.000485302
3.906125828
Muncy,
R.
J.,
1984.
Species
Profiles,
Pinfish.
Average
of
egg
diameter.
1.1494E­
05
1.203639626
[
25601]
&
Bielsa
et
al.,
1983
1.1494E­
05
1.203639626
[
25601]
&
Bielsa
et
al.,
1983
0.002416803
6.22035638
[
26662]
0.000597513
3.932228555
Froese
&
Pauly,
2003.
avg.
of
min
&
max.
0.000268083
1.88478533
[
21827]
0.00023904
2.087802224
[
25580]
0.000381704
3.454882089
[
21805].
Pg.
5.2­
30
.
..
0.000220893
3.354651154
[
21805].
Pg.
5.2­
25
0.00023904
2.087802224
[
25580]
0.000243727
0.000243727
Fishbase.
Accessed
7/
25/
2003
0.000606131
0.000606
Wang
&
Kernehan,
#
25577.
Assumed
to
be
similar
to
weakfish.
0.000456046
0.000456046
Cailliet
2000.
(
Butler
et
al.
1982)

0.000796328
5.760909064
Froese
&
Pauly,
2003.
Mod.
value.
0.000381704
3.454882089
[
21805].
Pg.
5.2­
30
0.000606131
0.000606
Wang
&
Kernehan,
#
25577.
Assumed
to
be
similar
to
weakfish.
0.000381704
3.283483606
Sutter
et
al.,
1986,
Species
Profiles:
Black
Drum.
TR
EL­
82­
4.
0.000381704
3.283483606
Sutter
et
al.,
1986,
Species
Profiles:
Black
Drum.
TR
EL­
82­
4.
0.000021
2.05795E­
05
http://
fwie.
fw.
vt.
edu/
WWW/
macsis/
lists/
TSNL0010.
htm
0.000325
0.000325
Used
values
from
Atlantic
menhaden.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
relationship
fo
0.000325
0.000325
Used
values
from
Atlantic
menhaden.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
relationship
fo
0.000325
0.000325
Used
values
from
Atlantic
menhaden.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
relationship
fo
SE&
G
impingement,
1978­
98
p
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
p
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
p
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
species
stage
stage.
sequencetotal.
len.
mm
weight.
g
weight.
lbs
notes.
maximum.
age
dummy
dummy
­
999
­
999
­
999
­
999
dummy
bay.
anchovy.
gulf
egg
1
0.00001
0.00001
.
.
bay.
anchovy.
gulf
prolarvae
2
0.00002
0.00002
.
.
bay.
anchovy.
gulf
postlarvae
3
0.00107
0.00107
.
.
bay.
anchovy.
gulf
juv
4
0.21807
0.21807
.
.
bay.
anchovy.
gulf
age01
5
1.73000
1.73000
.
.
bay.
anchovy.
gulf
age02
6
2.25000
2.25000
.
.
bay.
anchovy.
gulf
age03
7
2.29000
2.29000
.
PSEG;
1999
[
26046]
blue.
crab.
gulf
zoeae
1
0.0000959
0.0000959
.
.
blue.
crab.
gulf
megalops
2
0.00132
0.00132
.
.
blue.
crab.
gulf
juv1
3
0.00133
0.00133
.
.
blue.
crab.
gulf
age01
4
3.26000
3.26000
.
.
blue.
crab.
gulf
age02
5
51.47000
51.47000
.
.
blue.
crab.
gulf
age03
6
147.73500
147.73500
.
ased
on
Hartman
1993
pink.
shrimp
egg
1
1.20364
0.00001
.
.
pink.
shrimp
prolarvae
2
5
.
.
.
pink.
shrimp
postlarvae
3
10
.
.
.
pink.
shrimp
juv
4
97
.
.
.
pink.
shrimp
age01
5
112.5
.
.
Bielsa
et
al.,
1983.
pink.
shrimp2
egg
1
1.20364
0.00001
.
.
pink.
shrimp2
larvae
2
5
.
.
.
pink.
shrimp2
juv
3
97
.
.
.
pink.
shrimp2
age01
4
112.5
.
.
Bielsa
et
al.,
1983.
silver.
perch.
gulf
egg
1
2.08780
0.00024
.
.
silver.
perch.
gulf
prolarvae
2
2.16
0.000262944
.
.
silver.
perch.
gulf
postlarvae
3
8.8
.
.
.
silver.
perch.
gulf
juv
4
95
.
.
.
silver.
perch.
gulf
age01
5
175
.
.
.
silver.
perch.
gulf
age02
6
201.5
.
.
.
silver.
perch.
gulf
age03
7
229
.
.
.
black.
drum
egg
1
3.28348
0.00038
.
.
black.
drum
prolarvae
2
3.39
0.000419874
.
.
black.
drum
postlarvae
3
8.9
.
.
.
black.
drum
juv
4
105
.
.
.
black.
drum
age01
5
283
.
.
.
black.
drum
age02
6
383
.
.
.
black.
drum
age03
7
472
.
.
.
black.
drum
age04
8
552
.
.
.
black.
drum
age05
9
622
.
.
.
black.
drum
age06
10
684
.
.
.
black.
drum
age07
11
739
.
.
.
black.
drum
age08
12
788
.
.
.
black.
drum
age09
13
831
.
.
.
black.
drum
age10
14
870
.
.
.
black.
drum
age11
15
904
.
.
.
black.
drum
age12
16
934
.
.
.
black.
drum
age13
17
961
.
.
.
black.
drum
age14
18
985
.
.
.
black.
drum
age15
19
1006
.
.
.
black.
drum
age16
20
1025
.
.
.
black.
drum
age17
21
1042
.
.
.
black.
drum
age18
22
1056
.
.
.
black.
drum
age19
23
1069
.
.
.
black.
drum
age20
24
1081
.
.
.
black.
drum
age21
25
1091
.
.
.
black.
drum
age22
26
1100
.
.
.
black.
drum
age23
27
1109
.
.
.
black.
drum
age24
28
1116
.
.
.
black.
drum
age25
29
1122
.
.
.
black.
drum
age26
30
1128
.
.
.
black.
drum
age27
31
1133
.
.
.
black.
drum
age28
32
1137
.
.
.
black.
drum
age29
33
1141
.
.
.
black.
drum
age30
34
1145
.
.
.
black.
drum
age31
35
1148
.
.
.
black.
drum
age32
36
1150
.
.
.
black.
drum
age33
37
1153
.
.
.
black.
drum
age34
38
1155
.
.
.
black.
drum
age35
39
1157
.
.
.
black.
drum
age36
40
1159
.
.
.
black.
drum
age37
41
1160
.
.
.
black.
drum
age38
42
1162
.
.
.
black.
drum
age39
43
1163
.
.
.
black.
drum
age40
44
1164
.
.
[
26535]
max
age
in
G
pinfish
egg
1
3.90613
0.00049
.
.
pinfish
larvae
2
10.15
.
.
.
pinfish
juv
3
57.5
.
.
.
pinfish
age01
4
123
.
.
.
pinfish
age02
5
168
.
.
.
stone.
crab
stage.
1
1
0.25
.
.
.
stone.
crab
stage.
2
2
0.4
.
.
.
stone.
crab
stage.
3
3
0.55
.
.
.
stone.
crab
stage.
4
4
0.7
.
.
.

stone.
crab
stage.
5
5
0.85
.
.
.

stone.
crab
megalops
6
1
.
.
.
stone.
crab
juv
7
1.4
.
.
.
stone.
crab
age01
8
52.5
.
.
.
stone.
crab
age02
9
80
.
.
.
stone.
crab
age03
10
100
.
.
.
stone.
crab
age04
11
112
.
.
Lindberg,
W.
J.,
1984
scaled.
sardine
egg
1
6.22036
0.00242
.
.
scaled.
sardine
prolarvae
2
6.407
0.002658484
.
.
scaled.
sardine
postlarvae
3
10.0
.
.
.
scaled.
sardine
juvenile
4
25.1
.
.
.
scaled.
sardine
age01
5
179.00
.
.
Pierce,
et
al.,
2001.
h
spotted.
seatrout
egg
1
3.45488
0.00038
.
.
spotted.
seatrout
prolarvae
2
3.57
0.000419874
.
.
spotted.
seatrout
postlarvae
3
6.55
.
.
.
spotted.
seatrout
juv
4
311
.
.
.
spotted.
seatrout
age01
5
364
.
.
.
spotted.
seatrout
age02
6
435
.
.
.
spotted.
seatrout
age03
7
510
.
.
.
spotted.
seatrout
age04
8
551
.
.
.
spotted.
seatrout
age05
9
573
.
.
.
spotted.
seatrout
age06
10
617
.
.
.
spotted.
seatrout
age07
11
642
.
.
.
spotted.
seatrout
age08
12
643
.
.
[
26569]
Ft.
Myers
tidewater.
silverside
egg
1
3.35465
0.00022
.
.
tidewater.
silverside
prolarvae
2
3.5
.
.
.
tidewater.
silverside
postlarvae
3
7.5
.
.
.
tidewater.
silverside
juvenile
4
13
.
.
.
tidewater.
silverside
age01
5
95
.
.
Froese
&
Pauly,
2001
tidewater.
silverside
age02
6
117
.
0.0169785
Scott
and
Scott
(
1988
hogchoker
egg
1
0.00022
0.00022
.
.
hogchoker
larvae
2
0.50000
0.50000
.
.
hogchoker
juvenile
3
0.94000
0.94000
.
.
hogchoker
age01
4
5.13000
5.13000
.
.
hogchoker
age02
5
14.18000
14.18000
.
.
hogchoker
age03
6
27.68000
27.68000
.
.
hogchoker
age04
7
44.25000
44.25000
.
.
hogchoker
age05
8
62.39000
62.39000
.
.
hogchoker
age06
9
80.82000
80.82000
.
.
menhaden.
spp
egg
1
0.00032
0.00032
.
.
menhaden.
spp
larvae
2
0.00092
0.00092
.
.
menhaden.
spp
juv
3
0.33843
0.33843
.
.
menhaden.
spp
age01
4
42.50000
42.50000
.
.
menhaden.
spp
age02
5
161.50000
161.50000
.
.
menhaden.
spp
age03
6
307.90000
307.90000
.
.
menhaden.
spp
age04
7
441.70000
441.70000
.
.
menhaden.
spp
age05
8
547.90000
547.90000
.
.
menhaden.
spp
age06
9
626.80000
626.80000
.
.
chain.
pipefish
egg
1
4.02354
0.00038
.
.
chain.
pipefish
larvae
2
11.0000
.
.
.
chain.
pipefish
juvenile
3
125.000
.
.
.
chain.
pipefish
age01
4
176.0
.
.
.
chain.
pipefish
age02
5
227.0
.
.
.
chain.
pipefish
age03
6
278.0
.
.
.
chain.
pipefish
age04
7
329.0
.
.
.
chain.
pipefish
age05
8
380.0
.
.
Fishbase,
2003.
searobin.
gulf
egg
1
3.93223
0.00060
.
.
searobin.
gulf
larvae
2
4.059011072
0.0007
.
.
searobin.
gulf
juvenile
3
25
.
.
.
searobin.
gulf
age01
4
140
.
.
.
searobin.
gulf
age02
5
200
.
.
.
searobin.
gulf
age03
6
230
.
.
.
searobin.
gulf
age04
7
260
.
.
.
searobin.
gulf
age05
8
290
.
.
.
searobin.
gulf
age06
9
320
.
.
.
searobin.
gulf
age07
10
350
.
.
.
searobin.
gulf
age08
11
380
.
.
Froese,
R.
and
D.
Pa
gulf.
killifish
egg
1
6.98018
0.00818
.
.
gulf.
killifish
larvae
2
7
.
.
.
gulf.
killifish
juvenile
3
14.500
.
.
.
gulf.
killifish
age01
4
63
.
.
.
gulf.
killifish
age02
5
88
.
.
.
gulf.
killifish
age03
6
105
.
.
.
gulf.
killifish
age04
7
118
.
.
.
gulf.
killifish
age05
8
127
.
.
.
gulf.
killifish
age06
9
134
.
.
.
gulf.
killifish
age07
10
150
.
.
.
leatherjacket
egg
1
3.80607
0.00052
.
.
leatherjacket
larvae
2
3.928928248
0.00058
.
.
leatherjacket
juvenile
3
102
.
.
.
leatherjacket
age01
4
200
.
.
.
leatherjacket
age02
5
280
.
.
.
leatherjacket
age03
6
290
.
.
.
leatherjacket
age04
7
300
.
.
http://
marinefisheries
sheepshead
egg
1
1.88479
0.00027
.
.
sheepshead
larvae
2
6.75
.
.
.
sheepshead
juv
3
29
.
.
.
sheepshead
age01
4
260
.
.
.
sheepshead
age02
5
280
.
.
.
sheepshead
age03
6
305
.
.
.
sheepshead
age04
7
350
.
.
.
sheepshead
age05
8
355
.
.
.
sheepshead
age06
9
356
.
.
.
sheepshead
age07
10
357
.
.
.
sheepshead
age08
11
358
.
.
.
sheepshead
age09
12
359
.
.
.
sheepshead
age10
13
360
.
.
.
sheepshead
age11
14
361
.
.
.
sheepshead
age12
15
362
.
.
.
sheepshead
age13
16
363
.
.
.
sheepshead
age14
17
364
.
.
.
sheepshead
age15
18
365
.
.
.
sheepshead
age16
19
366
.
.
Status
of
sheepshead
goby.
spp
egg
1
0.00090
0.00090
.
.
goby.
spp
larvae
2
0.001
0.001
.
.
goby.
spp
juv
3
0.22
0.22
.
.
goby.
spp
age01
4
0.93
0.93
.
.
bay.
anchovy.
gulf2
egg
1
0.00001
0.00001
.
.
bay.
anchovy.
gulf2
larvae
2
0.00072
0.00072
.
.
bay.
anchovy.
gulf2
juv1
3
0.022454962
0.022454962
4.95132E­
05
.
bay.
anchovy.
gulf2
juv2
4
0.090074319
0.090074319
0.000198614
.
bay.
anchovy.
gulf2
juv3
5
0.241346551
0.241346551
0.000532169
.
bay.
anchovy.
gulf2
juv4
6
0.518387836
0.518387836
0.001143045
.
bay.
anchovy.
gulf2
age01
7
1.73
1.73
0.00381465
.
bay.
anchovy.
gulf2
age02
8
2.25
2.25
0.00496125
.
bay.
anchovy.
gulf2
age03
9
2.29
2.29
0.00504945
PSEG;
1999
[
26046]
silver.
perch2
egg
1
2.08780
0.00024
.
.
silver.
perch2
larvae
2
5.15
.
.
.
silver.
perch2
juv
3
95
.
.
.
silver.
perch2
age01
4
175
.
.
.
silver.
perch2
age02
5
201.5
.
.
.
silver.
perch2
age03
6
229
.
.
.
striped.
mullet
egg
1
0.00024
0.00024
.
.
striped.
mullet
larvae
2
0.005
0.005
.
.
striped.
mullet
juv
3
59.6
59.6
.
.
striped.
mullet
age01
4
85
85
.
.
striped.
mullet
age02
5
172
172
.
.
striped.
mullet
age03
6
351
351
.
.
striped.
mullet
age04
7
715
715
.
.
striped.
mullet
age05
8
1456
1456
.
.
striped.
mullet
age06
9
2961
2961
.
.
spot
egg
1
0.00006
0.00006
.
.
spot
prolarvae
2
0.00007
0.00007
.
.
spot
postlarvae
3
0.000387483
0.000387483
8.544E­
07
.
spot
juv
4
0.05508323
0.05508323
.
.
spot
age01
5
35.87891
35.87891
0.079112997
.
spot
age02
6
135.626
135.626
0.29905533
.
spot
age03
7
230.025
230.025
0.507205125
.
spot
age04
8
294.0677
294.0677
0.648419279
.
spot
age05
9
331.9867
331.9867
0.732030674
.
spot
age06
10
353.0627
353.0627
0.778503254
.
spot
age07
11
353.0628
353.0628
0.778503474
.
spot
age08
12
353.0629
353.0629
0.778503695
.
spot
age09
13
353.063
353.063
0.778503915
.
spot
age10
14
353.0631
353.0631
0.778504136
.
spot
age11
15
353.0632
353.0632
0.778504356
.
spot
age12
16
353.0633
353.0633
0.778504577
.
spot
age13
17
353.0634
353.0634
0.778504797
.
spot
age14
18
353.0635
353.0635
0.778505018
.
spot
age15
19
353.0636
353.0636
0.778505238
PSEG;
1999
[
26046]
sea.
basses
egg
1
0.00046
0.00046
0.000456046
.
sea.
basses
larvae
2
0.000501651
0.000501651
0.055788432
.
sea.
basses
juvenile
3
0.263511875
0.263511875
0.263511875
.
sea.
basses
age01
4
14.175
14.175
.
.
sea.
basses
age02
5
28.35
28.35
.
.
sea.
basses
age03
6
56.7
56.7
.
.
sea.
basses
age04
7
141.7
141.7
.
.
sea.
basses
age05
8
241
241
.
.
sea.
basses
age06
9
368.5
368.5
.
.
sea.
basses
age07
10
510.3
510.3
.
.
sea.
basses
age08
11
680.4
680.4
.
.
sea.
basses
age09
12
850.5
850.5
.
.
sea.
basses
age10
13
992
992
.
.
mackerels
egg
1
5.76091
0.00080
.
.
mackerels
larvae
2
5.94
0.000875961
.
.
mackerels
juvenile
3
15
.
.
.
mackerels
age01
4
257
.
.
.
mackerels
age02
5
301
.
.
.
mackerels
age03
6
323
.
.
.
mackerels
age04
7
340
.
.
.
mackerels
age05
8
350
.
.
.
mackerels
age06
9
362
.
.
.
mackerels
age07
10
374
.
.
.
mackerels
age08
11
383
.
.
.
mackerels
age09
12
386
.
.
.
mackerels
age10
13
389
.
.
.
mackerels
age11
14
396
.
.
.
mackerels
age12
15
396.1
.
.
.
mackerels
age13
16
396.2
.
.
.
mackerels
age14
17
396.3
.
.
Scott
and
Scott
(
1988
black.
drum2
egg
1
3.28348
0.00038
.
.
black.
drum2
larvae
2
5.7
.
.
.
black.
drum2
juv
3
105
.
.
.
black.
drum2
age01
4
283
.
.
.
black.
drum2
age02
5
383
.
.
.
black.
drum2
age03
6
472
.
.
.
black.
drum2
age04
7
552
.
.
.
black.
drum2
age05
8
622
.
.
.
black.
drum2
age06
9
684
.
.
.
black.
drum2
age07
10
739
.
.
.
black.
drum2
age08
11
788
.
.
.
black.
drum2
age09
12
831
.
.
.
black.
drum2
age10
13
870
.
.
.
black.
drum2
age11
14
904
.
.
.
black.
drum2
age12
15
934
.
.
.
black.
drum2
age13
16
961
.
.
.
black.
drum2
age14
17
985
.
.
.
black.
drum2
age15
18
1006
.
.
.
black.
drum2
age16
19
1025
.
.
.
black.
drum2
age17
20
1042
.
.
.
black.
drum2
age18
21
1056
.
.
.
black.
drum2
age19
22
1069
.
.
.
black.
drum2
age20
23
1081
.
.
.
black.
drum2
age21
24
1091
.
.
.
black.
drum2
age22
25
1100
.
.
.
black.
drum2
age23
26
1109
.
.
.
black.
drum2
age24
27
1116
.
.
.
black.
drum2
age25
28
1122
.
.
.
black.
drum2
age26
29
1128
.
.
.
black.
drum2
age27
30
1133
.
.
.
black.
drum2
age28
31
1137
.
.
.
black.
drum2
age29
32
1141
.
.
.
black.
drum2
age30
33
1145
.
.
.
black.
drum2
age31
34
1148
.
.
.
black.
drum2
age32
35
1150
.
.
.
black.
drum2
age33
36
1153
.
.
.
black.
drum2
age34
37
1155
.
.
.
black.
drum2
age35
38
1157
.
.
.
black.
drum2
age36
39
1159
.
.
.
black.
drum2
age37
40
1160
.
.
.
black.
drum2
age38
41
1162
.
.
.
black.
drum2
age39
42
1163
.
.
.
black.
drum2
age40
43
1164
.
.
[
26535]
max
age
in
G
spotted.
seatrout2
egg
1
3.45488
0.00038
.
.
spotted.
seatrout2
larvae
2
3.57
0.000419874
.
.
spotted.
seatrout2
juv
4
311
.
.
.
spotted.
seatrout2
age01
5
364
.
.
.
spotted.
seatrout2
age02
6
435
.
.
.
spotted.
seatrout2
age03
7
510
.
.
.
spotted.
seatrout2
age04
8
551
.
.
.
spotted.
seatrout2
age05
9
573
.
.
.
spotted.
seatrout2
age06
10
617
.
.
.
spotted.
seatrout2
age07
11
642
.
.
.
spotted.
seatrout2
age08
12
643
.
.
[
26569]
Ft.
Myers
spot2
egg
1
0.00006
0.00006
.
.
spot2
larvae
2
0.000228741
0.000228741
.
.
spot2
juv
4
0.05508323
0.05508323
.
.
spot2
age01
5
35.87891
35.87891
0.079112997
.
spot2
age02
6
135.626
135.626
0.29905533
.
spot2
age03
7
230.025
230.025
0.507205125
.
spot2
age04
8
294.0677
294.0677
0.648419279
.
spot2
age05
9
331.9867
331.9867
0.732030674
.
spot2
age06
10
353.0627
353.0627
0.778503254
.
spot2
age07
11
353.0628
353.0628
0.778503474
.
spot2
age08
12
353.0629
353.0629
0.778503695
.
spot2
age09
13
353.063
353.063
0.778503915
.
spot2
age10
14
353.0631
353.0631
0.778504136
.
spot2
age11
15
353.0632
353.0632
0.778504356
.
spot2
age12
16
353.0633
353.0633
0.778504577
.
spot2
age13
17
353.0634
353.0634
0.778504797
.
spot2
age14
18
353.0635
353.0635
0.778505018
.
spot2
age15
19
353.0636
353.0636
0.778505238
PSEG;
1999
[
26046]
red.
drum
egg
1
3.28348
0.00038
.
.
red.
drum
prolarvae
2
3.39
0.000419874
.
.
red.
drum
postlarvae
3
8.9
.
.
.
red.
drum
juv
4
105
.
.
.
red.
drum
age01
5
283
.
.
.
red.
drum
age02
6
383
.
.
.
red.
drum
age03
7
472
.
.
.
red.
drum
age04
8
552
.
.
.
red.
drum
age05
9
622
.
.
.
red.
drum
age06
10
684
.
.
.
red.
drum
age07
11
739
.
.
.
red.
drum
age08
12
788
.
.
.
red.
drum
age09
13
831
.
.
.
red.
drum
age10
14
870
.
.
.
red.
drum
age11
15
904
.
.
.
red.
drum
age12
16
934
.
.
.
red.
drum
age13
17
961
.
.
.
red.
drum
age14
18
985
.
.
.
red.
drum
age15
19
1006
.
.
.
red.
drum
age16
20
1025
.
.
.
red.
drum
age17
21
1042
.
.
.
red.
drum
age18
22
1056
.
.
.
red.
drum
age19
23
1069
.
.
.
red.
drum
age20
24
1081
.
.
.
red.
drum
age21
25
1091
.
.
.
red.
drum
age22
26
1100
.
.
.
red.
drum
age23
27
1109
.
.
.
red.
drum
age24
28
1116
.
.
.
red.
drum
age25
29
1122
.
.
.
red.
drum
age26
30
1128
.
.
.
red.
drum
age27
31
1133
.
.
.
red.
drum
age28
32
1137
.
.
.
red.
drum
age29
33
1141
.
.
.
red.
drum
age30
34
1145
.
.
.
red.
drum
age31
35
1148
.
.
.
red.
drum
age32
36
1150
.
.
.
red.
drum
age33
37
1153
.
.
.
red.
drum
age34
38
1155
.
.
.
red.
drum
age35
39
1157
.
.
.
red.
drum
age36
40
1159
.
.
.
red.
drum
age37
41
1160
.
.
.
red.
drum
age38
42
1162
.
.
.
red.
drum
age39
43
1163
.
.
.
red.
drum
age40
44
1164
.
.
[
26535]
max
age
in
G
atlantic.
croaker.
gulf
egg
1
0.00001
0.00001
.
.
atlantic.
croaker.
gulf
larvae
2
0.00007
0.00007
.
.
atlantic.
croaker.
gulf
juv
3
0.02830
0.02830
.
.
atlantic.
croaker.
gulf
age01
4
99.92634
99.92634
.
.
atlantic.
croaker.
gulf
age02
5
304.54000
304.54000
.
.
atlantic.
croaker.
gulf
age03
6
562.57900
562.57900
.
.
atlantic.
croaker.
gulf
age04
7
853.18130
853.18130
.
.
atlantic.
croaker.
gulf
age05
8
1100.00000
1100.00000
.
.
atlantic.
croaker.
gulf
age06
9
1477.70000
1477.70000
.
.
atlantic.
croaker.
gulf
age07
10
1477.70000
1477.70000
.
.
atlantic.
croaker.
gulf
age08
11
1477.70000
1477.70000
.
PSEG;
1999
[
26046]
non.
ris.
com
egg
1
0.00032
0.00032
.
.
non.
ris.
com
larvae
2
0.00092
0.00092
.
.
non.
ris.
com
juv
3
0.33843
0.33843
.
.
non.
ris.
com
age01
4
42.50000
42.50000
.
.
non.
ris.
com
age02
5
161.50000
161.50000
.
.
non.
ris.
com
age03
6
307.90000
307.90000
.
.
non.
ris.
com
age04
7
441.70000
441.70000
.
.
non.
ris.
com
age05
8
547.90000
547.90000
.
.
non.
ris.
com
age06
9
626.80000
626.80000
.
.
non.
ris.
rec
egg
1
0.00032
0.00032
.
.
non.
ris.
rec
larvae
2
0.00092
0.00092
.
.
non.
ris.
rec
juv
3
0.33843
0.33843
.
.
non.
ris.
rec
age01
4
42.50000
42.50000
.
.
non.
ris.
rec
age02
5
161.50000
161.50000
.
.
non.
ris.
rec
age03
6
307.90000
307.90000
.
.
non.
ris.
rec
age04
7
441.70000
441.70000
.
.
non.
ris.
rec
age05
8
547.90000
547.90000
.
.
non.
ris.
rec
age06
9
626.80000
626.80000
.
.
non.
ris.
forage
egg
1
0.00001
0.00001
.
.
non.
ris.
forage
larvae
2
0.00072
0.00072
.
.
non.
ris.
forage
juv
3
0.21807
0.21807
.
.
non.
ris.
forage
age01
4
1.73000
1.73000
.
.
non.
ris.
forage
age02
5
2.25000
2.25000
.
.
non.
ris.
forage
age03
6
2.29000
2.29000
.
endix
F;
Attachment
F
note.
length
note.
weight
dummy
dummy
Based
on
values
from
PSEG,
Appendix
L
11.
Based
on
values
from
PSEG,
Appendix
L
11
Based
on
values
from
PSEG,
Appendix
L
11.
Based
on
values
from
PSEG,
Appendix
L
11
Average
of
pysl
and
pysl2
from
bay.
anchovy1
Average
of
pysl
and
pysl2
from
bay.
anchovy1
Average
of
juv1­
juv4
from
bay.
anchovy1
Average
of
juv1­
juv4
from
bay.
anchovy1
Represents
weights,
not
lengths.
PSEG,
1999
[
26046];
appendix
F,
Attachmen
Represents
weights,
not
lengths.
PSEG,
1999
[
26046];
appendix
F,
Attachmen
Represents
weights,
not
lengths.
PSEG,
1999
[
26046];
appendix
F,
Attachmen
Represents
weights,
not
lengths.
Mean
Length
for
YOY
and
older
from
PSEG,
Represents
weights,
not
lengths.
Mean
Length
for
YOY
and
older
from
PSEG,
Represents
weights,
not
lengths.
Mean
Length
for
YOY
and
older
from
PSEG,
Represents
weights,
not
lengths.
Mean
Length
for
YOY
and
older
from
PSEG,
Represents
weights,
not
lengths.
Mean
Length
for
YOY
and
older
from
PSEG,
Represents
weights,
not
lengths.
Mean
Length
for
YOY
and
older
from
PSEG,
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
assumed.
.
[
25601]
length
when
postlarvae
become
benthic
.
[
25601]
average
length
of
6wks
and
emigration
from
nursery
.
[
25601]
average
length
of
adult
shrimp
.
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
assumed.
.
[
25601]
average
length
of
6wks
and
emigration
from
nursery
.
[
25601]
average
length
of
adult
shrimp
.
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
Virtual
larval
length
based
on
egg
wt
plus
10%
Calculated
as
10%
greater
than
egg
weight.
[
25580]
length
when
fin
rays
complete.
.
[
25580]
average
yoy.
.
[
25580]
average
age01
in
spring.
.
assumed.
.
Author
Unknown.
Fishing
Lines:
Fish
Identification
Section.
http://
marinefisheries.
org/
fish.
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
Virtual
larval
length
based
on
egg
wt
plus
10%
Calculated
as
10%
greater
than
egg
weight.
Sutter
et
al.,
1986,
Species
Profiles:
Black
Drum.
TR
EL­
82­
4.
(
average
of
length
at
absor.
[
25580]
average
of
min
length
in
June
and
max
length
in
oct.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
Muncy,
R.
J.,
1984.
Species
Profiles,
Pinfish.
Average
of
min
larvae
and
max
larvae
from
.
Muncy,
R.
J.,
1984.
Species
Profiles,
Pinfish.
Average
of
min
&
max
juv
length.
.
Muncy,
R.
J.,
1984.
Species
Profiles,
Pinfish.
Average
of
age
1
length.
.
Muncy,
R.
J.,
1984.
Species
Profiles,
Pinfish.
Age
1
plus
age
2
growth
increment.
.
[
26979]
Blue
Crab.
Width
at
hatching.
.
[
26979]
Blue
Crab.
Estimated
based
on
length
as
z.
1
and
megalopa
.
[
26979]
Blue
Crab.
Estimated
based
on
length
as
z.
1
and
megalopa
.
[
26979]
Blue
Crab.
Estimated
based
on
length
as
z.
1
and
megalopa
.

[
26979]
Blue
Crab.
Estimated
based
on
length
as
z.
1
and
megalopa
Nates,
S.
F.
and
C.
L.
McKenney,
Jr.
2000.
G
[
26979]
Blue
Crab.
megalopal
stage.
.
[
26548]
Juveniles.
.
[
26548]
Average
of
age
1.
.
[
26548]
Year
2.
.
[
26548]
Year
3
and
4.
.
[
26548]
Year
3
and
4.
Assumed
to
be
slightly
larger
than
age
3.
.
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
Virtual
larval
length
based
on
egg
wt
plus
10%
Calculated
as
10%
greater
than
egg
weight.
Interpolated
based
on
prolarvae
and
juvenile
stages.
.
[
21805]
pg
5.2­
23.
23.0
SL
converted
to
FL
using
FL=
0.5
+
1.07
*
SL
.
Pierce,
et
al.,
2001.
http://
fishbull.
noaa.
gov/
991/
18.
pdf.
FL.
.
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
Virtual
larval
length
based
on
egg
wt
plus
10%
Calculated
as
10%
greater
than
egg
weight.
[
21805]
average
of
absorption
of
yolk
sac
and
transformation.
Pg.
5.2­
30
.
[
27954]
Charlotte
harbor.
Females.
.
[
27954]
Charlotte
harbor.
Females.
.
[
27954]
Charlotte
harbor.
Females.
.
[
27954]
Charlotte
harbor.
Females.
.
[
27954]
Charlotte
harbor.
Females.
.
[
27954]
Charlotte
harbor.
Females.
.
[
27954]
Charlotte
harbor.
Females.
.
[
27954]
Charlotte
harbor.
Females.
.
Assumed
to
be
larger.
.
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
[
26511]
length
at
hatching
of
Menidia
Beryllina.
.
[
26705]
postlarvae
p.
320
.
[
26511]
pg.
118,
Menidia
menidia.
.
Max
length
in
FL
waters
[
21805].
Pg.
5.2­
25
.
Scott
and
Scott
(
1988);
#
26762;
p.
317/
Annapolis
River:
little
bigger
than
in
August.
Atlant.
Represents
virtual.
length
as
calculated
in
worksheet
'
lbs.
from.
mm03'.
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
Represents
weights,
not
lengths.
assumed
by
AGret
based
on
other
ages
Represents
weights,
not
lengths.
[
28558];
Table
F1­
7
Represents
weights,
not
lengths.
[
28558];
Table
F1­
7
Represents
weights,
not
lengths.
[
28558];
Table
F1­
7
Represents
weights,
not
lengths.
[
28558];
Table
F1­
7
Represents
weights,
not
lengths.
[
28558];
Table
F1­
7
Represents
weights,
not
lengths.
[
28558];
Table
F1­
7
Represents
weights,
not
lengths.
[
28558];
Table
F1­
7
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Average
of
ysl
and
pysl
from
atlantic.
menhaden1
Average
of
ysl
and
pysl
from
atlantic.
menhad
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
Able
&
Fahay,
1998,
pg.
130
.
Northern
pipefish.
Able
&
Fahay,
1998,
pg.
130
.
Interpolated
based
on
ages
1
and
5.
.
Interpolated
based
on
ages
1
and
5.
.
Interpolated
based
on
ages
1
and
5.
.
Interpolated
based
on
ages
1
and
5.
.
Fishbase,
2003.
.
Represents
virtual.
length
as
calculated
in
worksheet
'
lbs.
from.
mm03'.
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
Calculated
using
weight
and
L­
W
equation.
Calculated
as
10%
greater
than
egg
weight.
http://
fwie.
fw.
vt.
edu/
WWW/
macsis/
lists/
M010501.
htm
.
http://
fwie.
fw.
vt.
edu/
WWW/
macsis/
lists/
M010501.
htm
NA
http://
fwie.
fw.
vt.
edu/
WWW/
macsis/
lists/
M010501.
htm
NA
Interpolated
based
on
ages
2
and
8.
NA
Interpolated
based
on
ages
2
and
8.
NA
Interpolated
based
on
ages
2
and
8.
NA
Interpolated
based
on
ages
2
and
8.
NA
Interpolated
based
on
ages
2
and
8.
NA
Froese,
R.
and
D.
Pauly
(
eds.).
2001.
FishBase.
www.
fishbase.
org.
Accessed
June
7,
NA
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
striped.
killifish.
Able
and
Fahay,
1998;
#
25580;
p.
110
(
7
­
11
mm
at
hatching,
larvae
are
11.
Able
and
Fahay,
1998;
#
25580;
p.
109
(
based
on
figure).
.
striped.
killifish.
Carlander,
1969.
P.
567,
MD
­
average
of
males
and
females
.
striped.
killifish.
Carlander,
1969.
P.
567,
MD
­
average
of
males
and
females
.
striped.
killifish.
Carlander,
1969.
P.
567,
MD
­
average
of
males
and
females
.
striped.
killifish.
Carlander,
1969.
P.
567,
MD
­
average
of
males
and
females
.
striped.
killifish.
Carlander,
1969.
P.
567,
MD
­
average
of
males
and
females
.
striped.
killifish.
Carlander,
1969.
P.
567,
MD
­
average
of
males
and
females
.
striped.
killifish.
Carlander,
1969.
P.
567,
MD
­
females
only
.
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
Calculated
using
weight
and
L­
W
equation.
Calculated
as
10%
greater
than
egg
weight.
Average
of
larvae
&
age
1.
.
Assumed
by
AGret
.
Assumed
by
AGret
.
Assumed
by
AGret
.
http://
marinefisheries.
org/
fishinglines/
fish_
id2.
pdf
.
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
[
21827]
average
of
length
at
hatch
and
length
at
transition
to
juvenile
.
Status
of
sheepshead
in
Florida
waters
Tampa
Bay
(
Murphy)
.
status
of
sheepshead
in
Florida
(
Murphy)
.
extrapolated
.
status
of
sheepshead
in
Florida
(
Murphy)
.
status
of
sheepshead
in
Florida
(
Murphy)
.
extrapolated
.
extrapolated
.
extrapolated
.
extrapolated
.
extrapolated
.
extrapolated
.
extrapolated
.
extrapolated
.
extrapolated
.
extrapolated
.
extrapolated
.
extrapolated
.
Represents
weights,
not
lengths.
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
Represents
weights,
not
lengths.
Calculated
as
10%
greater
than
egg
weight.
Represents
weights,
not
lengths.
[
28558]
Represents
weights,
not
lengths.
[
28558]
Based
on
values
from
PSEG,
Appendix
L
11.
Length
of
entrainable
and
impingeable
life
sta
Average
of
ysl,
pysl,
and
pysl2
from
bay.
anchovy1
Average
of
ysl,
pysl,
and
pysl2
from
bay.
anc
Represents
weights,
not
lengths.
Length
of
entrainable
and
impingeable
life
sta
Represents
weights,
not
lengths.
Length
of
entrainable
and
impingeable
life
sta
Represents
weights,
not
lengths.
Length
of
entrainable
and
impingeable
life
sta
Represents
weights,
not
lengths.
Length
of
entrainable
and
impingeable
life
sta
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
[
25580]
average
of
min
length
at
hatching
and
length
when
fin
rays
complete.
.
[
25580]
average
yoy.
.
[
25580]
average
age01
in
spring.
.
assumed.
.
Author
Unknown.
Fishing
Lines:
Fish
Identification
Section.
http://
marinefisheries.
org/
fish.
Represents
weights,
not
lengths.
from
virtual
length
calc
in
sheet
"
lbs
from
mm
Represents
weights,
not
lengths.
Weight
calculated
from
length
(
assumed
to
b
Represents
weights,
not
lengths.
weight
estimated
by
regression
from
info
in
C
Represents
weights,
not
lengths.
weight
estimated
by
regression
from
info
in
C
Represents
weights,
not
lengths.
weight
estimated
by
regression
from
info
in
C
Represents
weights,
not
lengths.
weight
estimated
by
regression
from
info
in
C
Represents
weights,
not
lengths.
weight
estimated
by
regression
from
info
in
C
Represents
weights,
not
lengths.
weight
estimated
by
regression
from
info
in
C
Represents
weights,
not
lengths.
weight
estimated
by
regression
from
info
in
C
Represents
weights,
not
lengths.
Size­
at­
age
from
PSE&
G
1984;
L­
W
regress
Represents
weights,
not
lengths.
Size­
at­
age
from
PSE&
G
1984;
L­
W
regress
Represents
weights,
not
lengths.
Size­
at­
age
from
PSE&
G
1984;
L­
W
regress
Average
of
juv1and
juv2
from
spot1
Average
of
juv1and
juv2
from
spot1
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Represents
virtual.
length
as
calculated
in
worksheet
'
lbs.
from.
mm03'
(
V=(
Pi)
x
diameter^
3Calculated
as
V=
Pi
x
diameter^
3/
6,
assuming
Egg
weight
plus
10%
Calculated
as
10%
greater
than
egg
weight.
Cailliet
2000.
(
Butler
et
al.
1982).
16.6
SL.
Weight
based
on
LW
euation
Both:
W=
0.0001.
Represents
weights,
not
lengths.
http://
www.
dfg.
ca.
gov/
mrd/
howold.
pdf.
Kelp
b
Represents
weights,
not
lengths.
http://
www.
dfg.
ca.
gov/
mrd/
howold.
pdf.
Kelp
b
Represents
weights,
not
lengths.
http://
www.
dfg.
ca.
gov/
mrd/
howold.
pdf.
Kelp
b
Represents
weights,
not
lengths.
http://
www.
dfg.
ca.
gov/
mrd/
howold.
pdf.
Kelp
b
Represents
weights,
not
lengths.
http://
www.
dfg.
ca.
gov/
mrd/
howold.
pdf.
Kelp
b
Represents
weights,
not
lengths.
http://
www.
dfg.
ca.
gov/
mrd/
howold.
pdf.
Kelp
b
Represents
weights,
not
lengths.
http://
www.
dfg.
ca.
gov/
mrd/
howold.
pdf.
Kelp
b
Represents
weights,
not
lengths.
http://
www.
dfg.
ca.
gov/
mrd/
howold.
pdf.
Kelp
b
Represents
weights,
not
lengths.
http://
www.
dfg.
ca.
gov/
mrd/
howold.
pdf.
Kelp
b
Represents
weights,
not
lengths.
http://
www.
dfg.
ca.
gov/
mrd/
howold.
pdf.
Kelp
b
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
Virtual
larval
length
based
on
egg
wt
plus
10%
Calculated
as
10%
greater
than
egg
weight.
http://
www.
nefsc.
noaa.
gov/
nefsc/
publications/
tm/
tm141/
tm141.
pdf,
pg
1
.
Scott
and
Scott
(
1988);
#
26762;
p.
453/
North
American
coast
.
Scott
and
Scott
(
1988);
#
26762;
p.
453/
North
American
coast
.
Scott
and
Scott
(
1988);
#
26762;
p.
453/
North
American
coast
.
Scott
and
Scott
(
1988);
#
26762;
p.
453/
North
American
coast
.
Scott
and
Scott
(
1988);
#
26762;
p.
453/
North
American
coast
.
Scott
and
Scott
(
1988);
#
26762;
p.
453/
North
American
coast
.
Scott
and
Scott
(
1988);
#
26762;
p.
453/
North
American
coast
.
Scott
and
Scott
(
1988);
#
26762;
p.
453/
North
American
coast
.
assumed
by
AGret
to
be
higher
than
last
stage
.
Scott
and
Scott
(
1988);
#
26762;
p.
453/
North
American
coast
.
Scott
and
Scott
(
1988);
#
26762;
p.
453/
North
American
coast
.
Scott
and
Scott
(
1988);
#
26762;
p.
453/
North
American
coast
.
Scott
and
Scott
(
1988);
#
26762;
p.
453/
North
American
coast
.
Scott
and
Scott
(
1988);
#
26762;
p.
453/
North
American
coast
.
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
Average
of
pro
and
post
larvae
for
black
drum.
.
[
25580]
average
of
min
length
in
June
and
max
length
in
oct.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
[
21805]
average
of
length
at
hatching
and
absorption
of
yolk
sac.
Pg.
5.2­
30
.
[
27954]
Charlotte
harbor.
Females.
.
[
27954]
Charlotte
harbor.
Females.
.
[
27954]
Charlotte
harbor.
Females.
.
[
27954]
Charlotte
harbor.
Females.
.
[
27954]
Charlotte
harbor.
Females.
.
[
27954]
Charlotte
harbor.
Females.
.
[
27954]
Charlotte
harbor.
Females.
.
[
27954]
Charlotte
harbor.
Females.
.
Assumed
to
be
larger.
.
Represents
weights,
not
lengths.
Size­
at­
age
from
PSE&
G
1984;
L­
W
regress
Represents
weights,
not
lengths.
Size­
at­
age
from
PSE&
G
1984;
L­
W
regress
Average
of
juv1and
juv2
from
spot1
Average
of
juv1and
juv2
from
spot1
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Represents
weights,
not
lengths.
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
assumed
by
AGret
we
need
increment
PSEG;
1999
[
26046];
appendix
F;
Attachmen
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
based
on
V=
Pi
x
diameter
^
3/
6,
as
Virtual
length
calculated
using
egg
weight
and
L­
W
relationship
Calculated
as
10%
greater
than
egg
weight.
Sutter
et
al.,
1986,
Species
Profiles:
Black
Drum.
TR
EL­
82­
4.
(
average
of
length
at
absor.
[
25580]
average
of
min
length
in
June
and
max
length
in
oct.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
[
26572]
calculated
with
age/
TL
formula
on
p.
133.
.
Represents
weights,
not
lengths.
Appendix
L,
11.
Average
of
ysl
and
pysl
from
atlantic.
croaker1
atlantic.
croaker1
Average
of
juv1and
juv2
from
atlantic.
croaker1
atlantic.
croaker1
Represents
weights,
not
lengths.
F;
Attachment
F
Represents
weights,
not
lengths.
F;
Attachment
F
Represents
weights,
not
lengths.
F;
Attachment
F
Represents
weights,
not
lengths.
F;
Attachment
F
Represents
weights,
not
lengths.
F;
Attachment
F
Represents
weights,
not
lengths.
F;
Attachment
F
Represents
weights,
not
lengths.
F;
Attachment
F
Represents
weights,
not
lengths.
F;
Attachment
F
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Avg
of
ysl
and
pysl
from
atlantic.
menhaden1
Average
of
ysl
and
pysl
from
atlantic.
menhad
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Avg
of
ysl
and
pysl
from
atlantic.
menhaden1
Average
of
ysl
and
pysl
from
atlantic.
menhad
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Able
&
Fahay
1998
and
USFWS
1978,
L­
W
Represents
weights,
not
lengths.
Bay
anchovy
data.
Length
of
entrainable
and
Avg
of
ysl,
pysl1,
and
pysl2
from
non.
ris.
forage1
Bay
anchovy
data.
Length
of
entrainable
and
Avg
of
juv1­
juv4
from
non.
ris.
forage1
Bay
anchovy
data.
Length
of
entrainable
and
These
are
not
lengths
but
weights;
model
uses
lengths
to
implement
into
the
formula
founPSEG;
1999
[
26046];
appendix
F;
Attachmen
These
are
not
lengths
but
weights;
model
uses
lengths
to
implement
into
the
formula
founPSEG;
1999
[
26046];
appendix
F;
Attachmen
These
are
not
lengths
but
weights;
model
uses
lengths
to
implement
into
the
formula
founPSEG;
1999
[
26046];
appendix
F;
Attachmen
11.
11.
vy1
ent
F
ent
F
ent
F
G,
F­
4
Table
4.
L­
W
Regression
based
on
Hartman
1993
G,
F­
4
Table
4.
L­
W
Regression
based
on
Hartman
1993
G,
F­
4
Table
4.
L­
W
Regression
based
on
Hartman
1993
G,
F­
4
Table
4.
L­
W
Regression
based
on
Hartman
1993
G,
F­
4
Table
4.
L­
W
Regression
based
on
Hartman
1993
G,
F­
4
Table
4.
L­
W
Regression
based
on
Hartman
1993
,
assuming
1
cm^
3
=
1
g.

,
assuming
1
cm^
3
=
1
g.

,
assuming
1
cm^
3
=
1
g.

,
assuming
1
cm^
3
=
1
g.
,
assuming
1
cm^
3
=
1
g.

.
Growth
and
Variations
in
Lipid
Class
and
Fatty
Acid
Composition
During
Larval
Development
of
the
Stone
Crab,
Menippe
adina
William
,
assuming
1
cm^
3
=
1
g.

,
assuming
1
cm^
3
=
1
g.

,
assuming
1
cm^
3
=
1
g.

,
assuming
1
cm^
3
=
1
g.
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
aden1
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
,
assuming
1
cm^
3
=
1
g.

,
assuming
1
cm^
3
=
1
g.

,
assuming
1
cm^
3
=
1
g.

,
assuming
1
cm^
3
=
1
g.

,
assuming
1
cm^
3
=
1
g.
,
assuming
1
cm^
3
=
1
g.

stages
from
PSEG,
Appendix
L
11;
L­
W
Regression
based
on
Derickson
&
Price
1973.
nchovy1
stages
from
PSEG,
Appendix
L
11;
L­
W
Regression
based
on
Derickson
&
Price
1973.
stages
from
PSEG,
Appendix
L
11;
L­
W
Regression
based
on
Derickson
&
Price
1973.
stages
from
PSEG,
Appendix
L
11;
L­
W
Regression
based
on
Derickson
&
Price
1973.
stages
from
PSEG,
Appendix
L
11;
L­
W
Regression
based
on
Derickson
&
Price
1973.
ent
F
ent
F
ent
F
,
assuming
1
cm^
3
=
1
g.

mm"
o
be
similar
to
carp,
Wang,
1986)
using
the
equation:
(
1.095x
10­
5)
x
length
(
mm)
3.025
=
weight
(
g)
(
Froese
and
Pauly,
2003).
n
Collins,
1985
(
refman
34713,
pg
5)
n
Collins,
1985
(
refman
34713,
pg
5)
n
Collins,
1985
(
refman
34713,
pg
5)
n
Collins,
1985
(
refman
34713,
pg
5)
n
Collins,
1985
(
refman
34713,
pg
5)
n
Collins,
1985
(
refman
34713,
pg
5)
n
Collins,
1985
(
refman
34713,
pg
5)
ssion
from
Warlen
et
al.
1980.
ssion
from
Warlen
et
al.
1980.
ssion
from
Warlen
et
al.
1980.

ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ing
1cm^
3
=
1
gram
lp
bass.
Accessed
10/
24/
02
lp
bass.
Accessed
10/
24/
02
lp
bass.
Accessed
10/
24/
02
lp
bass.
Accessed
10/
24/
02
lp
bass.
Accessed
10/
24/
02
lp
bass.
Accessed
10/
24/
02
lp
bass.
Accessed
10/
24/
02
lp
bass.
Accessed
10/
24/
02
lp
bass.
Accessed
10/
24/
02
lp
bass.
Accessed
10/
24/
02
,
assuming
1
cm^
3
=
1
g.

,
assuming
1
cm^
3
=
1
g.
,
assuming
1
cm^
3
=
1
g.

ssion
from
Warlen
et
al.
1980.
ssion
from
Warlen
et
al.
1980.

ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
ent
F
,
assuming
1
cm^
3
=
1
g.
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
aden1
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
aden1
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
W
relationship
for
early
life
stages
calculated
from
PSE&
G
impingement,
1978­
98
nd
impingeable
life
stages
from
PSEG,
Appendix
L
11;
L­
W
Regression
based
on
Derickson
&
Price
1973.
nd
impingeable
life
stages
from
PSEG,
Appendix
L
11;
L­
W
Regression
based
on
Derickson
&
Price
1973.
nd
impingeable
life
stages
from
PSEG,
Appendix
L
11;
L­
W
Regression
based
on
Derickson
&
Price
1973.
ent
F
ent
F
ent
F
ams
and
Felder,
1986.
Invertebr.
Reprod.
Dev.
37(
2):
157­
165.
(
ERL,
GB
1087).
abstract.
At
http://
www.
epa.
gov/
ged/
publica/
cabprj30.
ht
.
htm
species
stage
fraction.
mature
mean.
fecundity
notes.
fraction.
mature
notes.
mean.
fecundity
silver.
perch
age01
0
0
assumed
assumed
silver.
perch
age02
1
52800
[
21805]
[
21805]
silver.
perch
age03
1
52800
[
21805]
[
21805]
black.
drum
age01
0
0
[
26572]
table
2
black.
drum
age02
0
0
[
26572]
table
2
black.
drum
age03
0
0
[
26572]
table
2
black.
drum
age04
0
0
[
26572]
table
2
black.
drum
age05
0.5
22,202,094
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age06
1
23,610,616
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age07
1
25,019,137
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age08
1
26,427,658
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age09
1
27,836,180
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age10
1
29,244,701
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age11
1
30,653,223
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age12
1
32,061,744
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age13
1
33,470,265
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age14
1
34,878,787
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age15
1
36,287,308
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age16
1
37,695,830
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age17
1
39,104,351
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age18
1
40,512,872
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age19
1
41,921,394
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age20
1
43,329,915
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age21
1
44,738,437
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age22
1
46,146,958
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age23
1
47,555,479
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age24
1
48,964,001
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age25
1
50,372,522
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age26
1
51,781,044
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age27
1
53,189,565
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age28
1
54,598,086
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age29
1
56,006,608
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age30
1
57,415,129
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age31
1
58,823,651
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age32
1
60,232,172
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age33
1
61,640,693
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age34
1
63,049,215
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age35
1
64,457,736
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age36
1
65,866,258
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age37
1
67,274,779
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age38
1
68,683,300
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age39
1
70,091,822
[
26572]
table
2
[
26535]
Batch
fecundity
calc
black.
drum
age40
1
71,500,343
[
26572]
table
2
[
26535]
Batch
fecundity
calc
pinfish
age01
1
21600
(
Muncy,
1984,
Species
Pro#
of
eggs
in
8
pinfish
from
1
pinfish
age02
1
21600
(
Muncy,
1984,
Species
Pro#
of
eggs
in
8
pinfish
from
1
hogchoker
egg
0
NA
[
25906],
p.
I.
34
NA
hogchoker
larvae
0
NA
[
25906],
p.
I.
34
NA
hogchoker
age01
0.5
NA
[
25906],
p.
I.
34
NA
hogchoker
age02
1
NA
[
25906],
p.
I.
34
NA
hogchoker
age03
1
NA
[
25906],
p.
I.
34
NA
hogchoker
age04
1
NA
[
25906],
p.
I.
34
NA
hogchoker
age05
1
NA
[
25906],
p.
I.
34
NA
hogchoker
age06
1
NA
[
25906],
p.
I.
34
NA
menhaden.
spp
age01
0.00
115800
Scott
and
Scott
(
1988);
#
26Dietrich
(
1979);
#
26381;
Tab
menhaden.
spp
age02
0.50
177400
Scott
and
Scott
(
1988);
#
26Dietrich
(
1979);
#
26381;
Tab
menhaden.
spp
age03
1.00
302800
Scott
and
Scott
(
1988);
#
26Dietrich
(
1979);
#
26381;
Tab
menhaden.
spp
age04
1.00
308600
Scott
and
Scott
(
1988);
#
26Dietrich
(
1979);
#
26381;
Tab
menhaden.
spp
age05
1.00
568400
Scott
and
Scott
(
1988);
#
26Dietrich
(
1979);
#
26381;
Tab
chain.
pipefish
age01
0.5
860
northern.
pipefish
Scott
&
Scnorthern.
pipefish
Scott
&
Sc
chain.
pipefish
age02
1
860
northern.
pipefish
Scott
&
Scnorthern.
pipefish
Scott
&
Sc
chain.
pipefish
age03
1
860
northern.
pipefish
Scott
&
Scnorthern.
pipefish
Scott
&
Sc
chain.
pipefish
age04
1
860
northern.
pipefish
Scott
&
Scnorthern.
pipefish
Scott
&
Sc
chain.
pipefish
age05
1
860
northern.
pipefish
Scott
&
Scnorthern.
pipefish
Scott
&
Sc
searobin
age01
0.5
NA
NA
assumed
by
AGRET
searobin
age02
1
NA
NA
assumed
by
AGRET
searobin
age03
1
NA
NA
assumed
by
AGRET
searobin
age04
1
NA
NA
assumed
by
AGRET
searobin
age05
1
NA
NA
assumed
by
AGRET
searobin
age06
1
NA
NA
assumed
by
AGRET
searobin
age07
1
NA
NA
assumed
by
AGRET
searobin
age08
1
NA
NA
assumed
by
AGRET
leatherjacket
age01
0
NA
NA
assumed
by
AGRET
leatherjacket
age02
0.5
NA
NA
assumed
by
AGRET
leatherjacket
age03
1
NA
NA
assumed
by
AGRET
leatherjacket
age04
1
NA
NA
assumed
by
AGRET
ewater.
silverside
age01
0.5
NA
Atlantic.
silverside.
p.
3
http://
www.
nwrc.
usgs.
gov/
wdb/
pu
ewater.
silverside
age02
1
NA
Atlantic.
silverside.
p.
3
http:/
NA
lifetime.
fecundity
notes.
lifetime.
fecundity
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
alculated
from
age
with
formula
49.249*
age+
530,052
and
multiplied
by
average
spawning
events
per
season
of
28.6.
111
to
152
mm
SL
(
Muncy,
1984,
Species
Profiles)
111
to
152
mm
SL
(
Muncy,
1984,
Species
Profiles)
NA
NA
NA
NA
NA
NA
NA
33465
New
England
Power
Company
(
1994);
[
25906]
p.
I.
34
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
Scott,
1988,
pg
351
Scott,
1988,
pg
351
Scott,
1988,
pg
351
Scott,
1988,
pg
351
Scott,
1988,
pg
351
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
NA
8758.25129
assume
to
same
than
radiated
shanny
NA
NA
NA
112000
Fishbase:
Atule
mate
(
also
carangidae)
NA
NA
9125
4725­
13525
p.
4
http://
www.
nwrc.
usgs.
gov/
wdb/
pub/
0117.
pdf
Life
history
dat
for
the
Gulf
of
Mexico
case
study.
Initially
compiled
on
11/
28/
2001.
A.
Gage,
7/
25/
2003
Original
file:
Q:\
Elibrary\
Intake\
databases\
bigbend.
input.
data.
xls.

Worksheet
Description
losses01
Reported
impingement
&
entrainment
losses
at
Tampa
Bay
lifehistory02
Life
history
data
for
species
impinged/
entrained
lbs.
from.
mm03
Conversion
factor
(
lbs
to
mm)
for
each
species
species.
growth04
Average
growth
per
species
per
life
stage
fecundity05
Fecundity
of
each
species
Need
to
look
at:
lifehistory02:
scaled
sardine:
check
FA
equation
leatherjacket:
Check
econ
values
spotted
seatrout,
spotted
seatrout2:
Check
equation
for
natural
mortality.
Need
to
adjust
for
F
or
F?
L­
L
equation
for
striped
mullet
TL
=
0.0
+
1.1
x
FL
Fishbase,
7/
25/
2003
area
age
length.
fl
pensacola
1
142
apalachicola
1
134
cedar
key
1
175
homosassa
1
178
pensacola
2
207
apalachicola
2
207
cedar
key
2
258
homosassa
2
269
pensacola
3
263
apalachicola
3
271
cedar
key
3
307
homosassa
3
319
pensacola
4
.
apalachicola
4
.
cedar
key
4
.
homosassa
4
366
age
avg.
length.
fl
length.
tl
1
157.25
172.975
2
235.25
258.775
3
290
319
4
366
402.6
