t
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- u.
E gC}ENCE CENTER
MARINE
TATE UNIVER3iri
OREGON
ORTS OREGON 9TSC8
jI
couege of
DEC 17
1984
OCEANOGRAPHY
i
CURRENT METER OBSERVATIONS
OVER THE CONTINENTAL SHELF
OFF OREGON AND CALIFORNIA
FEBRUARY 1981- JANUARY 1941
1
by
Donald W. Denbo
Kurt Polzin
John S. Allen
Adriana Huyer
Robert L Smith
G ON ST TE UNIVERSITY
AI-
Data Rsport 112
Rsfsusnc.84-12
mom d M 1984
Nationd Science Fog ndaton
OCE-SOM91. OCE4MO5232
College of Oceanography
Oregon State University
97331
Corvallis, Oregon
CURRENT METER OBSERVATIONS
OVER THE CONTINENTAL SHELF
OFF OREGON AND CALIFORNIA,
FEBRUARY 1981 - JANUARY 1984
by
Donald W. Denbo
Kurt Polzin
John S. Allen
Adriana Huyer
Robert L. Smith
Data Report 112
Reference 84-12
November 1984
National Science Foundation
OCE-8026131, OCE-8405232
look
15
g195 3pgp5
Abstract
A large-scale west coast shelf experiment called SuperCODE
was conducted off Oregon and California between February 1981
and April 1984.
Current and temperature measurements were made
from subsurface arrays off Coos Bay (43°N), Crescent City
(42°N), Eureka (41°N), Half Moon Bay (37.5°N) and Purisima
Point (34.70), between February 1981 and September 1982.
Some
additional measurements were made in the Santa Barbara Channel
during May - September 1982 and off Coos Bay and Eureka during
September 1982 - January 1983.
This report summarizes the
results of the measurements by presenting statistics, scatter
diagrams, progressive vector diagrams and time series plots of
hourly and the six-hourly low-passed data.
Table of Contents
page
List of Tables and Figures
Introduction
1-1
Acknowlegments
1-20
References
1-21
Hourly
data from Coos Bay
Six-hourly
Hourly
2-1
data from Coos Bay
data from Crescent
2-61
City
Six-hourly data from Crescent City
Hourly data
from Eureka
Six-hourly
Hourly data
4-19
Six-hourly
from San Fransisco
5-1
data from San Fransisco
from Purisima
3-39
4-1
Six-hourly data from Eureka
Hourly data
3-1
Point
data from Purisima
Point
Hourly data from Herman - Capitan
5-33
6-1
6-53
7-1
Six-hourly
data from Herman - Capitan
7-17
Appendix
Sampling and Processing
A-1
-
List of Tables and Figures
page
Table 1.
Instrument code, nominal depth, mooring name.
1-8
Table 2.
Moored instrumentation deployed..
1-10
Figure 1.
Location of the SuperCODE moorings.
1-3
Figure 2.
Time history for SuperCODE measurements.
1-4
Figure 3.
Shallow mooring schematic.
1-5
Figure 4.
Deep mooring schematic.
1-6
Introduction
A large-scale west coast shelf experiment (with the
unofficially adopted name of SuperCODE) was conducted off
Oregon and northern California between February 1981 and April
1984.
The objectives of this experiment were:
1) to study the large scale (200-1000 km) response of
currents on the California and Oregon shelves to large
scale atmospheric forcing on time scales of several
days (wind
events)
to several months (seasonal
variablity);
2) to study the latitudinal variations in the basic
characteristics of the shelf flow field and in the
response of the currents on the shelf to the known
latitudinal variations in the atmospheric forcing;
3) to make current measurements which
span in space and in
time the measurements made as part of the intensive
Coastal Ocean Dynamics Experiments CODE-1 and CODE-2,
centered at 38.7°N during April - August of 1981 and of
1982, (Allen, et. al, 1983),to obtain information on
the large
space and time scales
of variability in which
these local dynamics experiments are embedded.
As part of this experiment, current and hydrographic
measurements were made at different locations along the
California and Oregon coasts during February 1981 - April 1983.
Because
of the occurrence of the 1982-83 El Nitio, some
1-2
SuperCODE current and hydrographic observations were extended
until January 1984.
SuperCODE
current
This report summarizes the results of the
measurements.
The CTD data
elsewhere (Fleischbein et al., 1981;
1982;
are presented
1983a,b).
SuperCODE current measurements were initially planned at
four locations along the California and Oregon coast (43°N,
42°N, 37.5°N, 34.7°N), with two moorings at each location, from
Additional current measurements
April 1981 to September 1982.
at 38.7°N during the same time period from the long-term
component of CODE (R. C. Beardsley, Woods Hole Oceanogrphic
Insitution)
form part of the total alongshore array. The two
SuperCODE moorings at each alongshore position were designed to
measure currents and temperatures below the surface layer at
midshelf (90 m water depth;
depths)
current meters at 35 in,. 65 m
and at the shelf break (150 m water
depth;
current
meters at 35 in, 65 m depths and 25 m above the bottom).
Aanderaa current meters on taut subsurface moorings were
utilized.
The locations of the SuperCODE moorings are shown in
Figure 1 and a time history diagram summarizing the data
collected is shown in Figure 2. Schematics of the moorings are
shown in Figures 3 and 4.
Both of the moorings at Crescent
(42°N) and the deep mooring at 37.5°N were repeatedly hit
by fishermen. Thus, attempts to maintain these moorings were
City
abandoned in early
1982.
measurements at Crescent
To make up for the subsequent lack of
City,
a single mid-shelf mooring was
deployed off Eureka (41°N) from February 1982 to April 1983.
1-3
g
Figure I. Location of
the SuperCODE
moorings.
91 m
ES
85m
HS
CS
88M
93m
PPD 155 m
PPS
95m
80m
SFD 133m
SFS
Figure 2.
34° 24'N
34°43'N
37°22'N
56,71
37
37,67
1981
34,64,124
, 39,69
35,65
46,76,136
, 40,70
F 105
I
35
38,71,132
138,68
3567
1982
4_
35,65
140,70
+42,72,139
36
141, 71,111
35,65
, 36,66
47177
, 40
38,68
II
L5
1983
F
1984
'J'A*S O N DIJ
,39,67,67 ,35,65
Deployment and recovery time history for SuperCODE measurements
M '
39,69,129
l-i
35,68
'38,70,110 0
I
35,65
37,65,130
, 35,64,107
+44,69,113
56,68,108
,35,65
+74
4 4,72
,51,83
I--II
CCD 149m j- -I
CCS
38°37°N C3 90m
40053'N
41°54'N
97m
430 08'N
CBD 130 m
CBS
I
1-5
MOORING SCHEMATIC
SUPERCODE SHALLOW
CRAB POT MARKER FLOAT
NEUTRALLY BUOYANT NYLON LINE
--29 INCH STEEL SPHERE (350 lb. buoyancy)
-5m 1/4" GALVANIZED WIRE ROPE
B 12 VINY FLOAT (40 lb. buoyancy)
35 m 01
AANDERAA RCM-5 CURRENT METER
E--17 INCH BENTHOS GLASS SPHERE
(56 lb. buoyancy)
ACOUSTIC RELEASE
CONCRETE
BLOC K --.k
Figure 3.
Schematic for shallot current meter moorings used
during SuperCODE
1-6
MOORING SCHEMATIC
SUPERCODE DEEP
CRAB POT MARKER FLOAT
NEUTRALLY BUOYANT NYLON LINE
29 INCH STEEL SPHERE (350 lb. buoyancy)
--- 5m 1/4" GALVANIZED WIRE ROPE
Qom- B 12 VINY FLOAT (40 lb. buoyancy)
35m 0
AANDERAA RCM-5 CURRENT METER
27m WIRE ROPE
0
8
65m 0
--WIRE ROPE CUT TO FIT DEPTH
25m
above bottom
8
I
I--i9m WIRE ROPE
O--17 INCH BENTHOS GLASS SPHERE
(56 lb. buoyancy)
ACOUSTIC RELEASE
RR
WHEEL-,,y
CONCRETE
BLOCK
"-WIRE ROPE
Figure 4.
Schematic for deep current meter moorings used
during SuperCODE.
1-7
In
addition,
a single shallow mooring at Coos Bay was
redeployed in April and July 1983 and was recovered in January
1984.
In this data report, the mooring
are designated
and instrument
by a four-character code;
follows the format used in the CODE data
Rosenfeld,
1983).
Y
Crescent City, E Eureka,
Point, R
this designation
reports (Beardsley and
The first letter signifies
in which the mooring was deployed:
Herman, and N
H
Q
the general area
represents Coos Bay,
San Francisco, P
Capitan.
locations
Purisima
The second character, a
number "3" or "4", signifies either a shallow
or a deep
mooring; a "3" indicates a mooring located near the 90 meter
isobath, and a "4" the 150 meter isobath. The actual depths at
which the
moorings were deployed are tabulated at the beginning
of the data presentation.
The third character,
indicates a subsurface mooring.
always an "S",
The last number represents the
relative position of the instrument on that particular mooring,
increasing
in order of
increasing
depth.
For
example, Q35l
represents the top instument on the Coos Bay Shallow mooring
and P4S2 designates the second instument on the Purisima Point
Deep mooring.
Table 1 contains a summary of the four-character
code, nominal depth and mooring name.
1-8
Table 1.
Summary of the four-character instrument code. nominal
depth and mooring name used during SuperCODE.
INSTRUMENT
CODE
NOMINAL
DEPTH
MOORING
NAME
(m7
Q3S1
O3S2
Q4S1
Q4S2
Q4S3
35
65
35
65
105
Coos Bay Shallow
Y3S1
Y3S2
Y4S1
Y4S2
Y4S3
35
65
35
65
125
Crescent City Shallow
E3S1
E3S2
35
65
Eureka Shallow
H3S1
H3S2
H4S1
H4S2
H4S3
35
San Fransisco Shallow
35
65
100
San Fransisco Deep
P3S1
P3S2
P4S1
P4S2
P4S3
35
65
35
65
125
Purisima Point Shallow
N3S1
N3S2
35
65
Capitan Shallow
R3S1
R3S2
35
65
Herman Shallow
Coos Bay Deep
Crescent City Deep
65
Purisima Point Deep
1-9
All current meters were equipped with speed, direction,
and temperature sensors.
Some current meters were also
Only the
equipped with pressure and/or conductivity sensors.
results of the velocity and temperature measurements are
presented in this
report.
A summary of the dates and locations
of the measurements appears in the Table 2.
An explanation of
the data processing and calibration procedures is given in the
Appendix.
The data return
is summarized in Table 2.
No data were
recovered from eight of the 87 instruments deployed.
incurred tape failures at the outset and the other
Two
six were
lost after being torn from their moorings by fishing boats.
An
additional nineteen have short records due to being hit by
fishing
boats.
Athough some of these moorings were merely
moved to a different location, all data were truncated at the
time of the encounter. For various other reasons, there are
five other instrument sets in which the data records are short.
In this report, we present both hourly data (filtered with
a half-power point of 2.9 hours) and six-hourly low-passed data
(with a half-power point of 46.6 hours) in which tidal and
inertial oscillations are removed.
operations are given in the
Details of the filtering
Appendix.
Basic statistics and
complete plots are included for both the hourly and the
The statistics presented are
means, standard deviations and principal axes. The units are
six-hourly low-passed data.
1-10
Table 2.
Moored instrumentation deployed
during SuperCODE.
MOORING
SET
MOORING
STATION! WATER INST. LATITUDE
LONGITUDE
DEPTH DEPTH
(m)
(m)
N
W
41
41 54.1
124 26.8
02/05/81 05/01/81
71
37
67
41 52.9
124 30.2
02/05/81 04/09/81
LOST
LOST
34 44.6
120 47.1
02/07/81 05/06/81
MOORING
RETRIEVED
DATA
COLLECTED
TAPE
NUMBER
DEPLOYMENT A
Y3S1
Y3S2
Y4S1
Y4S2
Y4S3
P3S1
P3S2
P4S1
P4S2
P4S3
97
97
146
146
146
91
127
37
91
67
155
155
155
39
69
129
U,V,T,P,C
U,V,T,P,C
U,V,T,P
U,V,T,P,C
U,V,T,P
U,V,T,P
U,V,T
746/41
1543/20
499/53
XXX/8
748/50
751/39
688/57
755/36
1237/22
2280/16
U.V,T,P,C
U,V,T
U,V,T,P,C
U,V.T,P,C
U,V,T,P,C
U,V,T,P,C
3621/10
1968/23
1541/22
1542/21
3123/19
2276/18
1544/23
4044/10
4045/12
U,V,T,P
U,V,T,P
U,V,T,P
U,V,T,P
U,V,T
U,V,T,P
U,V,T
U,V,T,P
U,V,T
U,V,T
1241
2759/4
2760/4
5211/5
756/38
3615/5
4916/10
4921/7
1534/17
4411/7
3125/19
34 42.9
120 50.7
02/07/81 05/06/81
U,V,T,P
U,V,T
U,V,T
43
8.2
124 34.1
04/29/81 08/13/81
U.V,T.P,C
U,V,T,P,C
43
7.9
124 37.4
04/29/81 08/13/81
DEPLOYMENT B
03SI
Q3S2
Q4S1
0452
04S3
Y3S1
Y3S2
Y4S1
Y4S2
Y4S3
H3S1
H3S2
H4S1
H4S2
H4S3
P3S1
P3S2
P4S1
P4S2
P4S3
97
97
130
130
130
90
90
148
148
148
75
75
132
132
132
96
96
143
143
143
51
83
36
68
108
35
65
31
63
121
35
68
38
70
LOST
LOST
41 53.2
124 26.2
05/01/81
41 53.4
124 30.5
05/01/81 05/22/81
07/02/81
37 22.2
122 30.9
04/22/81 08/16/81
37 22.4
122 50.7
05/07/81 06/04/81
34 44.6
120 47.1
05/06/81 08/17/81
34 42.3
120 50.6
05/06/81 08/17/81
100
39
69
34
64
124
DATA
STATION/
RETURN
MOORING
DEPLOYMENT A
Y3S1
Y3S2
Y4S1
Y4S2
Y4S3
P3S1
P3S2
P4S1
P4S2
P4S3
PRESSURE SENSOR CALIBRATIONS DRIFTED
COMPLETE
ALL DATA TRUNCATED (1)
NOT RECOVERED (1)
NOT RECOVERED (1)
LATTER U,V SUSPECT. CAUSE:FOULING
COMPLETE
COMPLETE
COMPLETE
COMPLETE
DEPLOYMENT B
03S1
03S2
Q4SI
04S2
0453
Y3S1
Y3S2
Y4S1
Y4S2
Y4S3
H3S1
H3S2
H4S1
H4S2
H4S3
P3S1
P3S2
P4S1
P4S2
P4S3
COMPLETE
TWO SMALL SECTIONS OF SUSPICIOUS CONDUCTIVITY
COMPLETE
COMPLETE
COMPLETE
NOT RECOVERED (1)
NOT RECOVERED (1)
ALL DATA TRUNCATED (1)
ALL DATA TRUNCATED (2)
TAPE FAILURE, NO DATA RECOVERED
COMPLETE
COMPLETE
ALL DATA TRUNCATED (1)
P SHORT; ALL DATA TRUNCATED (1)
ALL DATA TRUNCATED (1)
COMPLETE
COMPLETE
PT SHORT
U,V SHORT
COMPLETE
1-12
Table 2.
Moored instrumentation deployed during SuperCODE.
(continued)
STATION/ WATER INST. LATITUDE
N
MOORING DEPTH DEPTH
(m)
(m)
LONGITUDE
MOORING
W
SET
MOORING
RETRIEVED
DATA
COLLECTED
TAPE
NUMBER
DEPLOYMENT C
03S1
Q3S2
04S1
04S2
Q4S3
Y331
Y3S2
Y4S1
Y4S2
Y4S3
H3S1
H3S2
H4S1
H4S2
H4S3
P3S1
P3S2
P4S1
P4S2
P4S3
97
97
131
131
131
93
93
148
148
148
81
81
134
134
134
95
95
157
157
157
43
8.5
124 33.7
08/13/81 01/28/82
43
7.8
124 37.5
08/13/81 01/28/82
35
65
32
62
122
35
65
35
65
105
41 54.4
124 27.0
08/14/81 11/03/82
41 53.8
124 30.8
08/14/81 01/29/82
37 21.8
122 38.8
08/16/81 01/30/82
37 22.5
122 50.9
08/16/81
40
34 45.3
120 47.3
03/06/82
08/17/81 01/31/82
70
46
34 42.4
120 50.9
08/17/81 01/31/82
43
9.2
124 33.9
01/28/82 05/19/82
43
9.1
124 37.8
01/28/82 05/19/82
41 54.0
124 26.3
01/29/82 02/08/82
41 54.2
124 31.0
01/29/82 03/07/82
05/20/82
40 52.5
124 20.3
02/27/82 05/21/82
37 21.6
122 39.0 01/30/82 05/22/82
34 45.0
120 47.2
01/31/82 05/23/82
34 42.1
120 50.9
01/31/82 05/23/82
44
72
44
69
113
LOST
LOST
76
136
U,V,T,P,C
U,V,T,P,C
U,V,T,P,C
U,V,T,P,C
U,V,T,P
U,V,T,C
U,V,T,C
U,V,T,C
U,V,T,C
U,V,T,P
U,V,T
U,V,T,P
U,V,T,P
U,V,T,P,C
U,V,T
U,V,T
U.V,T,P
U,V,T
U,V,T,P
U,V,T
5645/5
5646/5
5644/5
5643/5
1323/17
2519/4
1965/10
760/15
1495/9
408/5
1966/6
1759/10
1321/18
3621/11
842/15
1326/18
1319/11
2265/13
762/18
2266/13
U,V,T,P,C
U,V,T,P,C
U,V,T,P,C
U,V,T,P,C
U,V,T,P
U,V,T,P,C
U,V,T,P
U,V,T,P,C
U,V,T,P,C
U,V,T,P
U,V,T
U,V,T,P
U,V,T,P
U,V,T,P
U,V,T,P
U,V,T,P
U,V,T,P
U,V,T,P
U,V,T,P
4044/15
4045/15
5647/5
5648/5
3481/10
1541/27
1968/30
746/47
5649/5
407/4
841/13
756/42
1542/28
1543/25
3615/9
755/40
2759/8
2760/9
5211/9
DEPLOYMENT D
03S1
03S2
Q4S1
04S2
04S3
Y3S1
Y3S2
Y4S1
Y4S2
Y4S3
E3S1
E3S2
H3S1
H3S2
P3S1
P3S2
P4S1
P4S2
P4S3
96
96
126
126
126
89
89
150
150
150
86
86
82
82
95
95
153
153
153
42
74
35
64
107
35
65
37
65
130
35
65
35
67
38
68
38
71
132
DATA
STATION/
RETURN
MOORING
DEPLOYMENT C
(3)
(4)
0352
U,V MISSING DATA
U,V MISSING DATA
Q4S1
COMPLETE
04S2
04S3
U,V MISSING DATA
Y3S1
Y3S2
Y4S1
Y4S2
Y4S3
H3S1
H3S2
H4S1
H4S2
H4S3
ALL DATA TRUNCATED (1)
P3SI
COMPLETE
P3S2
P4S1
P4S2
P4S3
PRESSURE SUSPECT DUE TO OUESTIONABLE SENSOR
03S1
(5)
COMPLETE
ALL DATA TRUNCATED (1); UV MISSING DATA (6)
ALL DATA TRUNCATED (2)
ALL DATA TRUNCATED (2)
ALL DATA TRUNCATED (2)
COMPLETE
COMPLETE
NOT RECOVERED (1)
NOT RECOVERED (1)
ALL DATA TRUNCATED (1)
U,V SHORT; ALL DATA TRUNCATED (2)
ALL DATA TRUNCATED (2)
ALL DATA TRUNCATED (2)
DEPLOYMENT D
03S1
ALL DATA SHORT
Q3S2
COMPLETE
04S1
CONDUCTIVITY CALIBRATION DRIFTED
Q4S2
COMPLETE
COMPLETE
04S3
Y3S1
Y3S2
Y4S1
Y4S2
Y4S3
E3S1
E3S2
H3S1
H3S2
P3S1
P3S2
P4S1
P4S2
P4S3
ALL DATA TRUNCATED (1)
ALL DATA TRUNCATED (1)
P MISSING DATA (7), CALIBRATION DRIFTED;
U,V SHORT
COMPLETE
COMPLETE
P FAILED
ALL DATA SHORT,P FAILED
COMPLETE
COMPLETE
U,V,P SHORT
COMPLETE
COMPLETE
COMPLETE
ALL DATA TRUNCATED (1)
1-14
Table 2.
Moored instrumentation deployed during SuperCODE.
(continued)
STATION/ WATER INST. LATITUDE
N
MOORING DEPTH DEPTH
(m)
(m)
LONGITUDE
MOORING
W
SET
MOORING
RETRIEVED
DATA
COLLECTED
TAPE
NUMBER
DEPLOYMENT E
0351
03S2
0451
Q4S2
0453
E3S1
E3S2
H3S1
H3S2
P3S1
P3S2
P4S1
P4S2
P4S3
N3S1
N3S2
R3S1
R3S2
99
99
133
133
133
84
84
83
83
95
95
155
155
155
86
86
93
93
47
43
9.5
124 35.2
05/19/82 09/08/82
43
8.9
124 38.0
07/07/82 09/08/82
77
41
71
111
36
40 52.4
124 19.5
05/21/82 09/10/82
66
35
65
37 22.0
122 38.8
05/22/82 09/11/82
40
34 45.9
120 46.9
05/23/82 09/12/82
34 42.9
120 50.7
05/23/82 09/12/82
34 24.2
120
2.6
05/24/82 09/12/82
34 23.6
120 24.9
05/24/82 09/12/82
70
42
72
139
35
65
43
73
U,V,T,P,C
U,V,T,P,C
U,V,T,P,C
U,V,T,C
U,V,T
U.V,T,C
U,V,T,P,C
U,V,T
U,V,T,P
U,V,T
U,V,T,P
U,V,T,P
U,V,T
U,V,T,P
U,V,T,C
U,V,T
U,V,T
U,V,T,P
5646/9
5645/9
5644/11
760/18
688/62
1495/12
1541/31
1966/11
408/9
6088/3
762/23
1759/15
6087/3
1964/23
1965/14
751/43
2281/16
1319/15
U,V,T,P,C
U,V,T,P,C
U,V,T,P,C
5647/9
5648/9
4045/20
4044/19
DEPLOYMENT E
03S1
03S2
E3S1
E3S2
100
100
38
68
43
9.7
124 34.5
09/08/82 04/15/83
91
91
40
40 52.4
124 19.9
09/10/82 04/14/83
70
DEPLOYMENT G
Q3S1
03S2
99
99
39
67
43
9.5
124 34.6
04/15/83 07/12/83
U,V,T,P,C
U,V,T,P,C
1495/18
4045/21
35
65
43
9.5
124 34.4 07/12/83 01/31/84
U,V,T,P
U,V,T,P,C
1968/35
746/54
DEPLOYMENT H
03S1
03S2
97
97
STATION/
DATA
MOORING
RETURN
DEPLOYMENT E
0351
COMPLETE
Q3S2
NUMEROUS SECTIONS OF LOW CONDUCTIVITY BRIDGED
COMPLETE
COMPLETE
COMPLETE
CONDUCTIVITY LOW IN TWO SMALL SECTONS
ALL DATA SHORT
COMPLETE
COMPLETE
COMPLETE
U.V FAILED
U.V MISSING DATA (8), BRIDGED (9)
COMPLETE
COMPLETE
U.V MISSING DATA (10), BRIDGED (11)
COMPLETE
U,V MISSING DATA (12)
COMPLETE
0451
04S2
04S3
E3S1
E3S2
H3S1
H3S2
P3S1
P3S2
P4S1
P4S2
P4S3
N3S1
N3S2
R3S1
R3S2
DEPLOYMENT F
03S1
Q3S2
E3S1
E3S2
COMPLETE
COMPLETE
COMPLETE
TAPE FAILURE,NO DATA RECOVERED
DEPLOYMENT G
03S1
03S2
ALL DATA SHORT;
COMPLETE
U,V.T,P,C MISSING DATA
DEPLOYMENT H
03S1
Q3S2
ALL DATA SHORT. P FAILED
COMPLETE
(13)
1-16
Table 2.
Moored instrumentation deployed during SuperCODE
(continued)
NOTES
(1)
(2)
MOORING BROKE UP AFTER BEING STRUCK BY FISHING BOAT
MORING WAS MOVED AFTER BEING STRUCK BY FISHING BOAT
MISSING DATA AND BRIDGE TIMES
(3)
(4)
(5)
(6)
(7)
(8)
(9)
(10)
(11)
(12)
(13)
08/27/81
09/24/81
09/13/81
10/17/81
01/30/82
08/05/82
06/11/82
07/20/82
08/16/82
08/03/82
05/17/83
0000
0000
1300
1200
0300
0300
0200
0200
1700
1400
1900
-
09/08/81
10/26/81
10/19/81
10/21/81
02/02/82
08/10/82
06/11/82
08/05/82
08/17/82
08/06/82
05/24/83
0600
1200
0600
0600
1100
0000
1300
0500
0300
2200
1700
294
780
857
90
80
117
11
387
10
80
166
hrs
hrs
hrs
hrs
hrs
hrs
hrs
hrs
hrs
hrs
hrs
DATA SHORT => INDIVIDUAL METER FAILED DURING DEPLOYMENT, PARTIAL DATA RECORD
DATA FAILED => INDIVIDUAL METER FAILED AT THE TIME OF DEPLOYMENT, NO RECORD
ALL DATA SHORT => EQUIPMENT FAILURE DURING DEPLOYMENT, PARTIAL RECORD
1-17
always cm/sec for velocity and °C for temperature.
The
princpal axes (Kundu and Allen, 1976) are specified by the
number of degrees rotation, positive clockwise from north, of
the major principal axis.
The data report is organized by mooring group location in
order of decreasing latitude, i.e.
all data from Coos Bay,
appears for the complete time in which that mooring group was
deployed followed by all data from Crescent City, etc.
The
data is divided into 8 distinct time periods (A - H)
corresponding to the installation and retrieval of the
instruments for maintainance (Table 2).
A bathymetric map of
the surrounding area showing the exact mooring locations,
marked with an A - H to denote deployment period, is presented
before the data from that mooring group.
presentation is as follows:
The order of data
statistics of the hourly
data; scatter plots and progressive vector diagrams of hourly
data; time series of
hourly velocity components and
temperature; statistics of the six-hourly
low-passed data; time
series of the six-hourly current vectors (one which encompasses
the entire SuperCODE time period and others by deployment
period); and time series of six-hourly velocity components and
temperature.
The hourly time series plots are presented in 3
month sections.
All others, with the exception of the entire
time period vector
plots,
are presented by deployment period.
1-18
The scale for the velocity components and velocity
vectors, in
both the hourly and six hourly plots, is 1 tic
equals 10 cm/s.
0.5°C.
For the temperature
Scaling for the
hourly data
hourly data.
plots, 1
tic represents
time axes was kept constant
for all the
and constant at a different value for all the six
One small tic on the time axis represents 5 days.
The scatter plots and the progressive vector diagrams were
auto-scaled to fit within a certain size boundary as their
range varied by a factor of 50.
with two exceptions, is north u being positive east and v positive north. The mean
The co-ordinate
south;
system,
currents at Capitan and Herman are to the west, and the data
for the vector time series at those locations are rotated by
-90 degrees, i.e. west appears at the top of the plot. In all
other plots for Captitan and Herman, the north - south
convention for u and v is kept.
A total of eight u,v records had sections of bad data.
These records and times are noted in the data synopsis (Table
2). The ,gaps were excluded from calculations of the
In the progressive vector diagrams, the start and
stop times of missing data are shown on the plots. The gaps
are by convention spaced either 250 or 75 km in either the
north-south or east-west direction. The progressive vector
diagrams are marked with an asterik (*) every 360 data points
(once every fifteen days). Asterisks that would occur during
statistics.
1-19
periods of missing data are suppressed.
The first asterisk to
appear after a data gap occurs at some multiple of fifteen days
from the date of the last asterisk.
In the scatter plots, data
points below the threshhold level, which for the Aanderaa
meters in this experiment is 1.5 cm/sec, are not plotted.
The
vector time series are plotted from the six-hourly low-passed
data at a twelve hourly sampling rate;
the vector time series
for the entire SuperCODE time period are plotted at a daily
sampling rate.
1-20
Acknowledgments
The SuperCODE experiment was funded by the National
Science Foundataion through Grants OCE-8026131 and OCE-8405232.
The current measurements were made by the OSU bony group under
R. D.
Pillsbury.
cruises.
Robert Still was on most of the mooring
Dennis Root and Joseph Bottero performed the initial
data processing.
The Sea Grant Marine Extension Agents and
Advisors in Oregon and California provided liason with the
fishing community; we are indebted to Paul Heikkila, Ed
Melvin, John Richards, Chris Toole and Jim Waldvogel for their
assistance.
1-21
References
J. S., R. Beardsley, W. Brown, D. Cacchione, R. Davis,
D. Drake, C. Friehe, W. Grant, A. Huyer, J. Irish,
M. Janopaul, A. Williams and C. Winant (The CODE group),
Coastal Ocean Dynamics, EOS, 64 (36), 538-539.
1983.
Allen,
Beardsley,
R. C., and L. K.
Rosenfeld, 1983.
Introduction to
the CODE-1 Moored Array and Large Scale Data Report, In
CODE-1: Moored Array and Large-Scale Data Report, pp
1-16, WHOI Technical Report 83-23, Woods Hole
Oceanographic Institution, Massachusetts, 186 pp.
J., W. E. Gilbert, R. Schramm and A. Huyer,
CTD observations off Oregon and California, 5-17
February 1981. Oregon State University, School of
81-16, 122 pp.
Oceanography, Data Report 89, Ref.
Fleischbein,
1981.
J., W. E. Gilbert, A. Huyer, R. L. Smith, 1982.
CTD observations off Oregon and California: R/V Wecoma,
W8201B, 28 January to 6 February 1982. School of
Oceanography, Oregon State University, Data Report 100,
Ref. 82-18, 55 pp.
Fleschbein,
Fleischbein,
J., W. E. Gilbert and A.
observations off Oregon and
CTD
Huyer, 1983.
R/V Wecoma,
California:
W8205A and Code 2 Leg 8, 18 May - 4 June 1982. School of
Oceanography, Oregon State Univeristy, Data Report 104,
Ref. 83-10, 149 pp.
J., R. E. Schramm, A. Huyer and R. L. Smith,
CTD observations off Oregon and California: R/V
School of
Wecoma, W8209A, 7-24 September 1982.
Oceanography, Oregon State Univeristy, Data Report 106,
Fleischbein,
1983.
Ref.
83-13.
107 pp.
and J. S. Allen, 1976. Some three-dimensional
characteristics of low-frequency current fluctuations near
Kundu, P. K.
the Oregon coast.
J.
Phys. Oceanogr.,
6, 181-199.
Pillsbury, R. D., J.
S. Bottero, R. E. Still and
W. E. Gilbert, 1974. A compilation of observations
from
Oregon continental
shelf April - October 1972. Oregon State University,
School of Oceanography, Data Report 57, Ref. 74-2.
moored current meters.
Pillsbury, R. D., F.
Volume VI:
Sciremammano, Jr., J. S. Bottero and
R. E. Still, 1980. A compilation of observations from
moored current meters. Volume XII: Currents, temperature
and pressure in the Drake Passage during F DRAKE 77, 78.
Oregon State University,
January 1977 - January 1979.
80-11.
School of Oceanography, Data Report 82, Ref.
1-22
COOS BAY
124030'
1250
too
ry
Coos Bay
(Q3, Q4)
SOUNDINGS IN METERS
0
5
km
10
APE 'ARAGO
15
t
Eg
G
C
ck.
o
o
0
,
ZOO
t
'.COQUILLE PT.
;'
;=
N
430
yO
IN
r-
,
2-4
SAMPLING INTERVAL = 60 MINUTES
STATION
Q3S1
Q3S1
START TIME -(GMT)
APR 30,1981
AUG 14,1981
0000
0400
MIN
JAN 29,1982
0300
Q3S1
Q3S1
MAY 20,1982
SEP
8,1982
APR 26,1983
0400
1908
2300
18.8
27.0
-0.3
-2.8
6.8
13.0
T
7.1
9.8
8.1
0.4
U
-36.7
-49.9
53.4
89.4
1.8
8.2
10.8
20.1
7.9
14.0
10.6
1.6
-28.5
-53.2
22.7
30.3
-19.1
-5.9
9.7
10.2
10.0
10.0
21.9
0.1
-33.2
-1.7
-1.7
7.6
14.1
U
Q3S2
JUL
12,1983' 1659
APR 30,1981
0000
AUG 14,1981
0400
Q3S2
Q3S2
JAN 29,1982
MAY 20,1982
SEP
8,1982
0300
0400
1909
1300
1300
1300
DEC 22,1981
DEC 22,1981
JAN 28,1982
1800
1800
1000
FEB
FEB
FEB
4,1982
4,1982
4,1982
1100
1100
1100
SEP
SEP
SEP
8,1982
8,1982
8,1982
0900
0900
0900
-70.9
T
7.2
10.8
8.6
0.7
U
V
-49.4
-82.4
58.5
75.3
2.6
8.5
T
8.6
14.5
11.7
12.8
23.6
1.1
APR 15,1983
APR 15,1983
APR 15,1983
1508
1508
1508
U
-36.7
-70.6
8.0
17.9
-0.7
33.7
12.1
-6.2
10.0
7.9
20.6
1.4
JUN 13,1983
JUN 13,1983
JUN 13,1983
2000
2000
2000
U
V
-23.4
-45.9
31.6
63.2
0.6
4.6
15.6
T
8 .6
16 . 3
10 . 3
1.2
4,1983
4,1983
4 , 1983
0859
0859
0859
U
-29.7
-30.5
6.2
19.5
33.3
-0.7
6.4
2.6
7.5
10.2
0.4
AUG 13,1981
AUG 13,1981
AUG 13,1981
1300
1300
1300
-38.8
-41.1
31.4
75.2
13.5
-0.2
7.8
16.0
6.2
9.7 - 1.5
JAN 28,1982
JAN 28,1982
JAN 28,1982
1000
1000
1000
-0.9
8.5
1.3
17.8
9.0
0.9
MAY 19,1982
MAY 19,1982
MAY 19,1982
1300
1300
1300
-1.0
8,1982
8,1982
8,1982
0900
0900
0900
APR 15,1983
-APR 15,1983
APR 15,1983
1509
1509
1509
U
V
T
Q3S2
AUG 13,1981
AUG 13,1981
AUG 13,1981
V
V
T
Q3S2
STOP TIME
20.4
40.0
U
V
T
Q3S1
STD
-27.7
-42.1
V
T
Q3S1
MEAN
U
V
V
T
Q3S1
MAX
7.6
8.4
8.3
U
-47.0
V
T
-53.0
6.7
26.1
60.7
10.3
U
-27.3
19.8
V
-43.7
34.5
2.2
11.5
T
6.8
9.8
8.1
0.6
U
-34.4
-51.3
8.0
40.4
1.2
74.4
8.8
14.2
11.2
10.7
19.6
1.2
V
T
6.8
NOV
NOV
NOV
SEP
SEP
SEP
2-5
SAMPLING INTERVAL = 60 MINUTES
STATION
Q3S2
START TIME -(GMT)
APR 16,1983
0200
MIN
MEAN
-37.2
-46.7
7.2
19.1
46.7
11.1
-0.9
7.8
JUL 12,1983
3.8
8.8
15.5
0.9
JUL 12,1983
JUL 12,1983
0900
0900
0900
U
V
T
-29.5
-46.5
8.3
36.7
56.1
14.4
1.0
7.4
10.6
9.1
16.8
1.5
JAN 31,1984
JAN 31,1984
JAN 31,1984
1457
1457
1457
U
-33.2
28.7
V
T
-58.3
36.2
10.5
-1.8
-11.8
8.8
10.0
15.6
0.5
AUG 13,1981
AUG 13,1981
AUG 13,1981
0900
0900
0900
U
-45.7
61.1
1.5
12.6
V
-71.0
4.4
21.2
T
7.9
117.1
13.7
10.7
1.5
JAN 28,1982
JAN 28,1982
JAN 28,1982
1500
1500
1500
U
-51.3
-78.3
T
8.6
63.5
98.7
10.4
-4.9
V
15.3
29.7
0.3
MAY 19,1982
MAY 19,1982
MAY 19,1982
0900
0900
0900
U
-23.6
-39.6
8.0
22.7
32.6
11.3
8,1982
8,1982
SEP _8,1982
1200
1200
V
T
-22.1
-43.2
7.0
21.1
25.8
AUG 13,1981
AUG 13,1981
AUG 13,1981
0800
0800
0800
U
-41.1
V
T
-48.3 103.0
7.7
13.6
JAN 28,1982
JAN 28,1982
JAN 28,1982
1500
1500
1500
U
-40.5
-70.4
51.1
U
V
T
Q3S2
Q4S1
Q4S1
Q4S1
Q4S1
JUL 12,1983
APR 30,1981
AUG 14,1981
JAN 29,1982
JUL
8,1982
1757
0400
0100
0500
1200
V
T
Q4S2
Q4S2
Q4S2
APR 30,1981
AUG 14,1981
JAN 29,1982
0400
0100
0500
U
JUL
8,1982
1200
APR 30,1981
0400
AUG 14,1981
0100
9.8
-2.2
-6.1
8.8
12.7
9.1
0.5
0.2
7.6
13.4
9.2
7.9
0.4
37.6
1.4
5.7
9.8
10.2
19.4
-2.2
1.5
SEP
SEP
1200
16.8
41.8
9.9
-1.4
6.8
11.2
0.3
SEP
SEP
SEP
-22.6
-33.6
5.9
20.8
30.6
-0.7
8.0
7.2
V
-34.8
-43.2
T
7.1
29.0
87.5
13.2
U
U
V
T
Q4S3
-13.6
MAY 19,1982 0900
V
T
Q4S3
7.6
STD
-3.3 12.9
-8.3 26.0
9.5,_ 0.5
V
T
Q4S2
STOP TIME
MAX
U
7.4
-20.9
-27.8
7.8
80.0
10.3
MAY 19,1982
MAY 19,1982
0900
8,1982
8,1982
8,1982
1300
1300
1300
6.3
12.0
0.3
AUG 13,1981
AUG 13,1981
AUG 13,1981
0800
0800
0800
-0.2
8.2
7.6
8.8
13.2
JAN 28,1982
-JAN 28,1982
JAN 28,1982
1500
1500
1500
0.6
8.6
4.3
1.0
0900
SAMPLING INTERVAL = 60 MINUTES
STATION
Q4S3
START TIME -(GMT)
JAN 29,1982
0600
MIN
U
V
T
Q4S3
JUL
8,1982
1200
U
V
T
STD
MAX
MEAN
-34.3
-57.9
6.1
24.4
62.9
-0.3
8.4
2.4
17.6
10.2
8.6
0.8
-22.4
-41.9
15.4
39.3
8.7
-1.2
5.9
11.9
7.5
3.8
8.1
0.3
STOP TIME
MAY 19,1982 .1000
MAY 19,1982 1000
MAY 19,1982 1000
SEP
SEP
SEP
8,1982
8,1982
8,1982
1200
1200
1200
EAST km
V Component
(NORTH)
U Component
(EAST)
Q3S 1
APR 30,1981
0000
-
AUG 13,1981
1300
NORTH km
1000 T
AUG 27,1981 0000 SEP 8 , 1981 0600
-- EAST km
-200
400
200
-200
V Component
(NORTH)
U Component
(EAST)
Q3S 1
AUG 14,1981
0400
-
DEC 22,1981
1800
V Component
(NORTH)
U Component
(EAST)
Q3S1
JAN 29,1982 0300
-
FEB 4,1982 1100
2-10
NORTH km
50 -
50
-300
V Component
(NORTH)
U Component
(EAST)
Q3S1
MAY 20,1982 0400
-
SEP 8,1982 0900
NORTH km
2500 --
-500 1
V Component
(NORTH)
U Component
(EAST)
Q3S 1
SEP 8,1982
1908
-
APR 15,1983
1508
NORTH km
100 T
(o
EAST km
50
MAY 17,1983 1900 MAY 24,1983 1700
V Component
(NORTH)
U Component
(EAST)
Q3S 1
APR 26,1983 2300
-
JUN 13,1983 2000
EAST km
/
-100
100
I
t,.,i
100
V Component
(NORTH)
U Component
(EAST)
Q3S 1
JUL 12,1983
1659
-
NOV 4,1983 0859
NORTH km
250 T
200
-50 -yV Component
(NORTH)
U Component
(EAST)
Q3S2
APR 30,1981
0000
-
AUG 13,1981
1300
600
400
SEP 24,1981 0000 200
OCT 26,1981 1200
EAST km
-200
200
-200
V Component
(NORTH)
U Component
(EAST)
Q3S2
AUG 14,1981
0400
-
JAN 28,1982
1000
EAST km
V Component
(NORTH)
U Component
(EAST)
Q3S2
JAN 29,1982 0300
-
MAY 19,1982
1300
NORTH km
250
EAST km
- 150
V Component
(NORTH)
-
U Component
(EAST)
Q3S2
MAY 20,1982 0400
-
SEP 8,1982 0900
NORTH km
2000 -,-
EAST km
V Component
(NORTH)
U Component
(EAST)
Q3S2
SEP 8,1982
1909
-
APR 15,1983
1509
NORTH km
300 -r
-50 -+V Component
(NORTH)
U Component
(EAST)
Q3S2
APR 16,1983 0200
-
JUL 12,1983 0900
NORTH km
1600 --r-
200
I
-200
t
M'
1
T
200
I
EAST km
400
-200 JV Component
(NORTH)
U Component
(EAST)
Q3S2
JUL 12,1983 1757
-
JAN 31,1984 1457
NORTH km
--r-
200
-] EAST km
200
-600
-1000
-1200 --L-
V Component
(NORTH)
U Component
(EAST)
Q4S1
APR 30,1981
0400
-
AUG 13,1981
0900
EAST km
V Component
(NORTH)
U Component
(EAST)
Q4S1
AUG 14,1981
0100
-
JAN 28,1982
1500
EAST km
V Component
(NORTH)
U Component
(EAST)
Q4S1
JAN 29,1982 0500
--
MAY 19,1982 0900
NORTH km
50 --rEAST km
-300
-350
V Component
(NORTH)
U Component
(EAST)
Q4S 1
JUL 8,1982 1200
-
SEP 8,1982
1200
2-25
EAST km
V Component
(NORTH)
U Component
(EAST)
Q4S2
APR 30,1981
0400
-
AUG 13,1981
0800
NORTH km
800 -
OCT 19,1981 0600
EAST km
-200
200
1
-200 -V Component
(NORTH)
U Component
(EAST)
Q4S2
AUG 14,1981
0100
-
JAN 28,1982
1500.
2-27
EAST km
V Component
(NORTH)
U Component
(EAST)
Q4S2
JAN 29,1982 0500
-
MAY 19,1982 0900
EAST km
V Component
(NORTH)
U Component
(EAST)
Q4S2
JUL 8,1982
1200
-
SEP 8,1982
1300
NORTH km
500 --r-
-100 -1-
V Component
(NORTH)
U Component
(EAST)
Q4S3
APR 30,1981
0400
-
AUG 13,1981
0800
-200
1
200
U Component
(EAST)
Q4S3
AUG 14,1981
0100
-
JAN 28,1982
1500
EAST km
V Component
(NORTH)
U Component
(EAST)
Q4S3
JAN 29,1982 0600
-
MAY 19,1982
1000
NORTH km
250 --r-
- 100
1
V Component
(NORTH)
U Component
(EAST)
Q4S3
JUL 8,1982 1200
-
SEP 8,1982
1200
2-33
Q4S3
Q4S2
Q4S1
Q3S2
Q3S1
}
--T
APR
U velocity
1981
MAY
JUN
-+---1-H--- }-- -1--}----1--
COOS BA's
108m
83m
51 m
}-----} ---+--r-----}----}- -I---I
I
E
-20
0
20
00)
Q4S3
Q4S2
Q4S1
Q3S2
Q3S1
APR
1981
MAY
COOS BAY V velocity
51m
JUN
-20
20
Q4S3
Q4S2
Q4S1
Q3S2
Q3S1
JUL
11 T- T
83m
51m
-1
II
T
1981
AUG
72m
44m
L
,
;
i
I
COOS BAY U velocity
I
---"I
SEP
Q4S1
Q3S2
Q3S1
N"r
JUL
f--- ----}---
M.pda-4.
1
1
i
1981
AUG
1da
44m
i1i
11
COOS BAY V velocity
I I
I
SEP
-+- -I
f
T--7
v
Q4S3
Q4S2
Q4S1
Q3S2
Q3S1
hL1"ll11'I11
OCT
-I--I
lumulwkwY
44m
I
I
I
1981
NOV
COOS BAY U velocity
I
DEC
}
OCT
COOS BAY V velocity
1981
NOV
DEC
Q4S3
Q4S2
Q4S1
Q3S2
Q3S1
JAN
COOS BAY U velocity
1982
FEB
MAR
-20
0
20
a)
Q4S3
Q4S2
Q4S1
Q3S2
Q3S1
JAN
COOS BAY V velocity
1982
FEB
MAR
Q4S3
APR
hy"
I
P,rll: i, U
U velocity
1982
MAY
COOS BAY
I
.mar 1.190-V A.A I i
JUN
Q4S3
Q4S2
Q4S1
Q3S1
APR
COOS BAY V velocity
1982
MAY
JUN
20
0
N
Q4S2
Q4S1
Q3S2
Q3S1
-1
77m
47m
mmu
I`I!
I:
I
w
IfnI it !'1
COOS BAY U velocity
NM
68m
38m
Q4S3
Q4S2
Q4S1
Q3S2
Q3S1
41m
JUL
11VIrg
COOS BAY V velocity
1982
AUG
1-11F if
-
SEP
wmwl, Ell,
68m
38m
-'r-mar
1w
Q3S2
Q3S1
Q3S2
Q3S1
JAN
OCT
COOS BAY U velocity
1983
FEB
1982
NOV
DEC
Q3S2
Q3S1
Q3S2
Q3S1
COOS BAY V velocity
0
E
ai
0
-20
0
20
Q3S2
Q3S1
Q3S2
Q3S1
67m
38m
JUL
65m
35m
APR
1
COOS BAY
U velocity
1983
AUG
1983
MAY
SEP
JUN
--20
0
20
a
Q3S2
Q3S1
Q3S2
Q3S1
JUL
APR
COOS BAY V velocity
1983
AUG
1983
MAY
NA ffviV
1
SEP
JUN
1
An,
E
Q3S2
Q3S2
Q3S1
65m
I
I
JAN
+
COOS BAY
U velocity
1984
FEB
I
I
MAR
Q3S2
Q3S2
I
65m
JAN
1984
FEB
COOS BAY V velocity
0
MAR
T1
1
1
-20 E
0
20 a
-20
20
0
Q3S2
Q3S1
i
I
APR
I
APR
51 m,83m
I
1981
MAY
i
r
I
I
I
I
I
rr
I
1981
MAY
--I
I
I
T
I
,
1
II
I
COOS BAY DEEP Temperature
I
COOS BAY SHALLOW Temperature
_r
I
JUN
I
JUN
I
-ri
I
5.5
6.5
7.5
6.0
7.0
8.0
9.0
10.0
Q4S3
Q4S2
Q4S1
Q3S2
Q3S1
T
JUL
1981
AUG
I
I I
I
1981
AUG
COOS BAY DEEP Temperature
I
44m,69m,113m
COOS BAY SHALLOW Temperature
36m,68m,108m
JUL
I
SEP
SEP
5.5
6.5
7.5
8.5
9.5
10.5
11.5
12.5
13.5
6.0
7.0
8.0
9.0
10.0
11.0
12.0
13.0
14.0
Q4S3
Q4S2
Q4S1
Q3S2
Q3S 1
I
U- I
r
OCT
OCT
I
I
I
I
1981
NOV
COOS BAY DEEP Temperature
1981
NOV
COOS BAY SHALLOW Temperature
I
DEC
DEC
7.5
E 8.5
Q4S3
Q4S2
Q4S1,
Q3S2
Q3S 1
JAN
JAN
1982
FEB
I
COOS BAY DEEP Temperature
1982
FEB
COOS BAY SHALLOW. Temperature
I
MAR
MAR
I
II
6.0
7.0
8.0
6.5
Q3S2
Q3S1
L
I
APR
APR
I
74m
II
1982
MAY
COOS BAY DEEP Temperature
1982
MAY
COOS BAY SHALLOW Temperature
I
JUN
-
6.0
7.0
8.0
9.0
10.0
11.0
Q4S3
Q4S2
Q4S1
Q3S2
Q3S1
I
I
I
I
I
I
1
I
I
I
I
I
COOS BAY DEEP Temperature
1
COOS BAY SHALLOW Temperature
1982
I
I
I
I
7.0
6.5
7.5
8.5
9.5
10.5
11.5
12.5
13.5
Q3S2
Q3S1
Q3S2
Q3S1
=
I
OCT
JAN
IIT
38m,68m
1983
FEB
1982
NOV
I
I
COOS BAY SHALLOW Temperature
I
I
MAR
DEC
7.5
8.5
9.5
13.5
8.0
9.0
10.0
- 13.0
14.0
15.0
'
1
I
I
I
JUL
T-
I
APR
I
I
I
i I
I
1
I
1
1
1
1983
AUG
I
1983
MAY
I
I
1
I
1
I
I
II
I
1
I
COOS BAY SHALLOW Temperature
I
I
1
I
SEP
I
JUN
I
I
I
I
I
-
7.5
8.5
9.5
10.5
11.5
12.5
13.5
7.0
Q3S2
Q3S2
Q3S1
I
I
I
JAN
I
OCT
I
I
I
I
1984
FEB
I
1983
NOV
I
I
I
I
I
COOS BAY SHALLOW Temperature
L1-
I
MAR
I
DEC
I
I
r
r
8.5
9.5
8.5
9.5
10.5
11.5
12.5
13.5
14.5
15.5
16.5
SAMPLING INTERVAL = 360 MINUTES
STATION
START TIME (GMT)
MIN
MAX
MEAN
STO
9.7
18.0
9.2
-0.3
-2.8
8.1
10.5
23.8
63.8
13.8
2.0
6.0
8.6
17.7
10.7
1.5
0000
U
-8.0
PRINCIPAL AXIS =
0.9
V
T
-27.0
7.3
AUG 15,1981
0600
U
V
-12.3
-37.7
Q3S1
Q3S1
MAY
1,1981
2.9
0.4
PRINCIPAL AXIS =
6.3
T
8.0
JAN 30,1982
0600
U
-12.3
1.7
-8.1
4.1
-39.4
PRINCIPAL AXIS =
16.9
V
T
6.2
10.1
-24.4
10.0
13.2
0.1
MAY 21,1982
0600
U
-15.5
13.4
24.6
-1.7
4.8
V
-1.5
11.6
10.4
8.6
0.7
8.1
21.2
1.1
Q3S1
Q3S1
9.9
PRINCIPAL AXIS =
7.0
T
-40.0
7.4
10,1982
0000
U
-29.9
29.7
V
-74.4
8.9
60.4
2.6
8.8
14.4
11.7
Q3S1
SEP
PRINCIPAL AXIS =
14.4
T
APR 28,1983
0000
U
-9.2
8.9
-0.7
V
21.9
12.0
-5.8
10.0
18.3
1.4
Q3S1
4.0
PRINCIPAL AXIS =
6.3
T
-49.1
8.3
JUL 13,1983
1800
U
V
-10.7
-27.3
14.4
42.9
0.5
4.3
13.2
PRINCIPAL AXIS,=
11.7
T
8.8
13.8
10.2
1.0
1,1981
0000
U
-7.8
4.8
18.3
-6.5
2.5
7.5
2.1
7.8
PRINCIPAL AXIS =
-16.6
6.8
-0.7
V
T
AUG 15,1981
0600
U
-11.8
-25.3
PRINCIPAL AXIS =
2.2
10.6
53.1
13.5
-0.2
V
T
JAN 30,1982
0600
U
3.7
T
7.1
1.4
9.1
15.7
PRINCIPAL AXIS =
10.8
46.6
10.2
-1.0
V
-17.6
-41.4
MAY 21,1982
0600
U
6.7
22.4
9.1
-1.0
Q3S1
Q3S2
Q3S2
Q3S2
Q3S2
MAY
PRINCIPAL AXIS =
Q3S2
SEP 10,1982
PRINCIPAL AXIS =
7.8
-9.3
8.2
4.7
'0.4
3.3
6.0 12.8
9.7 - 1.5
2.3
8.1
4.5
AUG 12,1981
AUG 12,1981
AUG 12,1981
1800
1800
1800
DEC 20,1981
DEC 20,1981
JAN 27,1982
1200
1200
0600
FEB
FEB
FEB
3,1982
3,1982
3,1982
1200
1200
1200
SEP
SEP
SEP
7,1982
7,1982
7,1982
1200
1200
1200
APR 14,1983 1800
APR 14,1983
APR 14,1983
1800
1800
JUN 13,1983
JUN 13,1983
JUN 13,1983
0000
0000
0000
3,1983
3,1983
3,1983
0600
0600
0600
AUG 12,1981
AUG 12,1981
AUG 12,1981
1800
1800
1800
NOV
NOV
NOV
JAN 27,1982 0600
JAN 27,1982 0600
JAN 27,1982 0600
0.9
MAY 18,1982
MAY 18,1982
MAY 18,1982
1800
1800
1800
3.0
9.0
0.6
SEP
SEP
SEP
7,1982
7,1982
7,1982
1200
1200
1200
APR 14,1983
APR 14,1983
APR 14,1983
1800
V
-24.6
-1.2
T
7.1
0000
U
V
T
-15.7
16.1
1.2
-40.0
52.6
9.0
16.6
8.4
13.6
11.2
1.2
5.9
STOP TINE
5.2
1800
1800
2-62
SAMPLING INTERVAL = 360 MINUTES
STATION
MEAN
-0.9
3.9
3.8
8.8
13.7
-13.9
-26.0
7.9
34.8
PRINCIPAL AXIS =
5.5
T
7.4
10.7
JUL 13,1983
1800
U
PRINCIPAL AXIS =
7.2
V
T
-14.2
-40.1
8.4
14.7
43.1
14.1
1,1981
0600
U
V
-17.5
-37.8
11.8
14.2
Q3S2
Q4S1
APR 17,1983
0600
MAY
STD
MAX
U
V
Q3S2
0.9
STOP TIME
JUL 11,1983
JUL 11,1983
JUL 11,1983
1200
1200
1200
1200
1200
1200
1.1
4.3
7.5
10.6
14.9
1.5
JAN 30,1984
JAN 30,1984
JAN 30,1984
-1.7
5.5
AUG 12,1981
1200
-11.8
12.7
AUG 12,1981
AUG 12,1981
1200
1200
1800
1800
1800
PRINCIPAL AXIS =
11.2
T
7.9
9.9
8.7
0.5
AUG 15,1981
0600
U
24.4
67.2
1.5
V
-36.1
-44.4
4.4
9.1
18.8
PRINCIPAL AXIS =
17.6
T
8.2
13.5
10.7
1.5
JAN 27,1982
JAN 27,1982
JAN 27,1982
JAN 30,1982
0600
U
-34.0
-61.9
PRINCIPAL AXIS =
18.2
V
T
8.9
29.1
57.8
10.2
-4.9
-13.5
9.8
11.5
28.0
0.3
MAY 18,1982
MAY 18,1982
MAY 18,1982
1200
1200
1200
9,1982
1200
U
-13.7
14.8
20.3
10.4
10.5
SEP
SEP
12.6
-24.6
8.5
-2.3
-6.2
PRINCIPAL AXIS =
V
T
7,1982
7,1982
SEP _7,1982
1200
1200
1200
1,1981
0600
U
-11.4
7.2
V
-29.8
17.9
-2.2
7.9
AUG 12,1981
AUG 12,1981
AUG 12,1981
1200
1200
1200
Q4S1
Q4S1
Q4S1
Q4S2
JUL
MAY
9.1
0.3
6.2
0.5
3.3
11.6
0.4
PRINCIPAL AXIS =
-2.3
T
7.3
8.7
AUG 15,1981
0600
U
15.4
60.4
PRINCIPAL AXIS =
9.2
V
T
-25.3
-33.5
7.8
13.3
JAN 30,1982
0600
U
-23.9
26.3
V
PRINCIPAL AXIS =
12.7
T
-46.7
8.1
57.4
10.2
9,1982
1200
U
-12.4
7.5
-1.4
3.9
PRINCIPAL AXIS =
-2.1
V
T
-20.8
8.1
26.0
9.5
0.7
8.6
9.3
0.3
1,1981
0600
U
-8.8
8.4
-0.6
3.4
V
-26 . 2
21 . 6
T
6.3
7.8
4.2
7.2
10.4
0.3
0600
U
-8.4
15.2
-0.2
3.2
-33 . 6
47 . 0
7.5
10 . 5
PRINCIPAL AXIS = -12.6
V
T
-JAN 27 , 1982
7.2
12.1
8.8
1.0
JAN 27,1982
Q4S2
Q4S2
Q4S2
.
MIN
START TIME -(GMT)
Q4S3
JUL
MAY
PRINCIPAL AXIS = -15.4
Q4S3
AUG 15,1981
1.4
6.1
5.5
9.8
17.3
1.5
JAN 27,1982
JAN 27,1982
JAN 27,1982
1800
1800
1800
8.9
24.2
9.5 - 0.5
MAY 18,1982
MAY 18,1982
MAY 18,1982
1200
1200
1200
7,1982
7,1982
7,1982
1800
1800
1800
AUG 12,1981
AUG 12,1981
AUG 12,1981
1200
1200
1200
JAN 27,1982
1800
1800
1800
-3.4
-8.3
SEP
SEP
SEP
SAMPLING INTERVAL = 360 MINUTES
STATION
START TIME -(GMT)
JAN 30,1982
MIN
MAX
MEAN
9.7
46.0
-0.4
4.0
2.4
15.7
10.1
8.6
0.8
0600
U
PRINCIPAL AXIS =
-7.4
V
T
9,1982
1200
U
-9.1
5.0
-1.3
-22 . 0
7.6
30 . 0
4
-12.6
V
T
Q4S3
Q4S3
JUL
PRINCIPAL AXIS
=
-11.4
-46.0
6.8.
8.6
STOP TIME
STD
3.2
MAY 18,1982
MAY 18,1982
MAY 18,1982
1200
1200
1200
7,1982
7 , 1982
7,1982
1200
1200
1200
1
10 . 1
SEP
SEP
8.1
0.3
SEP
.
E
P
1981
JUN
U
bJ LEA
P
U
1982
JUN
COOS BAY
E
LEA
velocity
LC1
E
1I4
U
1983
JUN
LC1
E
36m
Q4S 1
Q4S3 ;
APR
108m
68m
83m
Q3S2
Q4S2
51 m
Q3S 1 -
I
`4`"1A'' '
'-
wk,
...
u
.ti.
I m Tf ;Vff -
W-- - -- I%- -
MAY
IV
COOS BAY velocity
1981
JUN
w
JUL
inly"
INe
AuAI.Aq'Ikj%jI Am.
1141rK
fA&mv
,I'ih..AL*llta,,,, ,1111i,a11,,,Ibr.,`"
N
WIF ?"AUVIIAU'14111
6l
1
AUG
I-
E
72m
Q4S3
Q4S2
i A,
fl,
0
AUG
113m
69m ,atAira1.y,g111
Q4S1 -a 44m
Q3S2
Q3S1 -I 44m ,UmAI
I
SEP
COOS BAY
1981
.1
/Ip
Aulk,
fl.
OCT
11,41
14
velocity
NOV
P
JA
DEC
Av
4A
It
I Zz,,-
JAN
-
A1,1111k
E
-20
20
JAN
1982
MAR
COOS BAY
FEB
velocity
APR
MAY
MAY
1982
JUL
COOS BAY
JUN
velocity
AUG
SEP
Q3S2
Q3S1
Q3S2 --I
Q3S 1 -4
DEC
i
AUG
68m
38m
1982
OCT
FES
COOS BAY
JAN
i i II I i i i i iT
COOS BAY
SEP
5o,-k
111,
f
MAR
velocity
1983
r
1
NOV
+A
IliLw,
velocity
0
jigll-r
68m
DEC
'N
APR
f---f---1---I
"gyp.
1
MAR
67m
39m
1983
MAY
COOS BAY
APR
velocity
JUN
JUL
p352
Q3S1
Q3S2
Q3S 1
:
SEP
65m
JUN
i
I
65m
35m
I
I
1983
AUG
COOS BAY
1983
NOV
COOS BAY
OCT
JUL
, A, I/W
111-31
velocity
DEC
velocity
SEP
-IOWA
JAN
OCT
7[%
__
4101MAL
-ad 111,41111z' A/A VIA"I
ML.PI9rrW&VMM#V%
mm
IIIjIr'7'I,_
-20
-20
0
20
E
Q4S3
Q4S2
Q4S1
Q 3S2
Q3S1
APR
1 08M
68m
36m
83m
51m
4-
1981
JUN
11-6
JUL
COOS BAY U velocity
MAY
iv 4w
tv-f -1
AUG
-20
zu
A%
Q4S3
Q4S2
Q4S1
Q3S2
Q3S1
E
1
APR
108m
68m
36m
83m
51m
1981
JUN
JUL
COOS BAY V velocity
MAY
I
AUG
I
H
E-20
0
20
a
Q4S2
Q3S2 E
AUG
113m
69m
44m
72m
44m
SEP
NOV
COOS BAY U velocity
1981
OCT
DEC
y41
11
1
JAN
1F
AUG
SEP
NOV
COOS BAY V velocity
1981
OCT
DEC
JAN
Q4S3
Q4S2
Q4S1
Q3S2
Q3S1
E
JAN
107m
64m
35m
74m
42m
1982
MAR
APR
COOS BAY U velocity
FEB
MAY
C
C
107m
35m
74m
42m
1982
MAR
APR
COOS BAY V velocity
0
MAY
I
I
2o
o
20
Q4S3
Q4S2
Q4S1
Q3S2
Q3S 1
j
1
1
1
MAY
1
1
111m
71m
41m
77m
47m
1
all1
A
I
I
1
I
JUL
1982
I
Ims
ci
.L
11
V&--,l
1
AUG
_
#--*4++
COOS BAY U velocity
JUN
!
+0q, 1
SEP
0
20
Q4S3
Q4S2
Q4S1
Q3S2
Q3S1
1
1-4-11
1
MAY
111m
71m
41m
77m
47m
1982
JUL
V-V
AUG
1
COOS BAY V velocity
JUN
V
IV%I
n+z4 A IV a
I %'JV I
I[
IV 1
11
IN
11%
SEP
flogs
T,
P
%O
1\Vr\,.Jvv 1w IV F-Vil
I -\V-, gul
N\j 'TV
I
v
Q3S2
Q3S1
Q3S2
Q3S1
DEC
AUG
68m
38m
1982
OCT
NOV
FEB
1983
MAR
COOS BAY U velocity
JAN
COOS BAY U velocity
SEP
DEC
v
DEC
AUG
1982
OCT
NOV
FEB
1983
MAR
COOS BAY V velocity
JAN
COOS BAY V velocity
SEP
APR
DEC
Q3S2
Q3S1
MAR
67m
39m
l
1983
MAY
Pnlal
I
JUN
COOS BAY U velocity
APR
1101W
1
i
JUL
.
Q3S2
Q3S1
LI
MAR
39m
-
t
MAY
I
1983
T..I
JUN
/ ittItt _9P- I
COOS BAY V velocity
APR
'i"T
I
I
i
JUL
i
I
i
i"
E
r-
--20
0
20
Q3S2
Q3S1
Q3S2
Q3S1
SEP
65m
35m
JUN
65m
35m
1983
AUG
SEP
_1
NOV
DEC
n.N Y _1 nLA Q
1983
i_1
COOS BAY U velocity
OCT
nrw
COOS BAY U velocity
JUL
i1' I
JAN
/A1 Vd
OCT
a
U
0-1
-20 E
20
-20
0
20
1
Q3S2
Q3S 1
SEP
JUN
1983
AUG
1983
NOV
DEC
COOS BAY V velocity
OCT
JAN
OCT
tr-nD can 1. A
SEP
I ca
COOS BAY V velocity
JUL
Ar,
I
I
APR
I
I
I
t
1
MAY
1
1
1
11
1
JUN
I
I
1981
I
11
1
1
JUL
1
1
1
1
COOS BAY DEEP Temperature
1981
COOS BAY SHALLOW Temperature
I
1
1
AUG
1
1
1
1
5.5
6.5
7.5
8.5
9.5
10.5
6.0
1
I
1
I
AUG
1
AUG
I
1
i
1
11
11
1
1
1
1
1
1
I
1
1
OCT
1
1
1981
1
1
it
1
e
NOV
1
i
11
i
I
DEC
i
1
1
1'
1
OCT
1
1
1981
1
1
I(
1
1
NOV
1
1
1
I
1
1
1
1
DEC
COOS BAY DEEP Temperature
SEP
1
COOS BAY SHALLOW Temperature
SEP
1
1
1
1
I
II
Il
1
i
1
JAN
1
JAN
1I
1
i
1
I
1
i
6.5
7.5
8.5
9.5
10.5
11.5
12.5
13.5
7.0
8.0
9.0
10.0
11.0
12.0
13.0
14.0
Q4S3
Q4S2
Q4S1
1
1
JAN
JAN
1
1
t
11
1
MAR
1982
APR
1
1
t
i
l
MAY
l
11
MAR
1982
APR
I
MAY
COOS BAY DEEP Temperature
FEB
I
COOS BAY SHALLOW Temperature
FEB
I
111
d
A
I
JUN
JUN
I
I
I
6.0
7.0
8.0
9.0
10.0
11.0
6.5
Q3S2 :
Q3S1
I
1
MAY
MAY
47m,77m
1_
JUN
1
1982
JUL
1
I
1
AUG
I
I
I
1
I
1
JUL
I
1982
1
1
1
I
AUG
I
I
COOS BAY DEEP Temperature
JUN
I
II
COOS BAY SHALLOW Temperature
1
I
I
SEP
TI
I
SEP
I
1
7.0
11.0
6.5
7.5
8.5
9.5
I- 10.5
Q3S2
Q3S1
DEC
AUG
1982
OCT
NOV
I
I
JAN
1
I
I
II
I
I
FEB
I
a
I
1983
I
I
MAR
I
I
II
COOS BAY SHALLOW Temperature
II
COOS BAY SHALLOW Temperature
SEP
I
I
APR
DEC
I
I
8.0
9.0
8.0
I
1
FEB
,
1
, I
1
1
MAR
1
1
11
1
1
APR
1
1
I
I
1
1983
i
I
MAY
i
1
II
1
JUN
1
1
1
COOS BAY SHALLOW Temperature
1
i
1
JUL
1
1
i
7.0
8.0
9.0
Q3S2
Q3S2
Q3S1
I
I
OCT
I
JUN
I
1
TI
JUL
1983
AUG
SEP
1
NOV
1
1
1983
1
1
I
I
1
1
DEC
1
1
1
11
1
1
JAN
I
a
1
II
COOS BAY SHALLOW Temperature
i
COOS BAY SHALLOW Temperature
I
35m,65m
a
TI
I
FEB
I
OCT
I
I
8.0
9.0
10.0
11.0
12.0
13.0
14.0
15.0
8.0
14.0
CRESCENT CITY
124° 30'
".POINT ST. GEORGE
.
CRESCENT CITY
3-4
SAMPLING INTERVAL = 60 MINUTES
STATION
Y3S1
START TIME -(GMT)
FEB
6,1981
0100
MIN
AUG 14,1981
2200
JAN 30,1982
0400
14.1
21.3
7.8
10.8
1.3
-27.7
-56.1
8.3
45.8
48.6
16.1
2.4
0.5
10.3
10.2
18.3
-24.4
-36.4
9.3
23.8
46.8
10.4
-6.2
1.8
10.4
18.2
0.3
-34.6
-53.9
6.8
33.8
43.6
12.5
-0.2
-2.2
-29.4
-31.8
8.1
27.4
39.0
V
T
1,1981
1,1981
1,1981
0800
0800
0800
3,1981
NOV 3,1981
NOV
3,1981
1100
1100
1100
FEB
FEB
FEB
8,1982
8,1982
1300
1300
1300
MAY
MAY
MAY
1,1981
1,1981
1,1981
0800
0800
9.2
10.3
16.8
1.3
7.6
12.4
0.9
NOV
NOV
NOV
3,1981
3,1981
3,1981
1100
13.8
0.3
7.0
9.1
-20.8
-36.8
8.3
24.1
48.3
10.4
-0.3
9.4
1.5
10.7
18.9
8,1982
8,1982
8,1982
1300
1300
0.5
FEB
FEB
FEB
U
V
T
-44.7
-86.5
9.4
36.6
36.4
12.9
14.1
22.4
0.6
APR
APR
APR
9,1981
9,1981
9,1981
1100
1100
1100
U
-32.7
-54.4
-9.4
3.4
14.6
16.8
7.5
38.1
24.1
10.9
8.9
1.0
MAY 22,1981
MAY 22,1981
MAY 22,1981
1700
1700
1700
-20.7
-16.9
8.5
17.1
32.3
11.9
-2.6
11.2
9.6
7.9
9.7
0.5
AUG 30,1981
AUG 30,1981
AUG 30,1981
1300
1300
1300
-28.3
-44.4
9.2
33.1
60.6
11.0
-0.6
6.0
10.8
21.7
10.2
0.4
7,1982
7,1982
7,1982
1200
1200
1200
U
V
T
-24.1
-37.1
28.9
27.1
9.6
2.0
9.3
8.0
13.7
0.6
MAY 22,1981
MAY 22,1981
MAY 22,1981
1700
1700
1700
U
-15.5
-14.8
8.0
AUG 30,1981
-AUG 30,1981
AUG 30,1981
1300
1300
1300
U
U
V
T
Y3S2
FEB
6,1981
0100
U
V
T
Y3S2
AUG 14,1981
2200
U
V
T
Y3S2
Y4S1
Y4S1
JAN 30,1982
FEB
MAY
6,1981
2,1981
0500
0400
0300
U
V
T
Y4S1
AUG 15,1981
0000
U
V
T
Y4S1
JAN 30,1982
0300
U
V
T
Y4S2
Y4S2
MAY
2,1981
AUG 15,1981
0300
0000
STOP TIME
STD
2.8
-14.4
V
T
Y3S1
MEAN
45.4
34.8
12.9
U
V
T
Y3S1
-39.4
-80.8
MAX
V
T
7.1
15.6
35.4
9.6
9.9
2.8
-19.9
11.7
-1.6
1.4
-3.7
6.3
11.2
8.5
10.6
0.2
MAY
MAY
MAY
NOV
MAR
MAR
MAR
8,1982
0800
1100
1100
1300
SAMPLING INTERVAL = 60 MINUTES
STATION
Y4S2
Y4S3
Y4S3
MIN
START TIME -(GMT)
JAN 30,1982
AUG 15,1981
JAN 30,1982
0200
0000
0200
U
V
-37.2
-31.8
T
7.7
U
V
-23.6
-25.8
T
U
V
T
STOP TIME
MAX
MEAN
STD
25.4
63.4
10.8
-0.8
6.9
9.5
10.2
22.5
0.8
MAR
MAR
7,1982
7,1982
MAY 20,1982
1200
1200
1100
13.6
-3.3
7.7
11.5
0.2
AUG 30,1981
AUG 30,1981
AUG 30,1981
1300
1300
1300
9.7
16.0
0.7
MAY 20,1982
MAY 20,1982
MAY 20,1982
1100
1100
1100
7.6
34.0
8.5
7.2
8.1
-35.9
-40.2
6.8
26.5
51.9
10.3
-1.3
4.1
8.4
3-6
3-7
V Component
(NORTH)
s
I
U Component
(EAST)
.}1V
.IM
Y3S1
FEB
6,1981
0100
-
MAY 1,1981
0800
EAST km
V Component
(NORTH)
U Component
(EAST)
Y3S1
AUG 14,1981
2200
-
NOV
3,1981
1100
3-9
NORTH km
20 --r-
EAST km
-20
20
-100
V Component
(NORTH)
U Component
(EAST)
Y3S 1
JAN 30,1982 0400
--
FEB 8,1982
1300
NORTH km
100
I--
,
EAST km
50
-30
-100
-130
-200
-250
V Component
(NORTH)
U Component
(EAST)
Y3S2
FEB
6,1981
0100
-
MAY 1,1981
0800
V Component
(NORTH)
U Component
(EAST)
Y3S2
AUG 14,1981
2200
-
NOV 3,1981
1100
NORTH km
10 -r-
EAST km
-10
20
-10
-20
-30
-40
-50
-60 -1V Component
(NORTH)
U Component
(EAST)
Y3S2
JAN 30,1982 0500
-
FEB 9,1982
1300
3-13
EAST km
V Component
(NORTH)
U Component
(EAST)
I..
Y4S1
FEB
6,1981
0400
-
APR 9,1981
1100
NORTH km
50 -r
-
EAST km
150
-50 -4-
-100 -F-
-150 -4-
-200 --4-
-250 -'V Component
(NORTH)
U Component
(EAST)
Y4S1
MAY 2,1981
0300
-
MAY 22,1981
1700
3-15
NORTH km
160 T
EAST km
-60
-40
-20
20
-20 V Component
(NORTH)
U Component
(ST)
Y4S1
AUG 15,1981
0000
-
AUG 30,1981
1300
EAST km
-100 -+V Component
(NORTH)
U Component
(EAST)
Y4S1
JAN 30,1982 0300
-
MAR 7,1982
1200
NORTH km
20 T
-, EAST km
60
-20
-40
-60 -+-
-80 -4-
- 100 -LV Component
(NORTH)
U Component
(EAST)
Y4S2
MAY 2,1981
0300
-
MAY 22,1981
1700
NORTH km
200 -r-
150
d EAST km
-100
-50
50
-50 --iV Component
(NORTH)
U Component
(EAST)
Y4S2
AUG 15,1981
0000
AUG 30,1981
1300
EAST km
V Component
(NORTH)
U Component
(EAST)
Y4S2
JAN 30,1982 0200
-
MAR 7,1982
1200
EAST km
V Component
(NORTH)
U Component
(EAST)
Y4S3
JAN 30,1982 0200
-
MAY 20,1982
1 100
NORTH km
120 -
-r--EAST km
-60
-40
-20
20
-20
V Component
(NORTH)
U Component
(EAST)
Y4S3
AUG 15,1981
0000
--
AUG 30,1981
1300
Y4S1
Y3S2
Y3S1
JAN
-}
1981
FEB
U velocity
MAR
- ---- t-- _ { -t---I-f----F--- - ---
CRESCENT CITY
I
Y4S1
Y3S2
Y3S1
JAN
1981
FEB
CRESCENT CITY V velocity
71m
41m
MAR
I
Y4S2
Y4S1
Y3S2
Y3S1
APR
1981
MAY
CRESCENT CITY
31m
U velocity
"JA F;TrIi
41m
I
I
1
JUN
1
F
E
37m
41m
APR
1981
MAY
CRESCENT CITY V velocity
63m
JUN
-20
Y4S3
Y4S2
Y4S1
Y3S2
Y3S1
CRESCENT CITY
1981
AUG
122m
62m
32m
65m
35m
U velocity
AAA
Nil JAYA
-Irriorlp'-fr -,F
Y4S3
Y4S2
Y4S1
Y3S2
Y3S1
}-
JUL
i il,
.
t L
I.
CRESCENT CITY V velocity
1981
AUG
122m
62m
32m
65m
35m
rT
II
SEP
I
Li
I
F
Y3S2
Y3S1
OCT
CRESCENT CITY
1981
NOV
65m
U velocity
DEC
Y3S2
Y3S1
1
OCT
CRESCENT CITY V velocity
1981
NOV
DEC
I
Y4S3
Y4S2
Y4S1
Y3S2
Y3S1
130m
65m
37m
65m
35m
JAN
CRESCENT CITY
1982
FEB
U velocity
MAR
u
Y4S3
Y4S2
Y4S1
Y3S2
Y3S1
130m
65m
37m
65m
35m
JAN
II
CRESCENT CITY V velocity
1982
FEB
I
MAR
E
200
01-1
_20E
s-.
Y4S3
Y4S3
APR
U velocity
CRESCENT CITY V velocity
1982
MAY
±---}---{---}-
CRESCENT CITY
JUN
JUN
-20
0
20
E
a
Y4S1
Y3S2
Y3S1
7
I
JAN
37m
I
I
1981
FEB
T
I
I
MAR
I
I
I I
I
I
I
1981
FEB
I
I
I
I
I
I
1
CRESCENT CITY DEEP Temperature
I
MAR
CRESCENT CITY SHALLOW Temperature
JAN
41 m,71 m
I
I
I
I
T
9.5
- 10.5
11.5
F- 13.5
F- 12.5
14.5
7.5
Y3S2
Y3S1
1
i
I
I- I
I
r
APR
I
APR
I
I
I
I
1981
MAY
I
I
I
I
II
I
I
I
I
I
!
1981
MAY
I
I
I
II
I
CRESCENT CITY DEEP Temperature
U --I
I
I
CRESCENT CITY SHALLOW Temperature
41m,71m
I
JUN
I
JUN
I
I
I
I
I
I
6.5
7.5
8.5
9.5
10.5
11.5
12.5
13.5
6.5
7.5
8.5
9.5
10.5
11.5
12.5
13.5
Y4S2
Y3S2
Y3S1
I
1
JUL
I
JUL
1981
AUG
I
II
I
I
1981
AUG
I
I
I
I
I I
1
CRESCENT CITY DEEP Temperature
I
I
CRESCENT CITY SHALLOW Temperature
35m,65m
SEP
I
SEP
1
I
1
I
7.0
!- 15.5
16.5
Y3S2
Y3S1
I
1
OCT
---T
I
I I
I
1981
NOV
CRESCENT CITY SHALLOW Temperature
I
DEC
7.5
10.5
- 11.5
-- 12.5
H- 14.5
F- 13.5
15.5
7
Y3S2
Y4S3
Y4S2
Y4S1
:
Y3S1
J
L
1
II
Li
I
I
1982
FEB
I
L
I
I
I
JAN
I
I
1982
FEB
I
L
I
I
I
I
I
I
CRESCENT CITY DEEP Temperature
II
I
I
T
I
MAR
CRESCENT CITY SHALLOW Temperature
JAN
35m, 65m
I
37m,65m,130m
I
I
1
I
I
L
I
9.0
6.5
11.5
7.0
- 8.0
!-
10.0
11.0
APR
1982
MAY
I
CRESCENT CITY DEEP Temperature
I
JUN
6.0
11.0
SAMPLING INTERVAL = 360 MINUTES
STATION
Y3S1
START TIME -(GMT)
7,1981
MIN
0600
U
PRINCIPAL AXIS =
-7.7
V
T
AUG 16,1981
0000
U
Y3S1
FEB
V
MAX
MEAN
-18.2
-57.2
8.2
21.3
26.2
12.7
2.6
-14.2
-7.9
16.6
40.1
13.6
2.4
0.2
-32.3
8.6
6.9
18.7
1.3
10.8
4.3
16.0
1.3
PRINCIPAL AXIS =
-7.8
T
JAN 31,1982
0600
U
-0.2
9.0
3.7
-3.3
-22.9
9.6
23.3
10.3
-7.6
14.8
PRINCIPAL AXIS =
V
T
9.8
0.3
7,1981
0600
U
-0.2
-2.0
PRINCIPAL AXIS =
5.0
-14.8
-34.5
9.0
V
T
AUG 16,1981
0000
U
-5.0
Y3S1
Y3S2
Y3S2
FEB
PRINCIPAL AXIS =
Y3S2
JAN 31,1982
PRINCIPAL AXIS =
Y4S1
FEB
7,1981
0600
-2.7
0600
PRINCIPAL AXIS = -13.1
Y4S1
MAY
3,1981
0600
PRINCIPAL AXIS = -35.2
Y4S1
AUG 16,1981
0000
1200
1200
1200
2.3
FEB
FEB
FEB
7,1982
7,1982
7,1982
1800
1800
1800
4.0
APR 30,1981
APR 30,1981
APR 30,1981
1200
1200
1200
-4.9
-15.4
8.2
7.6
25.2
13.6
0.2
7.1
9.1
2.4
9.3
NOV
NOV
2,1981
2,1981
1200
1200
0.8
NOV 2,1981
1200
U
V
T
-2.0
-17.3
8.9
5.8
28.6
-2.0
2.0
2.0
13.9
10.2
9.4
0.4
FEB 7,1982
FEB 7,1982
FEB _7,1982
1800
1800
1800
U
V
T
-26.1
-72 . 4
9.9
21.7
2.8
9.6
22 . 8
12.9
-19 . 1
11.7
20 . 0
APR
APR
0.6
APR
8,1981
8 , 1981
8,1981
1200
1200
1200
U
V
T
-14.1
-34 . 7
7.8
27.2
14 . 8
2.8
-9 . 3
11.7
13 . 9
10.5
8.8
0.9
MAY 21,1981
MAY 21 , 1981
MAY 21,1981
1800
1800
1800
U
2.6
22. 8
10.2
-2.4
3.4
11. 7
6 .1
AUG 29,1981
AUG 2 9 ,1 981
1800
1 800
0.3
AUG 29,1981
1800
16.7
-0.6
6.3
46.4
6.6
19.5
MAR
MAR
11.0
10.2
0.4
MAR
6,1982
6,1982
6,1982
1200
1200
1200
T
0600
U
V
T
-13.2
-22.1
9.5
-9.8
NOV
2,1981
2,1981
2,1981
NOV
NOV
V
T
PRINCIPAL AXIS = -19.0
PRINCIPAL AXIS =
1200
1200
1200
7.1
-9.4
-4 . 0
9.1
JAN 31,1982
10.3
APR 30,1981
APR 30,1981
APR 30,1981
38.3
11.8
V
Y4S1
STOP TIME
STD
14.0
1.2
9.2
9.7
-
.
Y4S2
MAY
3,1981
0600
PRINCIPAL AXIS = -26.4
Y4S2
AUG 16,1981
PRINCIPAL AXIS =
0000
-14.8
U
V
-12.3
-20 . 7
7.4
14.4
U
V
-7.9
T
T
15 . 8
1.7
-1 . 9
6.2
10 . 8
9.2
8.0
0.5
1.1
24 .5
-3.7
11 . 7
2.4
- 5 .0
8.1
8.9
8.5
0.2
7.7
-
MAY 21,1981
MAY 21 , 1981
MAY 21,1981
1800
1800
AUG 29,1981
AUG 29 , 1981
AUG 29,1981
1800
1800
1800
1800
3-40
SAMPLING INTERVAL = 360 MINUTES
STATION
MIN
START TIME -(GMT)
MAX
MEAN
13.3
49.7
10.7
-0.5
8.3
9.5
20.5
0.8
STOP TIME
STD
6.4
JAN 31,1982
0600
V
PRINCIPAL AXIS =
-9.4
-17.2
-23.0
T
7.8
AUG 16,1981
0000
U
-7.4
1.8
-3.4
2.3
AUG 29,1981
-2 . 3
7.8
21 . 6
7.2
6 .9
AUG 29 , 1981
PRINCIPAL AXIS = -16.9
V
T
8.3
8.1
0.1
0600
U
-14.0
17.8
-1.4
5.8
-32 . 0
38 . 7
4 .3
13 . 6
PRINCIPAL AXIS = -21.8
V
T
9.7
8.4
0.6
Y4S2
Y4S3
Y4S3
JAN 31,1982
U
7.1
MAR
MAR
6,1982
6,1982
MAY 19,1982
1200
1200
1200
1800
1800
AUG 29,1981 1800
MAY 19,1982
MAY 19 , 1982
MAY 19,1982
1200
1200
1200
Y4S3 --
Y4S2
Y4S 1 -
Y3S2
Y3S1 -I
IUA LCJ.
1981
UN
U
1982
SU%
CRESCENT CITY
LEA
LEA
velocity
LcT
U
1983
JUN
LCJ.
LEA
20 E
0,11
20 a"
JAN
1981
MAR
CRESCENT CITY
FEB
velocity
APR
MAY
APR
1981
JUN
CRESCENT CITY
MAY
velocity
JUL
AUG
JUL
1981
SEP
CRESCENT CITY
AUG
velocity
OCT
NOV
JAN
1982
MAR
CRESCENT CITY
FEB
velocity
APR
MAY
Y4S1
Y3 S2
Y3 S 1
JAN
37m
FF i
71m
41m
F"
1981
MAR
CRESCENT CITY
FEB
APR
I
I
U velocity
1
I
MAY
Y4S1
Y3S2
Y3S1
i
JAN
37m
71m
41 m
4
1981
MAR
APR
CRESCENT CITY V velocity
FEB
MAY
F
o
-20 E
20
Y4S2
Y4S1
E
APR
63m
41m
I
1981
JUN
CRESCENT CITY
MAY
U velocity
JUL
AUG
i
i
I
}
i
E
Y4S2
Y4S1
I
APR
63m
41m
1981
JUN
JUL
CRESCENT CITY V velocity
MAY
AUG
I
--20
20 w
Y4S3
Y4S2
Y4S1
Y3S2
Y3S1
1
i
if
JUL
122m
i
62m
i--i{--I
32m
f-4-1
65m
35m
I
I
I
I'll
1
Ii--
--I--
1981
SEP
CRESCENT CITY
AUG
4-
-- f- --I
I
OCT
I
I-T
U velocity
I
I
--
i
NOV
rII
I
T
-2o E
0'-
20
Y4S3 :
Y4S2 -
Y4S1
:
Y3S2 E
Y3S1
JUL
#-+I
I
I
122m
62m
32m
65m
FFII-0
1981
SEP
OCT
CRESCENT CITY V velocity
AUG
NOV
E -20
0
20
Y4S3
Y4S2
Y4S1
Y3S2
Y3S1
i
I
JAN
130m
65m
37m
Ii
65m
35m
1
1
-
1982
MAR
F-
'401
CRESCENT CITY
FEB
t
LIw
t'L 1- _ _ L
APR
A
V"
1^4
U velocity
11
-
I
II
H
11{ F-i i
J1
MAY
I
1
-20
0
E 20
Y4S3
Y4S2
Y4S1
Y3S2
Y3S1
JAN
130m
65m
ii+1
37m
65m
35m
.I
FEB
. I
1982
MAR
.1
APR
CRESCENT CITY V velocity
p
1
1
MAY
H
F--4
i
i
-20
0
20 a
I
I
I
I
JAN
I
JAN
I
I
I
I
I
FEB
I
I
I
I
I
I
I
1981
MAR
I
I
II
I
I
APR
I
1
I
i
I
I
I
I
II
1
1
FEB
1
1
1
1
1
1
1
1981
MAR
1
1
II
I
I
APR
I
I
I
I
I
I
MAY
J
I
I
I
I
i
1
MAY
1 I T 1T-7
I!
CRESCENT CITY DEEP Temperature
I
CRESCENT CITY SHALLOW Temperature
I
8.5
,14.5
6.5
7.5
8.5
9.5
10.5
11.5
12.5
13.5
I
I
MAR
I
I
1981
MAY
JUN
CRESCENT CITY DEEP Temperature
APR
I
JUL
6.5
8.5
11.5
Y4S3
Y3S2
Y3S1
JAN
1I
JAN
I
1
35m,65m
11
11
11
FEB
1
1
I
l
MAR
1
.
1982
it
.
APR
I
I
I
i
.
MAY
.
.
.
1
FEB
11
1
I
l
1
1
MAR
1
1
1
1982
11
1
APR
1
1
1
I
l
1
1
MAY
1
11
CRESCENT CITY DEEP Temperature
1
CRESCENT CITY SHALLOW Temperature
1
11
11
1
1
.
JUN
1
JUN
1
1
1
T--l
.
6.5
7.5
8.5
9.5
7.5
8.5
9.5
10.5
11.5
Y4S3
Y4S2
Y4S 1
Y3S2
Y3S1
-"
:1
I
I
JUL
AUG
1981
SEP
.
OCT
.
.
.
.I
.
.
I
a
II
1
AUG
1
1
1
II
a
SEP
I
I
1981
I
I
I
I
i
OCT
I
I
1
iI
CRESCENT CITY DEEP Temperature
1
1
1
CRESCENT CITY SHALLOW Temperature
32m,62m,122m
I
JUL
35m, 65m
.
NOV
1
NOV
.
1
.
1
7.0
8.0
9.0
10.0
11.0
7.5
8.5
9.5
F- 10.5
11.5
12.5
13.5
3-58
EUREKA
124° 30'
PT7
410
D
F
;:' ARCATA`
BAY
EUREKA
,Lo
'`.. HUMBOLDT
BAY
so
Eureka
SOp
(E3)
SOUNDINGS IN METERS
0
5
m
km
10
15
FALSE CAPE
0° 30'
SAMPLING INTERVAL = 60 MINUTES
STATION
E3S1
START TIME
FEB 28,1982
MIN
0100
MEAN
-37.9
-69.1
57.5
67.9
11.0
-9.3
-26.7
-49.0
-0.4
13.1
.7.3
31.1
37.7
12.1
9.2
0.8
-44.8
-67.9
8.2
72.5
74.7
15.7
3.4
0.3
17.1
22.9
11.9
1.2
U
V
T
-35.6
-54.3
3.2
-1.7
9.0
14.5
16.1
7.3
56.4
60.4
10.9
U
-21.7
-27.7
7.0
32.5
40.7
10.3
2.2
2.4
8.4
U
V
T
E3S1
MAY 22,1982
0100
U
V
T
E3S1
SEP 10,1982
1836
U
V
T
E3S2
E3S2
FEB 28,1982
MAY 22,1982
0200
0100
STD
MAX
(GMT)
V
T
7.6
1.3
9.7
3.5
STOP TIME
14.6
21.3
0.9
MAY 21,1982
MAY 21,1982
MAY 21,1982
0900
0900
0900
9.3
SEP 10,1982
SEP 10,1982
SEP 10,1982
0900
0900
0900
APR 14,1983
APR 14,1983
APR 14,1983
1836
1836
1836
MAY 21,1982
MAY 21,1982
MAY 21,1982
0900
0900
0900
JUL 31,1982
JUL 31,1982
JUL 31,1982
1200
1200
1200
0.9
9.3
11.6
0.6
NORTH km
100
EAST km
-100
-100
-200
-300
-400
-500
-800
-700
V Component
(NORTH)
U Component
(EAST)
E3S1
FEB 28,1982 0100
--
MAY 21,1982 0900
NORTH km
100 --r-
50 -i-
- EAST km
t
-50
1
/50
1_
,i00
150/
200
250
300
350
-50
-100 -}-
-150
V Component
(NORTH)
U Component
(EAST)
E3S1
MAY 22,1982 0100
-
SEP 10,1982 0900
400
200
- EAST km
I
-200
800
-200
V Component
(NORTH)
U Component
(EAST)
E3S 1
SEP 10,1982
1836
-
APR 14,1983
1836
NORTH km
200 --r-
150 -f--
100 -}-
50 -+I
-50
50
100
200
150
EAST km
300
-50
-100
-150
V Component
(NORTH)
U Component
(EAST)
E3S2
FEB 28,1982 0200
-
MAY 21,1982 0900
4-9
NORTH km
-r--
160
-40
V Component
(NORTH)
U Component
(EAST)
E3S2
MAY 22,1982 0100
-
JUL 31,1982
1200
E3S2
E3S1
E3S2
E3S1
35m
APR
JAN
36m
EUREKA U velocity
1982
MAY
1982
FEB
JUN
MAR
E
E
-20 E
0
20 a
-20 E
0
20 N
E3S2
E3S1
APR
EUREKA V velocity
1982
MAY
JUN
--20
0
a
20 N
20
20
E3S2
E3S2
E3S1
EUREKA U velocity
1982
1982
I
DEC
I--I----}
H- --+-------}
-__ I
I
-20
20
0
1-1
U
E
a
r-.
E3S2
E3S2
E3S1
OCT
EUREKA V velocity
1982
E3S2
E3S2
7
JAN
1983
FEB
40m
APR
0--
EUREKA U velocity
1983
MAY
F--i--T-F----T------ --}
40m
I--1JUN
MAR
-20
0
20
1-1
U)
as
E3S2
E3S2
40m
APR
I-----I--
JAN
EUREKA V velocity
1983
MAY
1983
FEB
I
0
20
--20
0
aa)i
1-1
20 a
E3S2
E3S1
E3S2
E3S1
Z
I
I
APR
JAN
I
1
I
T
1982
MAY
F -I
1982
FEB
I
I
I
I
I I
I
EUREKA SHALLOW Temperature
I
T- T -1" --1
35m,65m
I
JUN
MAR
-
6.5
7.5
12.5
7.0
E8.0
9.0
10.0
F- 11.0
12.0
E3S2
E3S1
OCT
JUL
36m,66m
I
1982
NOV
1982
AUG
EUREKA SHALLOW Temperature
I
DEC
SEP
40m
z
7.0
8.0
9.0
10.0
11.0
12.0
13.0
E3S1
E3S1
1
40m
APR
40m
JAN
V-
1
T
1
1983
MAY
I
1983
FEB
1
I
I
I
I
I
1
I
I
1
EUREKA SHALLOW Temperature
I
ti
I
I
JUN
1
MAR
I
1
1
I-
8.0
9.0
10.0
11.0
12.0
13.0
14.0
8.0
9.0
-- 10.0
13.0
14.0
4-19
SAMPLING INTERVAL = 360 MINUTES
STATION
MIN
START TIME -(GMT)
MAX
MEAN
STD
1.5
-9.2
9.7
17.6
0.8
3.5
5.0
PRINCIPAL AXIS =
22.5
T
7.9
28.2
30.5
10.8
MAY 23,1982
0600
U
-12.5
16.1
E3S1
E3S1
MAR
1,1982
0600
U
V
-16.2
-56.4
V
18.3
10.7
-0.2
9.2
9.1
10.6
0.7
STOP TIME
MAY 20,1982
MAY 20,1982
MAY 20,1982
1200
SEP
9,1982
1200
SEP
SEP
9,1982
9,1982
1200
1200
1200
1200
PRINCIPAL AXIS =
20.7
T
-35.3
7.7
SEP 12,1982
0000
U
-26.2
26.9
3.4
8.3
APR 13,1983
1800
23.8
V
T
-57.1
9.1
46.4
14.9
0.4
11.9
15.6
1.1
APR 13,1983
APR 13,1983
1800
1800
0600
U
-9.7
16.3
3.3
5.5
MAY 20,1982
1200
V
-33.0
PRINCIPAL AXIS =
20.2
T
7.5
30.8
10.8
-1.7
9.0
11.7
0.8
MAY 20,1982
MAY 20,1982
1200
1200
MAY 23,1982
0600
PRINCIPAL AXIS =
23.6
U
V
T
-4.6
-14.9
7.2
10.1
15.3
9.7
2.4
2.7
8.4
3.3
6.6
0.5
JUL 30,1982
JUL 30,1982
JUL 30,1982
1200
1200
1200
E3S1
PRINCIPAL AXIS =
E3S2
E3S2
MAR
1,1982
E3S2
E3S 1
-,
E
1981
JUN
U
C
E
P
1982
JUN 1U
bC
LE
EUREKA velocity
E
E
P
U
1983
JUN
C
E
FEB
MAR
EUREKA velocity
1982
APR
MAY
JUN
MAY
66 m
JUN
EUREKA velocity
1982
JUL
AUG
SEP
E3S1
DEC
AUG
JAN
SEP
1983
EUREKA velocity
FEB
EUREKA velocity
1982
OCT
MAR
NOV
APR
DEC
20
E
U
E3S2
E3S1
E
FEB
65m
35m
MAR
MAY
EUREKA U velocity
1982
APR
JUN
m
-20E
20
0
E3S2
E3S1
E
FEB
65m
35m
MAR
MAY
EUREKA V velocity
1982
APR
JUN
--20 E
0
200
E3S1
MAY
66m
1982
JUL
AUG
EUREKA U velocity
JUN
SEP
E3S2
E3S 1
E
E
MAY
66m
JUN
A I`ti ,.,
EUREKA V velocity
1982
JUL
AUG
SEP
I
E3S1
E3S1
DEC
All
AUG
N
C
,
1982
OCT
NOV
FEB
A -aA A MA A
A
1983
MAR
A& L a 1-1- 4 a
EUREKA U velocity
JAN
M-0
EUREKA U velocity
SEP
APR
DEC
r-
E3S1
DEC
AUG
40m
1982
OCT
NOV
FEB
f
DEC
1983
MAR
APR
fill it, IIIIII
EUREKA V velocity
JAN
i
EUREKA V velocity
SEP
E3S2 7
E3S1
I
I
I
I
MAY
I
FEB
I
I
I
I
I
I
I
I
JUN
I
I
I
I
I
II
I&
I
JUL
I
I
1982
i
1982
APR
I
L
I
MAY
I
1
I
II
I
AUG
dI 1111111
I.. I.
EUREKA SHALLOW Temperature
II
MAR
II I..
35m.65m
I
I
I
I
1
SEP
1
JUN
I
I
I
I
6.5
7.5
8.5
9.5
6.5
7.5
8.5
9.5
r- 10.5
'h- 11.5
12.5
E3S1
E3S1
I
I
I
I
I
DEC
I
I
AUG
I
ce
I
I
I
I
40m
I
I
SEP
I
I
1
I
a
OCT
i
L
1982
a
1
.11
J
1
NOV
L
l
I
I
I
11
l
JAN
I
1
1
11
1
1
FEB
1
1
I
1983
1
I
MAR
I
I
I
EUREKA SHALLOW Temperature
I
EUREKA SHALLOW Temperature
II
J
i
APR
DEC
A
I
I
I
8.5
- 10.5
- 12.5
!- 11.5
- 13.5
14.5
8.5
9.5
10.5
11.5
12.5
13.5
14.5
15.5
4-32
5-1
SAN
123°
122°30'
San Fransisco
(H3, H4)
PACIFICA
so
SOUNDINGS IN METERS
0
5
10
km
15
%
':HALF MOON
BAY
37°30'
X30
lpo
'9o
c
100.0
B
B
pCE
.Y..4o
s0
o
Soo
y0
iooo
00
7°
5-4
5-5
SAMPLING INTERVAL = 60 MINUTES
STATION
H3S1
START TIME -(GMT)
APR 22,1981
2300
MIN
MAX
MEAN
STD
-22.6
-32.8
8.5
22.6
32.6
12.4
4.6
-1.1
9.6
7.6
12.1
0.7
AUG 16,1981
AUG 16,1981
AUG 16,1981
1000
1000
1000
34.8
4.8
10.6
T
-35.7
-38.7
9.5
48.7
14.7
4.3
11.6
14.3
1.1
JAN 30,1982
JAN 30,1982
JAN 30,1982
1300
1300
1300
U
-25.9
23.8
3.1
9.9
V
T
-26.9
10.5
37.0
12.3
5.8
11.3
13.7
0.3
MAR 10,1982
MAR 10,1982
MAR 10,1982
0800
0800
0800
U
-18.9
-29.8
30.9
5.3
8.0
V
T
28.8
13.4
-2.1
10.4
11.7
0.8
SEP 11,1982
SEP 11,1982
SEP 11,1982
0800
0800
0800
U
-31.8
V
T
-23.1
8.5
15.0
22.3
10.3
0.7
0.8
9.0
6.0
8.5
0.4
AUG 16,1981
AUG 16,1981
1000
1000
AUG 16,1981
1000
U
-38.5
V
-1.3
3.1
8.4
10.4
T
-32.6
9.2
25.4
40.0
13.3
10.5
0.8
JAN 30,1982 1300
JAN 30,1982 1300
JAN 30,1982 1300
U
-36.3
24.5
-0.5
8.7
MAY 22,1982
1100
V
-27.5
8.7
32.1
2.1
10.3
11.5
10.1
0.8
MAY 22,1982
MAY 22,1982
1100
1100
SEP 11,1982
SEP 11,1982
SEP 11,1982
0700
0700
0700
1400
1400
1400
U
V
T
H3S1
H3S1
H3S1
H3S2
H3S2
H3S2
AUG 17,1981
JAN 31,1982
MAY 23,1982
APR 23,1981
AUG 17,1981
JAN 31,1982
0100
0500
0100
0000
0100
0500
U
V
T
H3S2
MAY 23,1982
0100
19.0
-0.1
7.0
1.0
9.4
8.9
0.3
3.5
8.7
39.5
24.6
11.6
-4.4
12.2
14.0
U
-16.1
-31.5
32.2
V
T
29.6
8.3
U
V
T
MAY
8,1981
0700
H4S3
H4S3
MAY
MAY
8,1981
8,1981
AUG 17,1981
0800
0700
0300
-22.4
-41.6
0.6
JUN
4,1981
4,1981
4,1981
4.3
9.3
JUN
4,1981
1400
1.1
11.7
10.6
9.2
0.4
JUN
JUN
4,1981
4,1981
1400
1400
-29.8
22.3
-2.5
9.0
JUN
4,1981
1300
-23.2
33.1
4.4
10.3
JUN
4,1981
1300
T
8.0
9.9
8.7
0.2
JUN
4,1981
1300
U
V
-43.7
-31.5
8.6
34.4
59.9
11.6
-2.7
9.8
MAR
7.1
9.8
11.6
-MAR
0.5
MAR
6,1982
6,1982
6,1982
1000
1000
1000
U
V
T
H4S2
-29.6
-21.8
8.8
28.9
10.8
U
V
H4S1
9.0
STOP TIME
T
9.9 -
JUN
JUN
NORTH km
100 T
-j EAST km
I
-100
500
-100
-200
V Component
(NORTH)
U Component
(EAST)
H3S1
APR 22,1981
2300
--
AUG 16,1981
1000
NORTH km
700 -r-600 -F-
500 -+-
400 -}-
EAST km
-100
o0
200
300
400
500
600
700
-100
V Component
(NORTH)
U Component
(EAST)
H3S1
AUG 17,1981
0100
-
JAN 30,1982
1300
NORTH km
200 -r-
150
100 -
50
I
-50
100
50
EAST km
150
-50
V Component
(NORTH)
U Component
(EAST)
H3S 1
JAN 31,1982 0500
-
MAR 10,1982 0800
5-9
NORTH km
100 ---
I
-100
EAST km
600
-100
-200 -+-
-300 -+-
V Component
(NORTH)
U Component
(EAST)
H3S1
MAY
23,1982 0100
-
SEP 11.1982 0800
NORTH km
100 T
EAST km
-20 --&V Component
(NORTH)
U Component
(EAST)
H3S2
APR 23,1981
0000
-
AUG 16,1981
1000
NORTH ' km
500 --r-
400
300
EAST km
-300
-200
-100
100
-100
V Component
(NORTH)
U Component
(EAST)
H3S2
AUG 17,1981
0100
-
JAN 30,1982
1300
NORTH km
250 T
-50 -+V Component
(NORTH)
U Component
(EAST)
H3S2
JAN 31,1982 0500
-
MAY 22,1982
1100
5-13
NORTH km
100 T
-20
V Component
(NORTH)
U Component
(EAST)
H3S2
MAY 23,1982 0100
-
SEP 11,1982 0700
NORTH km
20 --r-
-i EAST km
-20
100
-20 +
-40
-60
V Component
(NORTH)
U Component
(EAST)
H4S1
MAY 8,1981
0700
-
JUN
4,1981
1400
5-15
EAST km
-20
_1
(
20
40
60
so
120
100
V Component
(NORTH)
U Component
(EAST)
H4S2
MAY 8,1981
0800
-
JUN
4,1981
1400
NORTH km
--r-
120
EAST km
-80
-60
-40
-20
20
-20 -1V Component
(NORTH)
U Component
(EAST)
H4S3
MAY 8,1981
0700
-
JUN
4,1981
1300
5-17
NORTH km
1400 ---
EAST km
-200
V Component
(NORTH)
U Component
(EAST)
H4S3
AUG 17,1981
0300
--
MAR 6,1982
1000
H4S3
H4S2
H4S 1
H3S2
H3S1
1----}-
I
APR
}---I------I
--E----}---____._
I
SAN FRANCISCO
1981
MAY
I - ---I
100m
38m
1-
U velocity
JUN
I- - --I--I----I
TW9111MIJIM1111W 1991.1"
I
I--
;;
E
i
H4S3
H4S2
H4S1
H3S2
H3S1
APR
38m
1981
MAY
SAN FRANCISCO V velocity
Um
68m
35m
JUN
H4S3
H3S2
H3S1
68m
35m
f
f
105m
65m
35m
JUL
SAN FRANCISCO
1981
AUG
U velocity
---} ---1-- }-- -- f }-----}---}----- ...1- 4
I
II
SEP
}--
H4S3
H3S2
H3S1
Aril
-j -E-} -
68m
IMU-Nmo
111111F1w
:1 35m
F
hi 1.1
ill h-j i
- AA
MMAnAA h .191A k
35m
_.T
ill, WI
--F
11
MAA
}
SEP
III
-1--
LAknvwWllNMl
11111401mrow
'LCLLOIll"Ll6l4l111
SAN FRANCISCO V velocity
1981
AUG
0 fl+f- 11 - 1 V 4
AMNAMMMA I
105m
65m
91MV111MMINNNUINM1W V" '-V PUTWUNPAKIIJ
WqA'A A-0
JUL
0
i
H4S3
H3S2
H3S1
35m
OCT
SAN FRANCISCO U velocity
1981
NOV
DEC
H4S3
H3S2
H3S1
-1
Ii i ITJ71 T;
lf+Y+fA'/"fY
105m
11l1
65m
35m
OCT
ifl!i
I
I
1981
NOV
1'1'I 4f141f
r.
4'
,
,
,
,
-,
,. 1I11I
1
I
DEC
,
11'
J,i,.+wl
"111
_
11'
,
.
'
II
-
'1n _i-
R,II
41'INI!li
li lllllllll (If'lih!;
lLlrrr alto,
r;llYl4til'lllli Irla
1' I
ii1'w"1
Kh IIIWI!IIluIaIIIN
,ILlll
.I'i
4
SAN FRANCISCO V velocity
-
Ir .r 17',
AIi''ul'Au' 1iil!i, I Iirlpili.i,i
m
--20
0
20
v
0
H4S3
H3S2
H3S1
35m
r
JAN
-F-----}-_I
I-rte--f
I
1982
FEB
1-4---- } --E
SAN FRANCISCO U velocity
I
35m
F{
MAR
IT-
I
0
20
H4S3
H3S2
H3S1
JAN
1982
FEB
I PIT,
YY"WVUI IWO
"
A fill I 1 11000
-0Y
11III110-
SAN FRANCISCO V velocity
-1-
IWI, IV UPT I
j I JQ
1 -.1111 qIA1W
MAI
35m
MAR
I
III
-+-
H3S2
H3S1
H3S2
H3S1
65m
35m
67m
35m
_F._
JUL
APR
I
1
I
F----I
I-
65m
I
U velocity
F-F
{1-----F f
All
1982
AUG
T
1982
MAY
I
SAN FRANCISCO
}--
7
---F
35m
SEP
JUN
I---I
-F---I4--+--F---41-.
H3S2
H3S1
H3S2
H3S1
65m
35m
JUL
APR
'
H
1982
MAY
I
i
JUN
-1-I_-I
SEP
I----{-- I+----+----+
---4--4
SAN FRANCISCO V velocity
1982
AUG
}-- I------I- 1_
}I --±_I -1---- -'
0
20
'
a
H3S2
H3S1
APR
APR
1981
7i
SAN FRANCISCO DEEP Temperature
1981
MAY
SAN FRANCISCO SHALLOW Temperature
35m,68m
JUN
7.5
r- 11.0
- 12.0
13.0
H4S3
H3S2
H3S1
JUL
JUL
1981
AUG
I
1981
AUG
I
SAN FRANCISCO DEEP Temperature
I
105m
SAN FRANCISCO SHALLOW Temperature
I
SEP
I
SEP
9.0
8.0
10.0
11.0
12.0
8.0
H4S3
H3S2
H3S1
OCT
OCT
1981
NOV
1981
NOV
I
1
I
SAN FRANCISCO DEEP Temperature
I
SAN FRANCISCO SHALLOW Temperature
I
DEC
DEC
r
-1
I-
8.0
9.0
- 11.0
12.0
H4S3
H3S2
H3S1'
I
35m,67m
1982
FEB
1
MAR
JAN
I
1982
FEB
SAN FRANCISCO DEEP Temperature
I
MAR
SAN FRANCISCO SHALLOW Temperature
JAN
35m,65m
I
8.0
- 9.0
F- 10.0
11.0
12.0
8.0
9.0
10.0
11.0
12.0
13.0
I
I
I
I
I
I
1982
MAY
1
I
II
I
I
SEP
I
r--
13.5
I
I
1982
AUG
v--v-
SAN FRANCISCO SHALLOW Temperature
JUL
-r_
8.5
H3S2
APR
1
h- 10.5
C 9.5
I
H3S1
I
67m
r- 12.5
I- 11.5
H3S2
H3S1
I
SAMPLING INTERVAL = 360 MINUTES
STATION
MIN
START TIME -(GMT)
MAX
MEAN
STOP TIME
STD
U
V
T
-8.5
-15 . 3
15.4
4.7
-1 . 1
3.9
11 . 7
6 .0
AUG 15,1981
AUG 15 , 1981
0600
0000
8.8
11.3
9.6
0.6
AUG 15,1981
0600
0600
U
V
T
20.8
27 . 0
13.9
4.7
4 .4
11.6
5.4
7 .4
1.0
JAN 29,1982
JAN 29 , 1982
JAN 29,1982
1200
PRINCIPAL AXIS = -23.1
-11.0
-13 . 3
9.9
-11.4
13.6
22 . 6
11.7
2.9
5. 9
11.2
4.8
MAR
MAR
MAR
9,1982
9 , 1982
9,1982
1200
6 .6
0.2
17.3
14 . 8
12.1
5.4
-2 . 2
10.4
4.8
6 .1
0.7
SEP 10,1982
SEP 10, 1982
SEP 10,1982
1200
1200
1200
AUG 15,1981
AUG 15 , 1981
AUG 15,1981
1200
1200
1200
H3S1
APR 24,1981
0000
PRINCIPAL AXIS = -19.0
H3S1
H3S1
AUG 18,1981
FEB
1,1982
0600
PRINCIPAL AXIS = -27.7
H3S1
MAY 24,1982
0600
U
V
T
-7 . 5
10.9
1200
1200
1200
1200
T
-8.4
-17 . 3
9.1
U
V
T
-6.7
-8 . 3
8.5
7.2
0.7
2.5
8 .6
0.8
9.0
3.5
-13.1
-6 . 1
9.3
8.9
14 . 1
12.5
-1.4
10.5
3.3
4.5
0.8
JAN 29,1982
JAN 29 , 1982
PRINCIPAL AXIS = -29.0
U
V
T
0600
U
-8.6
9.4
V
-7 . 1
8.8
12 . 3
-0.5
2.1
10.1
3.3
4.1
0.7
MAY 21,1982
MAY 21 , 1982
MAY 21,1982
1200
1200
1200
-0.1
0. 9
9.4
2.8
3.5
0.3
SEP 10,1982
SEP 10 , 1982
SEP 10,1982
1200
1200
1200
3.9
8.5
JUN
JUN
3,1981
3,1981
1800
1800
3,1981
1800
PRINCIPAL AXIS = -34.4
H3S2
APR 24,1981
0000
PRINCIPAL AXIS = -25.3
H3S2
H3S2
AUG 18,1981
FEB
1,1982
0600
U
V
9.9
3 .2
0.4
1200
1200
JAN 29,1982 1200
PRINCIPAL AXIS = -32.5
T
0600
U
V
-8.2
5.8
-6 . 3
11 . 6
T
8.9
10.1
U
V
-7.5
-16.8
11.2
3.7
9.5
9.2
-3.6
T
11.4
10.7
9.9 -
0.4
JUN
1200
U
-0.2
-4.6
-11.0
8.7
12.2
13.5
9.6
4.3
2.3
9.2
3.6
6.4
0.2
JUN 3,1981 1200
V
T
JUN
JUN
3,1981
3,1981
1200
1200
-8.3
-5 . 4
8.2
1.1
-2.8
2.3
12 . 8
5 .3
4. 6
9.0
8.7
0.2
JUN
JUN
JUN
3,1981
3 , 1981
3,1981
1200
1200
1200
-13.3
-15 . 2
11.3
-2.7
MAR
5,1982
5 , 1982
1200
7.1
4.6
7.3
MAR
1
8.8
10.9
9.8
0.4
MAR
5,1982
H3S2
MAY 24,1982
PRINCIPAL AXIS = -35.9
H4S1
MAY
9,1981
PRINCIPAL AXIS =
H4S2
MAY
9,1981
PRINCIPAL AXIS =
H4S3
MAY
9,1981
1200
1200
PRINCIPAL AXIS = -16.5
H4S3
AUG 18,1981
0600
PRINCIPAL AXIS = -29.6
U
V
T
U
11.4
25 .
1200
1200
5-34
H4S3 =
H4S2
H4S1 =
H3S2
H3S1
I
I
I
i
i
l
l
11 M-NA -09
i
I
l
TAT-TT-1 t l i
i
i
I
1
1 111111
1981
SAN FRANCISCO velocity
1982
1983
PR JUN AUG OCT DEC FEG APA JUN Aud bct bEC EE6 APR JUN AuO Oct bE
I
APR
1981
JUN
SAN FRANCISCO
MAY
velocity
JUL
AUG
AUG
105m
65M
35m
SEP
PTT
SAN FRANCISCO
1981
OCT
velocity
NOV
DEC
ITTT011
JAN
i
JAN
V.,.,r,,
H4S3
I
67m
au11
FEB
105m
SAN FRANCISCO
1982
MAR
APR
velocity
i iH1aIIi--i--f
...,,,
MAY
4--+-i--1
c1au.~r"1.,,u, ,,,u,, 6.,,vr', a.,e.au.....,,w
: 35mv,c.,/,lat'u
H3S2
H3S1
65m
H3S2
MAY
35m
H3S1 E
1982
JUL
AUG
SAN FRANCISCO velocity
JUN
a ..,..,u''',a''-''
SEP
H4S3
H4S2
H4S1
H3S2
H3S1
E
APR
100m
70m
38m
68m
35m
!1---Ii-1
1981
JUN
JUL
4-i-V
SAN FRANCISCO U velocity
MAY
I
I-1
AUG
I
20
0
20
H4S3
H4S2 :
H4S1
H3S2 :
H3S1
APR
100m
70m
38m
68m
35m
1981
JUN
JUL
SAN FRANCISCO V velocity
MAY
M
tkl
AUG
20
H4S3 -
H3S2
WWI
AUG
105m
65m
35m
SEP
NOV
SAN FRANCISCO U velocity
1981
OCT
1a
DEC
JAN
r
20
0
20
aai
AUG
SEP
NOV
SAN FRANCISCO V velocity
1981
OCT
DEC
JAN
H4S3
H3S2
H3S1
67m
1982
MAR
APR
SAN FRANCISCO U velocity
FEB
105m
1111"I evvill-I give oil
35m
MAY
E
H4S3
H3S2
H3S1
JAN
67m
35m
1982
MAR
-404
APR
cl - a I-
SAN FRANCISCO V velocity
FEB
105m
ILAI -
MAY
H
-20
0
20
a)
U
MAY
65m
I
1982
JUL
ii-
AUG
1
1
SAN FRANCISCO U velocity
JUN
om ,tom
-M
SEP
F
C
H3S2
H3S1
MAY
65m
35m
1982
JUL
AUG
SAN FRANCISCO V velocity
JUN
SEP
C
C
H4S3
H4S2
H4S1
I
I
I
I
I
r T-T
APR
I
MAY
I
I
1
11
1
JUN
1
1
1981
1
1
I
1
1
a
JUL
I
I
1
II
1
I
I
I
I
MAY
I
I
a
It
I
JUN
I
I
1981
I
I
I
I
I
JUL
I
I
AI
I
SAN FRANCISCO DEEP Temperature
I
a
I
SAN FRANCISCO SHALLOW Temperature
I
38m,70m,100m
I
AUG
I
AUG
1
I
1
1
11
J
I-
7.5
8.5
r- 10.5
-- 9.5
11.5
7.5
12.5
H4S3
H3S2
H3S1
Ls
AUG
I
AUG
I
I
l
1981
OCT
NOV
DEC
I
I
I
I
OCT
I
1
1981
I
L
Il
1
1
NOV
1
L
1
1
1
1
DEC
J
1
SAN FRANCISCO DEEP Temperature
SEP
IJ
SAN FRANCISCO SHALLOW Temperature
SEP
JAN
JAN
8.0
12.0
8.5
9.5
10.5
11.5
F- 12.5
- 13.5
14.5
I
I
1_.
JAN
I
JAN
I
I
I
I
I
II
II
I
FEB
I
I
I
MAR
.... I
1982
I
I
APR
I
I
I
I
I
I..
I
I
MAY
1
I
FEB
r-TT
I
I
I
I
I
MAR
I
I
I
I
1982
II
I
APR
I
I
I
I
I
1
I
MAY
I
I
SAN FRANCISCO DEEP Temperature
I
II
I.
I
iI
I
I
JUN
I
JUN
-T--- i --- 1- U--TI - -v --v- 7
I
SAN FRANCISCO SHALLOW Temperature
I
I
I
T7
11
8.0
12.0
8.0
H3S2
H3S1 7
L
i
I
I
it
MAY
I
i
JUN
I
I
I
1
I
JUL
I
1
1982
o
1
11
1
1
AUG
1
1
1
11
1
1
SAN FRANCISCO SHALLOW Temperature
35m,65m
I
SEP
1
1
E-
8.0
9.0
- 10.0
F- 11.0
- 12.0
13.0
5-52
PURISIMA POINT
121°
120030'
350
N
0
O
Purisima Point
(P3, P4)
SOUNDINGS IN METERS
0
5
km
10
15
1
`1o
0
I
I
34030'
6-4
SAMPLING INTERVAL = 60 MINUTES
STATION
START TIME -(GMT)
MIN.
MAX
MEAN
STD
STOP TIME
P3S1
FEB
8,1981
0500
U
V
T
-30.1
-45.2
9.4
33.9
50.5
14.3
5.1
3.6
11.8
11.4
18.2
1.2
MAY
MAY
MAY
6,1981
6,1981
6,1981
0800
0800
0800
P3S1
MAY
7,1981
0200
U
-27.4
-28.4
32.1
44.8
4.0
V
7.6
10.0
12.6
T
9. 8
14 . 8
11 . 4
0. 8
AUG 17,1981
AUG 17,1981
AUG 17 , 1981
1100
1100
1100
U
-35.8
-37.8
10.3
36.4
49.0
15.0
3.5
5.6
12.3
11.7
15.6
0.8
JAN 31,1982
JAN 31,1982
JAN 31,1982
1400
1400
1400
-27.8
-62.0
9.2
29.5
40.1
13.5
-5.1
4.1
9.8
11.5
16.2
0.8
MAY 23,1982
MAY 23,1982
MAY 23,1982
1000
1000
1000
-21.6
-32.2
31.5
53.2
2.0
3.5
13.9
SEP 12,1982
SEP 12,1982
9. 5
14 . 9
11 . 2
0. 9
SEP 12 , 1982
1000
1000
1000
-28.4
-39.7
1.8
4.5
10.9
10.8
14.6
1.1
MAY
MAY
8.9
32.0
40.2
13.9
6,1981
6,1981
MAY _6,1981
0800
0800
0800
U
-28.1
26.2
0.8
V
-27.5
34.1
T
9 .3
12 . 3
7.1
10 . 3
8.8
10.2
0. 4
AUG 17,1981
AUG 17,1981
AUG 17 , 1981
1100
1100
1100
U
V
-33.9
-27.4
9.8
28.3
52.9
13.9
5.7
11.1
9.8
11.2
0.6
JAN 31,1982
JAN 31,1982
JAN 31,1982
1400
1400
1400
29.0
39.9
T
-30.1
-36.4
9.1
2.0
3.7
10.7
9.8
13.4
0.8
MAR 21,1982
MAR 21,1982
MAY 23,1982
1300
1300
1000
U
V
-30.1
-36.4
24.3
29.6
0.6
T
9 .0
13 . 5
0.0
10 . 4
8.2
9.8
0. 7
JUL 12,1982
JUL 12,1982
SEP 13 , 1982
1100
1100
1500
U
V
-34.9
-46.4
9.2
43.0
0.0
11.2
50.5
6.0
18.6
14.3
11.8
1.2
MAY
MAY
MAY
6,1981
6,1981
6,1981
1200
1200
1200
-37.2
-37.8
10.0
26.9
53.2
13.0
-2.0
10.0
11.5
15.2
0.6
AUG 17,1981
1100
1100
2000
P3S1
AUG 18,1981
0600
V
T
P3S1
FEB
1,1982
0800
U
V
T
P3S1
MAY 24,1982
0100
U
V
T
P3S2
FEB
8,1981
0500
U
V
T
P3S2
P3S2
MAY
7,1981
AUG 18,1981
0200
0500
T
P3S2
P3S2
P4S1
FEB
1,1982
MAY 25,1982
FEB
8,1981
0800
0600
0600
U
V
T
P4S1
MAY
7,1981
0400
U
V
T
13.1
0.4
11.5
9.2
-AUG 17,1981
MAY 26,1981
6-6
SAMPLING INTERVAL = 60 MINUTES
STATION
P4S1
START TIME -(GMT)
AUG 18,1981
0300
MIN
MEAN
STD
35.4
58.6
14.9
-2.6
T
-31.8
-42.3
9.9
11.2
12.0
10.0
16.9
0.8
OCT 14,1981
OCT 14,1981
JAN 18,1982
1400
1400
2300
U
V
T
-36.1
-61.4
9.8
36.5
49.5
13.5
-0.7
-3.8
11.3
19.3
0.7
MAY 23,1982
MAY 23,1982
MAY 23,1982
0800
0800
0800
U
29.3
51.2
15.4
-2.2
8.2
SEP 12,1982 1100
V
T
-32.2
-32.6
9.4
U
-29.3
30.1
V
-41.2
47.4
1.4
5.6
15.8
T
8.8
13.5
10.7
0.8
U
V
T
-28.3
-29.6
9.3
28.9
50.4
12.2
-0.9
9.9
11.8
10.4
13.8
U
-30.3
-31.2
9.4
35.1
49.7
13.0
-0.7
V
T
-25.7
-51.7
9.1
38.0
47.6
1.4
0.0
12.9
10.7
U
V
T
-27.6
-26.7
9.2
26.0
58.6
-1.6
8.4
11.2
10.2
14.6
0.6
U
T
7.8
43.1
48.8
11.4
-0.2
V
-39.6
-38.8
U
-35.0
-26.1
8.8
24.3
45.1
10.6
0.7
6.6
9.5
10.2
11.6
-45.4
-33.0
8.8
31.1
-1.3
48.4
11.4
11.9
-37.3
-37.5
8.2
34.8
48.2
11.9
U
V
P4S1
P4S1
P4S2
P4S2
P4S2
FEB
1,1982
MAY 23,1982
FEB
MAY
8,1981
7,1981
AUG 18,1981
0700
2300
0600
0400
0300
V
T
P4S2
P4S2
P4S3
P4S3
FEB
1,1982
MAY 23,1982
FEB
MAY
8,1981
7,1981
0700
2300
0600
0400
U
V
T
P4S3
AUG 18,1981
0300
U
V
T
P4S3
FEB
1,1982
0700
STOP TIME
MAX
U
V
T
12.7
11.6
11.8
6.9
11.1
11.4
10.7
SEP 12,1982
SEP 12,1982
1100
1100
6,1981
6,1981
6,1981
1200
1200
1200
AUG
AUG
0.5
6,1981
6,1981
AUG 17,1981
0700
0700
1100
8.6
12.9
0.5
JAN 18,1982
JAN 18,1982
JAN 18,1982
2300
2300
2300
10.3
16.1
0.7
MAY 23,1982
MAY 23,1982
MAY 23,1982
0800
0800
0800
13.9
0.9
9.5
12.4
12.3
6.1
9.5 - 0.5
8.4
9.8
0.6
3.0
9.5
MAY
MAY
MAY
SEP 12,1982 1100
SEP 12,1982 1100
SEP 12,1982 1100
MAY
MAY
MAY
6,1981
6,1981
6,1981
1200
1200
1200
AUG 17,1981
AUG 17,1981
AUG 17,1981
1100
1100
1100
0.4
JAN 18,1982
JAN 18,1982
JAN 18,1982
2300
2300
2300
11.6
12.1
0.5
MAY 23,1982
MAY 23,1982
MAY 23,1982
0800
0800
0800
0.3
SAMPLING INTERVAL = 60 MINUTES
STATION
P4S3
MIN
START TIME -(GMT)
MAY 23,1982
2300
U
V
-44.5
-27.2
T
8.8
MAX
MEAN
STD
34.5
54.8
11.6
-1.7
12.3
12.6
7.7
9.6
0.4
STOP TIME
SEP 12,1982
SEP 12,1982
SEP 12,1982
1100
1100
1100
NORTH km
400 --r-
200
100
I
I
-100
200
100
300
EAST km
400
-100
V Component
(NORTH)
U Component
(EAST)
P3S1
FEB 8,1981
0500
-
MAY 6,1981
0800
NORTH km
700 T
600 -+500 -4-
400 -300 -4-
EAST km
-100
1
100
300
200
400
-100
V Component
(NORTH)
U Component
(EAST)
P3S1
MAY 7,1981
0200
-
AUG 17,1981
1100
NORTH km
1000 -r-
800 -F-
600 --4-
400
200 --1-
-J EAST km
-200
400
200
600
-200
V Component
(NORTH)
.40
tJ..aj
i y30 +
y '
U Component
(EAST)
P3S 1
AUG 18,1981
0600
-
JAN 31,1982
1400
NORTH km
200 100
d EAST km
-100
100
300
200
400
-400
-500
-600
V Component
(NORTH)
U Component
(EAST)
P3S1
FEB
1,1982 0800
-
MAY 23,1982
1000
NORTH km
350
EAST km
-150 -1V Component
(NORTH)
U Component
(EAST)
P3S 1
MAY 24,1982 0100
-
SEP 12,1982
1000
NORM km
350
T
300
200 -+150 --F-
100 -+-
---- EAST km
I
-50
1
50
100
150
-50
V Component
(NORTH)
U Component
(EAST)
P3S2
FEB 8,1981
0500
--
MAY 6,1981
0800
NORTH km
700 -r-
EAST km
-100
V Component
(NORTH)
U Component
(EAST)
P3S2
MAY 7,1981
0200
-
AUG 1.7,1981
1100
NORTH km
1000 -r-
Boo
600
I
400
F
4
EAST km
-200
200
-200 1
V Component
(NORTH)
U Component
(EAST)
P3S2
AUG 18,1981
0500
-
JAN 31,1982
1400
NORTH km
--r-
200
150
100
I
I
-50
50
EAST km
100
-50
V Component
(NORTH)
U Component
(EAST)
P3S2
FEB
1.1982 0800
-
MAR 21,1982 1300
V Component
(NORTH)
U Component
(EAST)
P4S 1
FEB
8,1981
0600
-
MAY 6,1981
1200
NORTH km
1000 T
EAST km
-400
-200
200
-200 y
V Component
(NORTH)
U Component
(EAST)
P4S1
MAY 7,1981
0400
-
AUG 17,1981
1 100
NORTH km
600 -r-
-100
V Component
(NORTH)
U Component
(EAST)
P4S1
AUG 18,1981
0300
-
OCT 14,1981
1400
EAST km
V Component
(NORTH)
U Component
(EAST)
P4S1
FEB
1,1982 0700
-
MAY 23,1982 0800
6-21
NORTH km
800 -r-
400
AUG 5,1982 0300 AUG 10,1982 0000
300
Zoo
100
`-`1---} EAST km
V Component
(NORTH)
U Component
(EAST)
P4S1
MAY 23,1982 2300
-
SEP 12,1982
1100
EAST km
V Component
(NORTH)
U Component
(EAST)
P4S2
FEB
8,1981
0600
-
MAY
6,1981
1200
NORTH km
1000 -tom
400
200
I
i
-200
EAST km
200
-200
V Component
(NORTH)
U Component
(EAST)
P4S2
MAY 7,1981
0400
-
AUG 6,1981
0700
NORTH km
1600
--r-
-200 -+V Component
(NORTH)
U Component
(EAST)
P4S2
AUG 18,1981
0300
--
JAN 18,1982 2300
6-25
EAST km
V Component
(NORTH)
P4S2
FEB
1,1982 0700
-
MAY 23,1982 0800
NORTH km
1200 T
-200
V Component
(NORTH)
P4S2
MAY 23,1982 2300
-
SEP 12,1982
1100
-100
100
1
V Component
(NORTH)
U Component
(EAST)
P4S3
FEB
8,1981
0600
-
MAY 6,1981
1200
d EAST km
-100
100
-100
V Component
(NORTH)
U Component
(EAST)
P4S3
MAY 7,1981
0400
-
AUG 17,1981
1100
NORTH km
1200 --r-
d EAST km
-200
200
-200 -LV Component
(NORTH)
U Component
(EAST)
P4S3
AUG 18,1981
0300
-
JAN 18,1982 2300
NORTH km
300 -
r-so
-J EAST km
-50
50
1
100
-50 -V Component
(NORTH)
U Component
(EAST)
P4S3
FEB
1,1982 0700
-
MAY 23,1982 0800
EAST km
V Component
(NORTH)
U Component
(EAST)
P4S3
MAY 23,1982 2300
-
SEP 12,1982
1100
P4S3
P4S2
P4S1
P3S2
P3S1
JAN
}---- I
II
1981
FEB
I
PURISIMA POINT U velocity
69m
39m
67m
61 AMIldighli.11.1
37m
MAR
P4S3
P4S2
P4S1
P3S2
P3S1
PURISIMA POINT V velocity
1 `l IJ1,11'i'1'I7'duil I
P4S3
P4S2
P4S1
P3S2
P3S1
-I 39m
- 37m
I
APR
--I-----+---- A
1981
MAY
I
PURISIMA POINT U velocity
34m
39m
JUN
-F--
P4S3
P4S2
P4S1
P3S2
P3S1
i"
'
jaAl
h.
owl
APR
P
Md
1 Md 11 J
39m
1981
MAY
""V"I
vwj 11
{JI. I I4 J. U LII
JUN
jig" OWN%
IiAkIUIILIII
1 A11!!Ir F1 P 1A'h'NI1II!1Iii
PURISIMA POINT V velocity
IIIIN1111wVV`'1
' Tivtri ' 'INVI°I
lN'"1r'
IVVVIV1IIIY
37m
P4S3
P4S2
P4S1
P3S2
P3S1
2 69m
J 39m
JUL
--F
PURISIMA POINT
1981
AUG
NAY
U velocity
70m
40m
SEP
IMIRMAIL11 10-
0
20
20
aUi
P4S3
P4S2
P4S1
P3S2
P3S1
-1 124m
-1 64m
69m
-1 39m
JUL
'l ui
19MP
i 11"A
IYAU
f
76m
0
46m
1981
AUG
IHl1'141,741I1 ',f
'i',1,I'i ILY"riv,
Il10
40m
IIfiNl
IN
SEP
v1Y11Itii'Uliirillllh'i'1'LtiYWUlmY'iII
IhIIIVUIIIY
uIW
yyr,
IIII'`'I!Itlt ,11,j'IIIIII, II 11'!11
"IIL
'J'Iu'
X111, F71 yi,IIVAMirjj&Vll.
I11mr,T I - VI!'
will
PURISIMA POINT V velocity
V' 'Wmnl!
.oll,
I'
ill dall1"'I III IIII641 10
I
E
E
P4S3
P4S2
P4S1
P3S2
P3S1
136m
40m
OCT
PURISIMA POINT
1981
NOV
0,41
1111IIi I
U velocity
g4,iI,
lI1i
DEC
I& ,ii;l+
P4S3
P4S2
P4S1
P3S2
P3S1
j
136m
: 76m
OCT
i'il'1,0i
1981
NOV
PURISIMA POINT V velocity
W
,I.;'I'1!;4'lif I,I!RRI! !i 'i !!411 I!4' 4tI; 'lll,'u
71'[1 !Vi
DEC
;! Ieil Ib°°'u ''IIILI''
ml
P4S3
P4S2
P4S1
P3S2
P3S1
-1
40m
JAN
'1
1
I
1
38m
1
1982
FEB
1
H- _-
U velocity
1
l 1-_ ti
PURISIMA POINT
1
MAR
1
1
1__
P4S3
P4S2
P4S1
P3S2
P3S1
40m
JAN
I
If
niuInli
1982
FEB
s
IMP 11 ITF I -1p.1
AL"WAN
L
I'i!Ifl'I1,1'11L'''
K
PURISIMA POINT V velocity
Hill
11111
38m
1111
1wu
MAR
0'111Pllili
__.
11/11/1111
Inn
mm
E
+---_I I--
20
P4S3
P4S2
P4S1
P3S2
P3S1
1
132m
38m
APR
PURISIMA POINT
1982
MAY
H
U velocity
139m
40m
H
JUN
-.1---+f
f
rE
P4S3
P4S2
P4S1
P3S2
P3S1
E
-j--1
132m
38m
38m
APR
4
1982
MAY
139m
72m
42m
40
PURISIMA POINT V velocity
I
}
1
nil;
JUN
I
1
I
11
11"11,1119
it
i i(
1,
f11
.
,
mi
E
E
P4S3
P4S2
P4S1
P3S2
P3S1
72m
42m
: 139m
:1
:1
JUL
II
: 40m
PURISIMA POINT
1982
AUG
U velocity
I
SEP
_H-..}__-i
I-----}
---i
P4S3
P4S2
P4S1
P3S2
P3S1
PURISIMA POINT V velocity
1982
AUG
P4S3
P4S2
P4S1
-
I
I
1981
FEB
MAR
JAN
I
,I
I
I
1981
FEB
1
I
PURISIMA POINT DEEP Temperature
I
39m,69m,129m
I
MAR
PURISIMA POINT SHALLOW Temperature
JAN
I
7.5
E 8.5
9.5
10.5
11.5
12.5
13.5
14.5
8.5
9.5
10.5
11.5
12.5
13.5
14.5
P4S3
P4S2
P4S1
P3S2
P3S1
1
APR
APR
37m,67m
I
1981
MAY
I
I
I
I
JUN
PURISIMA POINT DEEP Temperature
1981
MAY
--JUN
PURISIMA POINT SHALLOW Temperature
I
39m,69m
1
-
-
C
7.5
8.5
9.5
10.5
11.5
12.5
13.5
8.5
9.5
10.5
11.5
12.5
13.5
14.5
P4S3
P4S2
P4S1
P3S2
P3S1
, ,1
If
4
I
I
JUL
Ll
39m,69m
I
1981
AUG
I
I
oil,
I
PURISIMA POINT DEEP Temperature
1981
PURISIMA POINT SHALLOW Temperature
I
Al
.
l
40m,70m
SEP
I
)
I
,
1,
,
.
++
8.0
9.0
10.0
11.0
12.0
13.0
14.0
15.0
9.0
1- 10.0
- 11.0
-12.0
13.0
14.0
15.0
P4S3
P4S2
P4S1
P3S2
P3S1
I
OCT
OCT
I
PURISIMA POINT DEEP Temperature
1981
NOV
PURISIMA POINT SHALLOW Temperature
1981
NOV
DEC
DEC
:
8.0
12.0
13.0
14.0
15.0
9.0
10.0
11.0
12.0
13.0
14.0
15.0
P4S3
P4S2
P4S1
P3S2
P3S1
-I
I
L
I
I
JAN
I
I
I
t
I
I
I
I
I
'I! IA
- Iv.
-I1
.MII Ilil',
1982
FEB
38m,71 m,132 n
I I
I
I
I
I
I
PURISIMA POINT DEEP Temperature
46m,76m,136m
I
1982
FEB
I
I
MAR
PURISIMA POINT SHALLOW Temperature
JAN
t
I
I
I
I
I
7.5
8.5
9.5
10.5
11.5
12.5
13.5
8.5
9.5
10.5
11.5
I- 12.5
1- 13.5
P4S3
P4S2
P4S1
P3S2
P3S1
-I
-I
I
I
I
I
r
T-
APR
T
I
11
I
o
I I ,
, I ,
.i
I
II
I
I; Il<1ii
I
i
I
,
1982
MAY
I
I
I
I
I
I
I
1982
MAY
I
II
I
I
I
Ili+ lll
JUN
I
,
I
F11
I
JUN
1'l,. :,4mu'l.Nl!',!111i(.J, Ir,s,
L,
1
42m,72m,139m
I
PURISIMA POINT DEEP Temperature
---I
I
PURISIMA POINT SHALLOW Temperature
I
I
38m,71 m,.1 32m
I
APR
38m,68m
I
.
I
,
Al
,_
-
7.5
8.5
9.5
10.5
11.5
12.5
13.5
14.5
8.5
- 13.5
14.5
P4S3
P4S2
P4S1
JUL
I
1982
AUG
I I
I
PURISIMA POINT DEEP Temperature
I
PURISIMA POINT SHALLOW Temperature
SEP
SEP
8.5
9.5
r- 10.5
11.5
12.5
13.5
r-- 15.5
I-- 14.5
9.0
-- 10.0
!-- 11.0
- 12.0
13.0
14.0
15.0
SAMPLING INTERVAL = 360 MINUTES
STATION
P3S1
START TIME -(GMT)
FEB
9,1981
0600
PRINCIPAL AXIS = -12.0
P3S1
MAY
8,1981
PRINCIPAL AXIS =
P3S1
0600
21.4
MIN
-15.0
20.6
5.0
6.3
MAY
5,1981
1200
35 . 6
13.7
3. 5
11.8
14 . 1
MAY
MAY
5 , 1981
T
-30 . 9
9.8
5,1981
1200
1200
U
V
T
-18.2
-16.6
10.4
20.0
29.8
12.6
4.1
5.7
7.8
8.8
11.4
0.5
AUG 16,1981
AUG 16,1981
AUG 16,1981
1200
1200
1200
-11.4
-20.8
11.0
14.4
30.7
13.8
3.5
5.0
JAN 30,1982
5.6
12.3
9.3
0.5
JAN 30,1982
JAN 30,1982
1800
1800
1800
14.1
MAY 22,1982
MAY 22,1982
MAY 22,1982
1200
1200
1200
1200
1200
1200
1200
1200
U
V
PRINCIPAL AXIS =
-4.8
T
1200
U
V
4.1
4.4
-5.3
12.9
11.5
12.2
0.6
2.0
3.4
11.2
10.7
0.7
SEP 11,1982
SEP 11,1982
SEP 11,1982
1.8
4.4
MAY .5,1981
PRINCIPAL AXIS =
-1.9
T
MAY 25,1982
0600
U
V
T
-8.4
-17.7
10.3
13.0
33.1
13.6
U
V
T
-11.1
-24.5
9.4
15.0
22.9
13.3
U
V
-6.3
-11.0
9.6
P3S1
PRINCIPAL AXIS =
-1.2
9,1981
0600
P3S2
FEB
PRINCIPAL AXIS =
-6.0
8,1981
0600
P3S2
MAY
PRINCIPAL AXIS =
2.2
T
AUG 19,1981
0600
U
V
P3S2
PRINCIPAL AXIS =
1.2
23.8
-8.1
-35.5
10.3
2,1982
STOP TIME
STD
V
0600
FEB
MEAN
U
AUG 19,1981
P3S1
MAX
4.3
4.5 - 10.0
MAY
10.9
1.0
MAY
14.2
0.7
3.4
11.2
7.3
10.3
6.6
AUG 15,1981
23.9
-11.7
-14.4
10.1
13.3
5,1981
5,1981
1200
0.3
AUG 15,1981
AUG 15,1981
0000
0000
0000
0.4
3.6
JAN 30,1982
1200
28.1
5.8
11.1
JAN 30,1982
JAN 30,1982
1200
12.4
6.7
0.4
10.0
16.8
1.9
3.8
4.2
8.3
MAR 20,1982
MAR 20,1982
12.6
10.7
0.7
MAY 22,1982
1800
1800
1200
1200
-7.2
T
2,1982
1200
U
V
PRINCIPAL AXIS =
2.5
T
-7.7
-14.8
9.6
MAY 25,1982
0600
U
0.0
0.0
0.0
0.0
0.0
0.0
0.0
0.0
JUL 10,1982
JUL 10,1982
PRINCIPAL AXIS =
0.0
V
T
9.5
12.3
10.4
0.6
SEP 11,1982
1200
1200
1200
9,1981
0600
U
V
T
-19.1
-27.9
9.7
15.1
0.0
5.9
6.3
14.3
MAY
MAY
11.8
1.1
MAY
5,1981
5,1981
5,1981
1200
1200
1200
-21.3
-12.5
10.6
11.4
39.4
12.6
-1.9
6.9
9.9
0.5
AUG 16,1981
AUG 16,1981
MAY 25,1981
1200
1200
1800
P3S2
P3S2
P4S1
FEB
FEB
PRINCIPAL AXIS =
-8.8
8,1981
0600
U
V
PRINCIPAL AXIS =
-6.7
T
P4S1
MAY
37.3
13.7
10.3
11.5
SAMPLING INTERVAL = 360 MINUTES
STATION
P4S1
START TIME -(GMT)
AUG 19,1981
0600
MIN
-2.6
5.5
12.4
0.6
-9.2
24.0
32.9
T
10.5
13.6
-16.9
-38.5
-0.8
-3.8
10.5
16.4
34.8
13.0
12.1
37.2
13.6
-2.1
2,1982
1200
U
PRINCIPAL AXIS =
2.4
V
T
MAY 25,1982
0000
U
PRINCIPAL AXIS =
-4.1
T
-21.8
-16.0
9.9
9,1981
0600
U
-12.6
P4S1
STD
-13.6
-9.0
FEB
MEAN
V
U
PRINCIPAL AXIS =
P4S1
MAX
V
11.7
12.0
11.8
6.6
11.1
6.0
STOP TIME
OCT 13,1981 .1800
OCT 13,1981 1800
JAN 18,1982 0000
15.4
0.5
MAY 22,1982
MAY 22,1982
MAY 22,1982
1200
1200
1200
4.6
11.0
0.7
SEP 11,1982
SEP 11,1982
SEP 11,1982
1200
1200
1200
MAY
MAY
MAY
5,1981
5 , 1981
5,1981
1200
5,1981
5 , 1981
1.3
4.9
-22 . 4
12.3
V
28 . 7
5.5
12 . 1
T
9.3
12.2
10.7
0.7
0600
U
10.4
-1.0
5.2
31 . 8
11 . 9
8.9
AUG
AUG
PRINCIPAL AXIS = -20.3
V
T
-19.2
-7 . 7
9.7
11.5
10.4
0.4
AUG 16,1981
0600
0600
1200
0600
U
-14.2
14.4
-0.8
4.6
-10 . 9
9.8
30 . 1
11 . 4
8 .7
PRINCIPAL AXIS = -17.7
V
T
11.8
10.7
JAN 18,1982
JAN 18 , 1982
JAN 18,1982
0000
0000
0000
U
-12.6
13.6
1.4
4.7
V
-28 . 6
32 . 0
0. 0
12 . 0
T
9.8
12.2
10.7
0.5
MAY 22,1982
MAY 22 , 1982
MAY 22,1982
1200
1200
1200
0000
U
4.4
-8.8
11.1
36.2
11.9
11.1
10.2
11.7
PRINCIPAL AXIS =
-13.9
-9.8
9.4
-1.5
V
T
0.5
SEP 11,1982
SEP 11,1982
SEP 11,1982
1200
1200
1200
9,1981
0600
U
-6.1
4.8
-0.2
-8.4
V
T
-11.7
8.7
20.3
10.5
6.0
9.5
2.2
7.1
0.4
MAY
MAY
MAY
5,1981
5,1981
5,1981
1200
1200
1200
8,1981 0600
U
-5.9
PRINCIPAL AXIS =
-9.3
-14.3
9.1
5.8
25.6
10.0
0.7
6.7
9.5
2.3
V
T
7.7
0.2
AUG 16,1981
AUG 16,1981
AUG 16,1981
1200
1200
1200
AUG 19,1981
0600
U
-8.6
5.5
2.6
JAN 18,1982
V
T
-13 . 4
-1.4
22 . 7
8. 4
5 .9
JAN 18 , 1982
9.2
10.5
9.8
0.3
JAN 18,1982
0000
0000
0000
1200
U
-4.4
-12.0
-5.9
V
T
5.6
22.4
10.2
0.6
3.1
9.5
2.0
6.9
0.3
MAY 22,1982
MAY 22,1982
MAY 22,1982
1200
1200
1200
P4S2
FEB
PRINCIPAL AXIS = -12.3
P4S2
P4S2
P4S2
MAY
8,1981
AUG 19,1981
FEB
2,1982
1200
PRINCIPAL AXIS = -10.8
P4S2
P4S3
MAY 25,1982
FEB
PRINCIPAL AXIS =
P4S3
P4S3
MAY.
PRINCIPAL AXIS = -18.3
P4S3
FEB
2,1982
PRINCIPAL AXIS =
8.9
0.4
1200
1200
SAMPLING INTERVAL = 360 MINUTES
STATION
P4S3
MIN
START TIME *(GMT)
MAY 25,1982
PRINCIPAL AXIS =
0000
U
-8.8
V
T
-7.7
-7 . 7
9.0
MAX
5.2
29 . 7
10.7
MEAN
-1.7
7.6
9.6
STD
2.3
7.9
0.4
STOP TIME
SEP 11,1982
SEP 11,1982
SEP 11,1982
1200
1200
1200
P4S3 :
P4S2 -I
P4S1
P3S2 -
P3S1 -I
E
1981
IPA JUN
U
C
E
1PFL
U
1982
JUN
PURISIMA POINT
LE
+owwba1+
velocity
UCI. UEJ JE
jpJ
U
1983
JUN
W
67m
39m
69m
129m
P3S2 -
P4S1
P4S2 ..
P4S3 :
JAN
37m
P3S1 -I
1981
MAR
PURISIMA POINT
FEB
\w1u11A111/\NINI(,'l
\1
velocity
APR
,AA\\bal11dA19UNG11AwU'
MAY
fF-
-20
P4S3 :
P4S2
P4S1 :
P3S2 -I
P3S1 :
APR
124m
64m
1
,y
\A,
1981
JUN
JUL
\i//i1 e,aur,1
PURISIMA POINT velocity
MAY
A\11,.XA1j.j,,,jeAJ1
,
34m11
69m
39m
AUG
'
--20 E
0
20
I
NYP
I
I
I
i rp/m/1r
i
I
I
I
I
IM-
030
11IR
1
I
I
AON
44!30I A
I
"v.\\
11pr/ir" 11 qp\\xtlrylplimwj\
I
'i
'-I
100
1861
'
1
I
'
'
fir'.
'
i
y/j jr
',II ",m
d3S
s1w.,1\\W\`
irrip1qptjj
'
INIOd VWISIei ld
I
lp\\\,,/I
,, j jqt/ r - - ^IlnV'
'
- £Std
0(ld
n-r- W 9 2 ti
- ZSU
: LSibd
ZStd
W OIL
W9L
irv,...
`'I ll/ ni'",rirwIYt'....,,I..,I,I,+,,,,,,,-,r,n''u,P,_.Y,,r"
W0j E LSCd
E
:
P4S3 -
P4S2 :
P4S1 :
P3S2
P3S1
!qP
1411AIIU,
y
w.Xa1u/a ,,,,.pa
Vim.
JAN
1982
MAR
PURISIMA POINT
FEB
velocity
APR
MAY
ai1,IuAllrr.11AI11iUnIiaIu,lllrw-r`didacaUIma,T,.a.allialll,It
,t fit.
iur
132m
Ilr
.(Alllllilli,l\u\11111
"
71 m
38m1,1
68m
38m
agAIL,
-20 E
0
20
:
42m
40m
P4S3 -,'
MAY
139m
P4S2 : 72m
P4S1
P3S1
W11,
xiA
JUN
VA
1982
JUL
AUG
1III&6,61%
velocity
L All
ime&-WIIJI11a11IIuMr,,
AI
PURISIMA POINT
,,,.11/,.., .
11au
Ali
SEP
P4S3
P4S2
P4S1
P3S2
P3S1
JAN
129m
69m
39m
67m
37m
11
1981
MAR
1
91
4- -11-11
APR
PURISIMA POINT U velocity
FEB
4.
I
MAY
E
E
P4S3
P4S2
P4S1
P3S2
P3S1
JAN
1981
MAR
APR
PURISIMA POINT V velocity
FEB
MAY
P4S3
P4S2
P4S1
P3S2
P3S1
APR
124m
64m
34m
69m
MAY
1981
JUN
JUL
PURISIMA POINT U velocity
d-
AUG
H
f
4
H
H
H
APR
1981
JUN
JUL
PURISIMA POINT V velocity
MAY
AUG
P4S3
P4S2
P4S1
P3S2
P3S1
AUG
136m
76m
46m
70m
40m
SEP
NOV
PURISIMA POINT U velocity
1981
OCT
DEC
JAN
AUG
if
SEP
I- IVI
NOV
PURISIMA POINT V velocity
1981
OCT
Lb dACi
DEC
JAN
P4S3
P4S2
P4S1
P3S2
P3S1
JAN
132m
71m
'381m'
68m
38m
I
1982
MAR
APR
PURISISMA POINT U velocity
FEB
MAY
E
P4S3
P4S2
P4S1
P3S2
P3S1
JAN
FIiI
132m
71m
38m
I
1982
MAR
I
APR
I
I
MAY
I-I--I---I----I-I
oil 1111i
PURISISMA POINT V velocity
FEB
V
,w,
Hili will
lVj_-flVlVVVV-V fill
r-
P4S3
P4S2
P4S1
P3S1
MAY
139m
72m
1982
JUL
AUG
I
PURISISMA POINT U velocity
JUN
A 'AVos,
-T %V
SEP
P4S3
P4S2
P4S1
P3S1
a
i
MAY
139m
+
42m
40m
1
1
j
JUN
I
1982
JUL
fc:ao
AUG
I
.1
A
a-A,,L
PURISISMA POINT V velocity
I{I}
:4 11
aD,
aw4A
I
SEP
A
I
I
C
E
P4S3
P4S2
P4S1
P3S2
P351
I
1
II
JAN
1
JAN
1
FEB
1
1
1
1
I
MAR
I
I
1981
I
I
lI
I
i
APR
I
I
I
I
I
I
l
I
I
II
I
FEB
I
I
I
I
I
I
I
1981
MAR
I
I
iI
11
APR
1
I
I
I
I
I
PURISIMA POINT DEEP Temperature
I
I
l
MAY
I
MAY
PURISIMA POINT SHALLOW Temperature
37m,67m
I
11
I
39m,69m,129m
I
I
I
i
I
1
I
1
13.0
8.0
9.0
10.0
11.0
-- 12.0
.
F- 14.0
9.0
10.0
11.0
12.0
- 14.0
- 13.0
P4S3
P4S2
P4S1
i
APR
I
I
I
I
L
APR
i
MAY
I
I
1
11
I
I
1981
JUN
LI
I
I
i
1
JUL
I
I
J
11
I
I
MAY
1981
JUN
JUL
PURISIMA POINT DEEP Temperature
-
I
PURISIMA POINT SHALLOW Temperature
I
34m, 64m,124m
I
AUG
AUG
I
1
I
11.5
8.5
9.5
-- 10.5
-
12.5
13.5
I
I
AUG
AUG
11
,I
1981
OCT
NOV
DEC
1
SEP
1
1
1
I
1
OCT
1
1
1981
,
1
II
1
1
NOV
1
a
I
I
I
I
a
DEC
I
I
PURISIMA POINT DEEP Temperature
1
1
PURISIMA POINT SHALLOW Temperature
SEP
11
1
JAN
1!
JAN
1
1
1
8.5
9.5
P4S3
P4S2
P4S1
P3S2
P3S1
D
r
I
JAN
I
JAN
I
38m.68m
1._1_._1L 1
11
FEB
J- 1
I
I
AI
I
I
MAR
1982
APR
1
MAY
I
FEB
I
MAR
I
I
I
1982
I
APR
MAY
PURISIMA POINT DEEP Temperature
I
PURISIMA POINT SHALLOW Temperature
I
JUN
JUN
- 11.0
- 13.0
I- 12.0
9.0
10.0
1- 12.0
1- 11.0
!- 13.0
P3S2
P3S1
MAY
MAY
1982
JUL
AUG
I
1982
JUL
AUG
PURISIMA POINT DEEP Temperature
JUN
PURISIMA POINT SHALLOW Temperature
JUN
SEP
SEP
I-
8.5
8.5
9.5
10.5
11.5
12.5
F- 13.5
CAPITAN AND HERMAN
ao
20
90
130
2p0
R3
50
90
PT. CON.......
120°30'
...:.
-TION
50
-
200
5
500
km
10
15
SOUNDINGS IN METERS
0
CFTq
90
Capitan
(R3, N3)
Herman
zoo
N3
:..
0
34° 30'
7-4
SAMPLING INTERVAL = 60 MINUTES
STATION
R3S1
START TIME -(GMT)
MAY 24,1982
2300
MIN
N3S1
MAY 24,1982
MAY 25,1982
2300
0300
MAY 25,1982
0400
STD
STOP TIME
-33.3
T
27.4
32.8
15.8
22.4
10.2
0.9
SEP 12,1982
SEP 12,1982
SEP 12,1982
1400
1400
1400
U
-82.2
-37.9
T
9.2
21.8
20.8
12.4
-27.2
V
10.2
21.3
8.3
0.6
SEP 12,1982
SEP 12,1982
SEP 12,1982
1400
1400
1400
U
-58.2
-18.3
9.9
13.1
25.3
16.5
-19.4
12.4
5.8
11.6
6.0
1.1
SEP 12,1982
SEP 12,1982
SEP 12,1982
1700
1700
1700
-48.9
-15.2
9.3
15.9
16.9
13.5
-14.4
11.4
4.7
0.8
SEP 12,1982
SEP 12,1982
SEP 12,1982
1800
1800
1800
V
T
N3S2
MEAN
-85.2
-31.6
9.4
U
V
R3S2
MAX
U
V
T
1.0
10.9
-1.5
3.6
10.6
NORTH km
500 -AUG 3,1982 1400 - AUG 6,1982 2200
EAST km
-3500
-3000
-2500
-2000
-1000
-1500
-500
500
-500 1-
V Component
(NORTH)
U Component
(EAST)
R3S1
MAY 24,1982 2300
-
SEP 12,1982
1400
NORTH km
500 --r-
EAST km
-500
-3000
500
-500
V Component
(NORTH)
U Component
(EAST)
R3S2
MAY 24,1982 2300
-
SEP 12,1982
1400
R3S2
R3S1
R3S2
R3S1
JUL
}i----}--- I
I
AUG
MAY
U velocity
1982
HERMAN
F
F; 4
SEP
JUN
-20
0
20
R3S2
R3S1
R3S2
R3S1
73m
I
JUL
APR
HERMAN V velocity
1982
AUG
1982
MAY
73m
43m
IAM
Y. Yi511117;1!"!
SEP
JUN
-20
20
R3S2
R3S1
R3S2
R3S1
L- I
I
1
JUL
1
43m,73m
APR
I
I
I
I
I
1
I
I
I
1982
AUG
r-- T --l
1982
MAY
I
I
I
I
i
I I
I
I I
I
I
I
HERMAN SHALLOW Temperature
I
43m,73m
I
I
SEP
JUN
I
I
I
I
8.5
12.5
13.5
11.0
9.0
- 10.0
r--
- 12.0
- 13.0
14.0
15.0
'r- 16.0
.-
7-11
NORTH km
500 --
JUL 20,1982 0200 AUG 5,1982 0500
'
-' EAST km
-2000
-1500
-500
-1000
500
-500
V Component
(NORTH)
U Component
(EAST)
N3S1
MAY 25,1982 0300
-
SEP 12,1982
1700
V Component
(NORTH)
U Component
(EAST)
N3S2
MAY 25,1982 0400
-
SEP 12,1982 1800
N3S2
N3S1
N3S2
N3S1
r- R
35m
II
CAPITAN
U velocity
1982
AU G
N3S2
N3S1
N3S2
N3S1
65m
35m
JUL
APR
CAPITAN V velocity
1982
AUG
1982
MAY
35m
n., .Atui""wW
SEP
JUN
-20
0
20
E
:1
N3S2
N3S2
N3S1
=
N3S1
I
APR
I
JUL
-r-
35m,65m
I
I
I
I
I
I
35m,65m
I
I
I
1982
AUG
I
1982
MAY
I
I
I
II
I
CAPITAN SHALLOW Temperature
I
I
I
SEP
I
I
I
I
9.0
10.0
11.0
12.0
13.0
14.0
15.0
16.0
17.0
13.5
SAMPLING INTERVAL = 360 MINUTES
STATION
START TIME -(GMT)
MAY 26,1982
MIN
0000
U
PRINCIPAL AXIS =
86.9
V
T
MAY 26,1982
0000
U
PRINCIPAL AXIS =
86.2
V
T
MAY 26,1982
0600
U
R3S1
R3S2
N3S1
V
PRINCIPAL AXIS = -75.6
MAY 26,1982
T
0600
U
PRINCIPAL AXIS = -77.6
V
T
N3S2
-79.2
-13.8
9.8
-72.7
-19.2
9.4
-54.8
-8 . 8
10.0
-40.6
-7 . 2
9.5
MAX
6.1
24.0
MEAN
-32.9
14.1
0.9
10.8
STD
STOP TIME
20.0
7.2
0.8
SEP 11,1982
SEP 11,1982
SEP 11,1982
1800
1800
1800
SEP 11,1982
SEP 11,1982
SEP 11,1982
1800
1800
1800
1800
1800
1800
3.6
-26.9
11.1
11.8
-1.5
10.2
18.5
5.3
0.5
1.8
-19.7
12.0
SEP 11,1982
16 . 2
5.9
4. 7
SEP 11 , 1982
15.3
11.5
1.0
SEP 11,1982
11.1
-14.5
10.5
SEP 11,1982
11 . 0
3. 7
2 .9
SEP 11 , 1982
12.6
10.6
0.8
SEP 11,1982
1800
1800
1800
1981
HERMAN
velocity
1982
1983
EB APR JUN AUG OCT DEC FEB APR JUN AUG OCT DEC FEB APR JUN AUG OC
MAY
]3m
43m
JUN
velocity
1982
JUL
HERMAN
I
AUG
SEP
R3S2
R3S1
MAY
43m
1982
JUL
AUG
HERMAN U velocity
JUN
}
SEP
f
R3S2
R3S1
MAY
73m
43m
I
6
JUL
-1
1982
1
a
11
a *,%I
a ZY
AUG
HERMAN V velocity
JUN
.*, a
VJV
SEP
I
I
MAY
I
I
I
I
JUN
I
I
I
I
1
JUL
I
I
1982
I
I
JI
I
I
AUG
I
I
I
II
HERMAN SHALLOW Temperature
II
I
I
SEP
I
I
1
9.0
15.0
7-23
N3S2 E
N3S1 :
E
1981
JUN
U
JC4
E
U
C
E
velocity
1982
JUN
CAPITAN
E
E
1PF!
U
1983
JUN
bCT. LE
N3S2
N3S1
MAY
65m
35m
JUN
velocity
1982
JUL
JA11111141411% 1 L
I
CAPITAN
M11%.,"1111111AIIIIIA",
11
AUG
.illl
SEP
-ZO
20
N3S1
CAPITAN
U velocity
1982
JUL
N3S2
E
MAY
1982
JUL
AUG
CAPITAN V velocity
JUN
SEP
t
I
MAY
I
I
I
I
I
JUN
I
I
I
I
JUL
I1
1982
I
1'
1
1
AUG
1
1
1
11
CAPITAN SHALLOW Temperature
II
1
1
SEP
1
1
1
9.0
10.0
11.0
12.0
13.0
14.0
15.0
16.0
AA
APPENDIX
SAMPLING AND PROCESSING INFORMATION
A description of the instruments and the procedures used
in processing the data can be found in Pillsbury, et al. (1974)
and (1980).
The general calibration techniques for Aanderaa
current meters are discussed in Pillsbury et al. (1974).
The
calibration of the pressure transducers and improvements in
compass calibration are described in Pillsbury et al. (1980).
The temperature calibration procedure used for the instruments
in SuperCODE is described in a section below.
The Aanderaa current meters sampled speed, direction,
temperature and, in some cases, pressure at 30 minute intervals
during the main period of SuperCODE (February 1981 - September
1982).
The current meters installed in September 1982 and July
1983 off Coos Bay and Eureka used an hourly sampling interval.
The speed record from Aanderaa current meters is based on the
rotor count during the sampling interval and, hence, is the
average speed over the interval.
speed sensor is 1.5 cm
s-1.
The nominal threshold of the
In processing, a zero in the speed
sensor record is set equal to 0.8 cm s-1, i.e., half the
threshold.
The direction, temperature
and pressure are
A-4
'instantaneous'
measurements at the end of the sampling
The data are processed into engineering units and
the time assigned to each data record is the time (UT) at the
interval.
end of the sampling interval rounded to the minute.
The data taken at 30 minute intervals were converted to
low-passed (LP) data (houly values, half-power at 2.9 hours)
using the program LP30 (all processing programs are included at
the end of this section). These data were interpolated using
the program LPNTRP to give the data points on the hour (UT).
These LP data records were then used to form low-low-passed
(LLP) files (at 6 hourly intervals) with the program LLP which
low-pass filters (half-power at 46.6 hours) the hourly data to
remove the diurnal and shorter period tidal energy and any
inertial frequency energy.
The data taken at hourly intervals were
interpolated in forming the hourly
report.
not filtered or
series used
in this data
However, in forming the LLP files, the program LPNTRP
was used to interpolate the data to fall on the hour before
applying the program LLP.
CALIBRATION OF THE TEMPERATURE SENSORS
Laboratory calibrations of the current meter temperature
sensors are conducted by immersing several current meters
simultaneously in a bath of water, which is vigorously stirred,
and whose temperature is measured precisely.
thermistor (Model
SBE3-0115)
A Sea Bird
is used in the calibration. This
instrument has a guaranteed accuracy of ±0.01°C over a
six-month
10.003°C.
and is typically stable to better than
The Sea Bird thermistor is itself calibrated at
period,
least once per year using a Leeds-Northrup 8163Q3 platinum
thermometer and a Mueller resistance bridge.
In general, the Aanderaa current meters used in the
SuperCODE experiment were calibrated in the 0 to 20°C
temperature range with a calibration point made at every
degree. The data between 5 and 15°C were used for the final
SuperCODE calibrations. A file of bit number versus
temperature is created and from it the calibration
coefficients, a, b, and c, are calculated by least squares fit,
assuming the form T = a + bN +cN2 where N is the bit number
recorded by the Aanderaa current meters.
In general, each current meter is calibrated once between
each recovery and redeployment. Differences between T(N) at
different
times are a measure
temperature measurement.
of the accuracy of the
For the current meters used during
SuperCODE, these were < 0.05°C.
PROGRAM LP30
C**READS A 30-MINUTE AANDERAA RCM P FILE AND LOW-PASS FILTERS IT.
C**THE OUTPUT POINTS ARE 1 HOUR APART. THE FILTER IS A COSINE-LANCZOS
C**FILTER WITH 12+1+12 POINTS. WAVES WITH PERIODS LONGER THAN 3.6 HOURS
C**ARE PASSED UNATTENUATED AND WAVES WITH PERIODS SHORTER THAN 2 HOURS
HALF AMPLITUDE AT 0.38 CYCLES/HR AND HALF
C**ARE REMOVED ENTIRELY.
C**POWER AT 0.35 CYCLES/HR.
DIMENSION W(13), X(5,25), SUM(5), IBUF(11), BUF(9). FCTR(12,5),
X
ADDEND(12.5), IPRMA(12). IPRMB(12)
DATA IPRMA /6*1, 2*3, 4. 3*3/ IPRMB /2. 3, 4, 5, 3*4. 3, 2*4,
5. 4/ FCTR / 6*.1. 6*0.. 6*.1, 7*0., 7*.O1, 0.. 3*.01, 2*0.,
X
X
2*.1, .01. .001. .01, 0.. .01. 2*.1, .001. 3*0.. .001.
X
6*0., .001, 0.1 ADDEND /60*0./
X W /.380297. .291885, .102790, -.0395268, -.0623169.
X
-.0133348. .0229200, .0175362, -.00161050, -.00740411,
X
-.00235450. .000888719. .000378864/
ADDEND(4.5) = 20.0
ADDEND(6.4) = 20.0
ADDEND(11.5) = 20.0
ADDEND(12.4) = 20.0
SUMO = 0.0
SUMV = 0.0
CALL INFIL (1, 'U')
CALL OUTFIL (2, 'U')
NSKIP = TTYIN ('NUMBER OF LINES TO SKIP INITIALLY', 33)
NPTS = TTYIN ('NUMBER OF LINES TO READ', 23)
IOP = TTYIN ('OPTION'. 6)
10
IF (IOP LE. 0 OR. IOP GE. 13) GO TO 10
IPRMST = IPRMA(IOP)
IPRMND = IPRMB(IOP)
MND = IPRMND + 6
IF (NSKIP LE. 0) GO TO 18
00 16 I=1.NSKIP
READ (1)
16
C**READ THE FIRST 25 CYCLES.
00 30 J=1,25
18
READ (1)
20
(IBUF(M), M=1,MND)
ASSIGN 20 TO LIMBO
GO TO 200
DO 30 IPRM=IPRMST.IPRMND
M = IPRM + 6
30
X(IPRM,J) = ADDEND(IOP,IPRM) + FLOAT(IBUF(M))*FCTR(IOP,IPRM)
NOUT = 0
NCNTR = 13
C**GET THE DOT PRODUCT OF THE FILTER AND THE CURRENT CONTENTS OF X.
DO 100 IPRM=IPRMST,IPRMND
50
SUM(IPRM) = X(IPRM,13)*W(1)
JLO = 13
JHI = JLO
DO 100 I=2,13
JLO = JLO -1
A-7
JHI = JHI + 1
SUM(IPRM) = SUM(IPRM) + W(I)*(X(IPRM,JLO) + X(IPRM,JHI))
NOUT = NOUT + 1
C**ASSEMBLE THE OUTPUT LINE AND WRITE IT TO LUN 2.
J = 0
00 130 IPRM=IPRMST,IPRMND
J = J + 1
BUF(J) = SUM(IPRM)
IF (IPRM EQ. 1) GO TO 115
IF (IPRM EQ. 2) GO TO 120
GO TO 130
115
SUMO = SUMO + BUF(J)
BUF(J+2) = SUMO
GO TO 130
120
SUMV = SUMV + BUF(J)
J = J + 2
BUF(J) = SUMV
130
CONTINUE
WRITE (2) (BUF(M), £ 1,J), NOUT
NCNTR = NCNTR + 2
IF (NCNTR+12 GT. NPTS) GO TO 150
C**MAKE ROOM FOR 2 NEW POINTS IN THE X ARRAY, THEN GET THEM FROM LUN 1.
DO 135 J=1,23
DO 135 IPRM=IPRMST,IPRMND
135
X(IPRM,J) = X(IPRM,J+2)
DO 140 J=24,25
READ (1) (IBUF(M), M=1,MVD)
ASSIGN 138 TO LIMBO
GO TO 200
138
DO 140 IPRM=IPRMST,IPRt4
100
M = IPRM + 6
X(IPRM,J) = ADDEND(IOP,IPRM) + FLOAT(IBUF(M))'*FCTR(IOP,IPRM)
GO TO 50
150
WRITE (5, 160) NOUT
160
FORMAT ('OTHE OUTPUT FILE HAS ', 14,
LINES.'/)
CALL EXIT
C**IF PRESSURE IS PRESENT AND SUFFICIENTLY GREAT. ADJUST FCTR.
IF (IOP.NE.3 AND. IOP.NE.4 AND. IOP.NE.10 AND. IOP.NE.11)
200
X
GO TO LIMBO
FCTR(IOP,4) = 0.1
IF (IBUF(10) LT. 0) FCTR(IOP,4)
1.0
GO TO LIMBO
140
'
END
A-8
PROGRAM LPNTRP
C***READS AN UNDATED LP OR LLP FILE AND INTERPOLATES TO PRODUCE AN
C***UNDATED FILE WHOSE POINTS LIE AT INTERMEDIATE POSITIONS SPECIFIED
C***THROUGH AN INPUT "FRACTION", WHICH DETERMINES THE FRACTIONAL
C***DISTANCE, MEASURED FROM POINT 1 TO POINT 2 OF THE INPUT SERIES, AT
C***WHICH THE FIRST POINT OF THE OUTPUT FILE IS TO LIE.
DIMENSION X(4,7), Y(7), Z(7)
IFLAG = 1
Y(3) = 0.0
Y(4) = 0.0
CALL INFIL (1. 'U')
CALL OUTFIL (2, Jul)
IOP = TTYIN ('FILTERING OPTION USED', 21)
500
IF (IOP LT. 1 OR. IOP GT. 12) GO TO 500
GO TO (1, 2, 3, 4, 3, 3. 7. 8, 8, 7, 11, 8) IOP
NVAR = 4
1
GO TO 50
NVAR = 5
2
GO TO 50
NVAR = 6
3
GO TO 50
NVAR = 7
4
GO TO 50
NVAR = 2
7
GO TO 50
NVAR = 1
8
GO TO 50
NVAR = 3
11
FRAC = TTYIN ('FRACTION', 8)
50
A = FRAC + FLOAT(IFLAG - 1)
55
AM1 =A- 1.0
AM2 = A - 2.0
AM3=A- 3.0
Cl = - AMi*AM2*AM3/6.0
C2 = A*AM2*AM3/2.0
C3
- A*AM1*AM3/2.0
C4 = A*AM1*AM2/6.0
GO TO (57, 110, 110, 110) IFLAG
C***READ THE FIRST 4 LINES.
DO 60 I=1,4
57
READ (1) (X(I,J), J=1.NVAR)
60
C***CALCULATE AN OUTPUT LINE BY LAGRANGIAN INTERPOLATION (SEE P. 329
C***OF 'MATHEMATICAL METHODS OF PHYSICS' BY MATHEWS WALKER).
IF (NVAR LT. 4) GO TO 170
110
DO 120 J=1,2
Y(J) = C1*X(1,J) + C2*X(2,J) + C3*X(3,J) + C4*X(4,J)
120
Y(3) = Y(3) + Y(1)
Y(4) = Y(4) + Y(2)
IF (NVAR EO. 4) GO TO 200
J1 = 5
GO TO 180
170
180
J1 = 1
00 190 J=JI,NVAR
Y(J) = C1*X(1,J) + C2*X(2.J) + C3*X(3,J) + C4*X(4,J)
WRITE (2) (Y(J), J=1,NVAR)
GO TO (300. 350, 400, 205) IFLAG
C***GET A NEW INPUT LINE.
READ (1, END=370) (Z(J), J=1.NVAR)
205
DO 210 J=1,NVAR
DO 208 I=1,3
208
X(I,J) = X(I+1.J)
X(4,J) = Z(J)
210
GO TO 110
C***CHANGE IFLAG, WHICH CONTROLS THE LOCATION OF THE INTERPOLATION
C***POINT.
300
IFLAG = 2
GO TO 55
350
IFLAG = 4
GO TO 205
370
IFLAG = 3
GO TO 55
400
CALL EXIT
190
200
END
A-10
PROGRAM LLP
C**LOW-LOW-PASS FILTERS AANDERAA LOW-PASS (HOURLY) DATA FILES. THE
C**FILTER IS A 60+1+60 POINT COSINE-LANCZOS FILTER WITH HALF AMPLITUDE
C**AT 0.025 CYCLES/HR AND HALF POWER AT 0.02146 CYCLES/HR. THE FIRST 6
C**AND LAST 6 POINTS OF THE OUTPUT SERIES ARE PRODUCED WITH A VARIABLEC**LENGTH TRUNCATED VERSION OF THE FILTER, SO THAT ONLY 24 HRS ARE LOST
C**AT EITHER END OF THE INPUT SERIES. OUTPUT POINTS ARE 6 HRS APART.
C**IOP HAS THE SAME MEANING HERE AS WITH THE LP PROGRAMS.
DIMENSION W(61), X(5,121). SUM(5), ABUF(9), BBUF(9), IPRMA(12),
X
IPRMB(12)
DATA IPRMA /12*1/ IPRMB /2. 3, 4, 5, 2*4, 2, 2*1, 2, 3, 4/
DATA W /.50184E-1. .499447E-1. .492317E-1, .480592E-1. .464503E-1,
X
.444366E-1, .420574E-1. .393586E-1. .363914E-1, .332112E-1,
X
.29876E-1, .264454E-1. .229786E-1. .195334E-1, .161646E-1,
X
.12923E-1, .985452E-2, .699864E-2, .438837E-2. .204941E-2,
X
.0. -.17492E-2. -.319491E-2. -.434092E-2, -.519754E-2,
X
-.57809E-2, -.611216E-2. -.621655E-2, -.612246E-2, -.586035E-2.
X
-.546179E-2. -.495844E-2, -.438118E-2, -.375924E-2, -.311952E-2,
X
-.248599E-2. -.18792E-2. -.131607E-2, -.80964E-3, -.369122E-3,
X
.0. .295727E-3. .519196E-3. .67425E-3, .766951E-3, .80505E-3.
X
.797444E-3. .753646E-3. .683272E-3, .595586E-3. .499108E-3,
X
.401287E-3. .308265E-3. .224728E-3. .153843E-3, .972726E-4.
.552832E-4. .269017E-4. .101382E-4, .224482E-5, .0/
X
NOUTND = 6
KFLAG = 0
SUMU = 0.0
10
SUNK = 0.0
CALL INFIL (1. 'U')
CALL OUTFIL (2, 'U')
NSKIP = TTYIN ('NUMBER OF LINES TO SKIP INITIALLY', 33)
NPTS = TTYIN ('NUMBER OF LINES TO READ', 23)
IOP = TTYIN ('OPTION', 6)
IF (IOP LE. 0 OR. IOP GE. 13) GO TO 10
IPRMST = IPRMA(IOP)
IPRMND = IPRMB(IOP)
MND = IPRMND + 2
IF (IOP GT. 1 AND. IOP LT. 7) MND = IPRMND + 4
IF (NSKIP LE. 0) GO TO 16
00 14 I=1,NSKIP
READ (1)
14
C**READ THE FIRST 121 CYCLES.
16
DO 20 J=1,121
(ABUF(M). M=1,MND)
DO 20 IPRM IPRMST,IPRMD
READ (1)
M = IPRM + 2
IF (IPRM
GT. 2
AND. IOP
GT. 1
AND. IOP
LT. 7)
X M= IPRM+4
20
X(IPRM,J) = ABUF(M)
NOUT = 0
NCNTR = 25
GO TO 200
C**GET THE DOT PRODUCT OF THE FILTER AND THE CURRENT CONTENTS OF X.
DO 100 IPRM=IPRMST,IPRMNO
50
SUM(IPRM) = X(IPRM,61)*W(1)
JLO = 61
JHI = JLO
DO 100 I=2,61
JLO = JLO -1
JHI = JHI + 1
SUM(IPRM) = SUM(IPRM) + W(I)*(X(IPRM,JHO) + X(IPRM,JHI))
NOUT = NOUT + 1
C**ASSEMBLE THE OUTPUT LINE AND WRITE IT TO LUN 2.
J = 0
100
105
00 130 IPRM=IPRMST,IPRMND
115
120
J = J + 1
BBUF(J) = SUM(IPRM)
IF (IPRM .E0. 1 AND. IOP
IF (IPRM EQ. 2 AND. IOP
GO TO 130
SUMO = SUMO + BBUF(J)
BBUF(J+2) = SUMU
GO TO 130
SUMV = SUMV + BBUF(J)
J = J + 2
LT. 7) GO TO 115
LT. 7) GO TO 120
BBUF(J) = SUMV
130
CONTINUE
MITE
(2)
(BBUF(M), M=1,J), NOUT
NCNTR = NCNTR + 6
IF (NOUT + KFLAG LE. NOUTND) GO TO 200
IF (KFLAG GT. 0) GO TO 155
IF (NCNTR + 60 GT. NPTS) GO TO 150
C**MAKE ROOM FOR 6 NEW POINTS IN THE X ARRAY, THEN GET THEM FROM LUN 1.
DO 135 J=1,115
DO 135 IPRM=IPRMST,IPRMNO
X(IPRM,J) = X(IPRM,J+6)
135
DO 140 J=116.121
READ (1) (ABUF(M), M=1,MND)
00 140 IPRM=IPRMST,IPRMND
M = IPRM + 2
IF (IPRM
GT. 2
AND. IOP
GT. 1
AND. IOP
LT. 7)
X M= IPRM+4
140
X(IPRM,J) = ABUF(M)
GO TO 50
NOUT + 6
NCNTR = 67
KFLAG = 1
GO TO 300
150
NOUTND =
155
160
WRITE (5, 160) NOUT
FORMAT ('OTHE OUTPUT FILE HAS '.
141
' LINES.'/)
CALL EXIT
C**THIS SECTION CALCULATES THE FIRST 6 POINTS OF THE OUTPUT SERIES. THE
C**FILTER USED IS A TRUNCATED VERSION OF THE 60+1+60 POINT FILTER, AND
C**ITS LENGTH INCREASES WITH EACH SUCCEEDING POINT.
IF (KFLAG GT. 0) GO TO 300
200
DO 220 IPRM=IPRMST,IPRMND
SUM(IPRM) = X(IPRM.NCNTR)*W(1)
A-12
JLO = NCNTR
JHI = NCNTR
DO 220 I=2.NCNTR
JLO = JLO - 1
JHI = JHI + 1
SUM(IPRM) = SUM(IPRM) + (X(IPRM.JLO) + X(IPRM,JHI))'*W(I)
220
LEND = NCNTR
SUMWTS = W(1)
225
DO 230 I=2,IEND
SUM-TS = SUNWTS + W(I)*2.0
230
DO 240 IPRM=IPRMST,IPRMND
SUM(IPRM) = SUM(IPRM)/SUMWTS
240
GO TO 105
C**THIS SECTION PROVIDES THE LAST 6 POINTS OF THE OUTPUT SERIES BY
C**A PROCESS INVERSE TO THE CALCULATION OF THE FIRST 6.
DO 330 IPRM=IPRMST.IPRMND
300
SUM(IPRM) = X(IPRM,NCNTR)*W(1)
JLO = NCNTR
JHI = NCNTR
LEND = 121 - NCNTR + 1
DO 330 I=2,IEND
JLO = JLO - 1
JHI = JHI + 1
330
SUM(IPRM) = SUMM(IPRM) + (X(IPRM.JLO) + X(IPRM.JHI))*W(I)
G0 TO 225
END