OBSERVATIONS FROM MOORED CURRENT METERS IN SAN FRANCISCO BAY, 1978 Compiled and Edited by Jeffrey W. Gartner and Ralph T. Cheng U. S. GEOLOGICAL SURVEY Open-File Report 82-153 Prepared as part of a continuing study of the San Francisco Bay estuary
OBSERVATIONS FROM MOORED CURRENT METERS IN
SAN FRANCISCO BAY, 1978
Compiled and Edited by Jeffrey W. Gartner
and Ralph T. Cheng
U. S. GEOLOGICAL SURVEY
Open-File Report 82-153
Prepared as part of a continuing study of the
San Francisco Bay estuary
UNITED STATES DEPARTMENT OF THE INTERIOR
James 6. Watt, Secretary
GEOLOGICAL SURVEY
Dallas L. Feck, Director
OPEN-FILE REPORT
For additional information write to:
Regional Hydrologist Water Resources Division U.S. Geological Survey 345 Middlefield Road Menlo Park, CA 94025
CONTENTS
Page
Abstract. ......................... 1
Introduction. ....................... 2
Methods .......................... 3
Data. ........................... 5
References. ........................ 10
TABLES
Table 1, Summary of current-meter deployments, 1978. . . . 6
FIGURES
Figure 1, San Francisco Bay current-meter stations, 1978 . 4
Figure 2, Salinity plots from a deployment with
degraded conductivity .............. 8
APPENDIX
Appendix A, Time-series plots of data ........... H
Appendix B, Speed and direction histograms. ........ 60
Appendix C, Data status summary. .............. 86
OBSERVATIONS FROM MOORED CURRENT METERS IN
SAN FRANCISCO BAY, 1978
Compiled and Edited by Jeffrey W. Gartner
and Ralph T. Cheng
ABSTRACT
Current-meter data collected at eight stations in the San
Francisco Bay estuarine system between August 1978 and December
1978 are compiled in this report. The measurements include
current speed and direction, and water temperature and salinity
(computed from conductivity and temperature). Data are presented
in graphical format with each parameter plotted separately.
-I-
INTRODUCTION
The deployment of current meters is one segment of an extensive
interdisciplinary study undertaken by the U.S. Geological Survey to
better understand the interactive physical, chemical, and biological
processes which affect the San Francisco Bay estuarine system. Broad
goals of this study are to understand the processes and rates by which
water, solutes, sediments, and organisms interact; to quantify effects
of river inflow, winds, and tides; and to develop and verify various
numerical and conceptual models of these relations (Cheng and Conomos,
1980).
To examine hydrographic properties of San Francisco Bay, in situ-
recording current-meter stations have been established throughout the
Bay system. Current meters employed permit recording of current speed,
direction, temperature, and conductivity at 2 minute intervals for
deployment periods of up to 30-40 days. This report presents, chron
ologically and station by station, all current-meter da£a collected
during 1978. A brief summary of equipment and methods is given below.
A more complete description of equipment, deployment, recovery, mainten
ance, and data processing procedures is given in Cheng and Gartner (1980)
-2-
METHODS
EQUIPMENT; The current meters used in the program are ENDECO-17^-
digital-recording current meters. The ENDECO-174 is an axial-flow,
ducted-impeller current meter which records data on a magnetic tape
cartridge. Data can be recorded for up to 40 days when the data-recording
interval is selected to be 2 minutes. Accuracy specifications for
ENDECO-174 current meters provided by the manufacturer (Environmental
Devices Corporation, Marion, Mass.) are as follows: speed,-3.0 percent
of full scale (257 cm/a) above the threshold (2.6 cm/s); direction,
-7.2 ; temperature, -0.2 C; and conductivity, -0.55 mmho/cm.
POSITION; During early deployments, all station positions (Fig. 1)
were determined by radar ranges and bearings or visual references.
Later positions were determined by horizontal sextant fixes. Fixes
were determined to the nearest second of arc (-31m).
TIME; In this report all reference times have been converted to
Pacific Standard Time and Julian days.
RECORDED PARAMETERS; Current speed is determined by measuring the
displacement of an encoder-disc driven by an impeller through a magnetic
coupler and a 500:1 reduction gear. Current direction (current meter
heading) is determined from the output of a damped magnetic compass.
Temperature is determined by a thermilinear thermistor and conductivity
by an induction type electrodeless-conductivity probe. Salinity is
computed from temperature and conductivity data based upon the modified
Cox relationship (D. W. Pritchard, personal communication, 1978).
Mention of a commercial company or product in this report does notconstitute an endorsement by the authors or the U.S. Geological Survey.
-3-
122*30' 122*00'
38*00'-
37*30' -
SOUTH SAM FRANCISCO §A Y
FIGURE 1. Map of study region and locations of current-meter
stations (1978)
-4-
DATA
Current-meter data are presented In Appendix A with each parameter
plotted against time for the entire deployment period. The temperature
and salinity values in the graphs were block averaged over 30 minutes
(15 samples) and speed and direction were vector averaged over the same
time period. If either speed or direction data became unusable at some
point in the record and the time series of these parameters are of different
lengths, the arithmetic averages of the "good" data have been plotted
rather than vector averages. This is the case if a compass or speed
encoder failed to perform correctly. In addition to the time-series
plots, histograms of speed and direction (Appendix B) are included to
show the parameter distributions for the deployment period based on the
original 2 minute (nonaveraged) data. Plot legends give station position,
meter height, and tape number. Table 1, which summarizes station locations,
deployment and recovery times for all data included in this report can
be used as a cross-reference to the current-meter stations by referring
to deployment tape number.
In several records the temperature data were in error due to an
electronic problem in the current meters. In these cases conductivity
is plotted rather than salinity because salinity could not be computed
without temperature data. The minimum conductivity which can be
measured by the ENDECO-174 current meter is approximately 5 mmho/cm
(approximately 3 /oo salinity at 20 C). Therefore, during several
deployments, the minimum conductivities and salinities were below the
threshold of the sensor and are not known. Accuracy of conductivity
data may also be affected by two external conditions. These are the
-5-
TAB
LE
1.
Sum
mar
y o
f cu
rren
t-m
ete
r d
ep
loy
me
nts
, 19
78
DE
PL
OY
ME
NT
S
BE
TW
EE
N
1 7
8
AN
D
36
9
7B
CO
MP
LE
TE
D
DE
PL
OY
ME
NT
S
STATION
NUMBER OS
1ea
iOS1
031
08 i
082
082
OS2
082
082
082
083
083
084
084
089
085
GS3
086
086
086
087
087
ess * Date
**Ha
ter
LATITUDE
DEO
38.
38.
38.
38.
38.
38.
38.
38.
38.
38
38.
38.
38.
38.
38.
37.
37.
37.
37.
37.
37.
37.
37.
37.
in J
ulian
MIN
2.6
2. 6
2.6
2. 6
2. 6
2. 5
2. 3
2. 9
2. 9
2. 5
2. 9
9. 6
3. 6
9.8
9. 8
49. 4
49. 4
43. 4
46. 2
46. 2
46. 2
46. 2
46. 2
31. 2
Day
column d
epth
referenced
LONGITUDE
DEO
MIN
121
121
121
121
121
122
122
122
122
122
122
122
122
122
122
122
122
122
122
122
122
122
122
122
to
. 53.9
93. 9
93. 9
93. 9
93. 9
7. 9
7. 9
7. 9
7. 5
7. 9
7. 9
1. 1
1. 1
4.0
4. O
. 21.9
. 21.9
21. 9
. 21. 3
. 21. 3
. 21. 3
. 20. 0
. 20. 0
8. 0
Mean Lower
DEPLOYMENT
DATE*
214
214
214
255
255
214
214
214
255
255
255
250
230
2SO
25O
319
319
319
319
319
319
319
319
319
Low Water
7878
78
78
7878
78
78
78
78
78
78
7878
78 78
78
78
78
7878
78
78
78
RECOVERY
DATE
250
78
23O
78
250
78
286
78
286
78
249
78
249
78
249
78
286
78
286
78
286
78
286
78
286
78
286
78
286
78
343
78
345
78
343
78
345
78'
345
78
345
78
345
78
345
78
343
78
TAPE
NUMBER
OS001A1
OS001A2
08001A3
08001B2
GSOO1B3
GS002A1
OS002A2
OS002A3
OS002B1
GSOO2B2
OSO02B3
GS003A1
08003A2
08004A1
G8004A2
O80O5A1
OSOOSA2
O8OO3A3
OSOO6A1
GS006A2
OS006A3
GS007A1
G8007A2
OSO08A1
DEPTH**
POSITION
50
SO
SO
SO
50
SO
SO
SO
SO
SO
SO
25
29
23
23
40
4O
40
60
60
60
30
30
3O
PITTSBURO
PITTSBURG
PITTSBURO
PITTSBURO
PITTSBURO
BENECIA BR.
BENECIA BR.
BENECIA BR.
BENECIA BR.
BENECIA BR
. BENECIA BR
. RYER 18.
RYER 18.
RESERVE FL
T.
RESERVM FL
T.
POTRERO PT
. POTRERO PT
. POTRERO PT
. POTRERO PT
. POTRERO PT.
POTRERO PT
. NAS ALAMEDA
NAS ALAMEDA
DUMBARTON BR
.
amount of marine growth on the external sensor and the battery voltage
which is a function of the deployment length and water temperature.
Current-meter circuitry generates conductivity reference values applied
in data reduction which greatly eliminates the latter problem; however,
marine growth is not a simple problem to evaluate. As a check on data
validity, current-meter records were compared to existing data from
nearby water-sampling stations collected during research cruises (Alpine
and others, 1981a, b) as well as other current-meter records from the
same area. If data were incorrect for an entire tape (for example if
the electronic circuitry had failed} no record was plotted. However, if
data were correct for only a part of a deployment, the plot was termi
nated at the time of the last corresponding cruise sample where the
data were in agreement or at the point of obvious electronic failure
(see Fig. 2). If no suitable data existed in order to make this
determination, yet the data appeared to be erroneous, the time series
plot was terminated at the point of apparent error. This situation
might exist if the conductivity value at the end of one deployment
differed from that at the beginning of a subsequent deployment at the
same station.
The histograms in Appendix B give the statistical distributions of
speed and direction for each deployment. The histograms can also be
used to identify abnormal instrument performance. For example, in a
few cases an examination of the speed histograms revealed an additional
problem. Discontinuities in the data occured because a few binary
digits were never recorded. This was the result of a mechanical
problem in the encoder which prevented certain discrete speeds from
being recorded. However, this discrepency did not affect the general
-7-
36
30
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1
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yvvwwv/yvvvvwv^v<vi>v^i * m M
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1
m M
w
54 161 1BB 175 1B2 16
FIGURE 2. Salinity from a deployment with degraded conductivity. The
dots in the top plot show the corresponding water sample
obtained from a research cruise. The bottom plot is an
example of that time series plot truncated at the point
of the last cruise when the data were in agreement. The
same data screening procedure is used for all temperature
and conductivity data presented in this report.
-8-
features of the speed records when, they were averaged over a
30-minute period.
Editing of speed and direction readings are much more
difficult and there is no simple procedure that can be routinely
applied to these series. No attempt has been made to correct
erroneous speed and direction readings prior to the averaging and
plotting of the records unless a parameter was obviously unreliable,
The plotted data provide users with a visual record to examine for
possible "glitches". It is left for users to further edit the data
set if desired before the next phase of data analysis. All data
files (2 minute and 30 minute) are currently stored on computer
retrievable media.
Appendix C lists the status of measured parameters and any
applicable notes for all deployments.
-9-
REFERENCES
1. Alpine, A.E., Cloern, J.E., and Cole, B.E., I981a, Plankton
studies in San Francisco Bay. I. Chlorophyll distributions
and hydrographic properties of the San Francisco Bay Estuary,
July 1977 - December 1979: U.S. Geological Survey Open-File
Report 81-213, 150 p.
2. Alpine, A.E., Cloern, J.E., and Cole, B.E., 1981b, Plankton studies
in San Francisco Bay. II. Chlorophyll distributions and
hydrographic properties of the San Francisco Bay Estuary,
January 1980 - April 1981: U.S. Geological Survey Open-File
Report, in prep.
3. Cheng, R. T. and Conomos, T. J., 1980, Studies of San Francisco
Bay by the U.S. Geological Survey, Institute of
Environmental Sciences, Philadelphia, Perm., May 12-14,
1980, Proceedings, p. 299-303.
4. Cheng, R. T. and Gartner, J. W., 1980, Working notes on current
meter deployment, recovery, maintenance, and data
processing for San Francisco Bay: U.S. Geological Survey
Open-File Report 80-1297, 68 p.
-10-
APPENDIX A
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JULIAN DAY, 19
78248
255
CURRENT METER OBSERVATIONS C3
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PITTSBURG
38- 2-38N I21-53-58W
METER
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JULIAN DAY, 1978
CURRENT
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MINUTE AVERAGES)
PITTSBURG
38-
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24 FEET ABOVE BE
D. TAPE NUMBER
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160
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227
234
241
JULIAN DA
Y, 1978
CURRENT METER OBSERVATIONS C3
0 MINUTE AVERAGES)
PITTSBURG
38- 2-38N 121-53-58W
METER
5 FE
ET ABOVE BE
D. TAPE NUMBER GS001A3
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SENSOR.
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248
CURRENT METER OBSERVATIONS C3
0 MINUTE AVERAGES)
PITTSBURG .
38- 2-38N I2I-53-S8W
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5 FE
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CURRENT
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PITTSBURG
38-
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METER
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D. TA
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D
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, 1978
CURRENT METER OBSERVATIONS C3
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BENECIA BRIDGE
38- 2-27N 12
2- 7-30W
METER
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-85-
APPENDIX C
DEPLOYMENT TAPE STATUS
NOTES:1. ALL UTR COORDINATES ME IN ZONE 10.2. HLLH DEPTH AND METER DEPTH ME ACTUALLY A HEIGHT ABOVE Ttffi BED,3. HETER TYPES: E=ENDECO* A«AANDERAA»4* MOORING TYPES: T=TAUT, PsBOTTOH PLATFORR, R=RID-LBEL PLATFORH,5* PARAMETERS MEASURED:
1=SPEED, 2SDIRECHON» 3=TEHPERATW?Et 4=CONDUCTIVITY, 5:PRESSURE»6. DATA PROCESSING STEPS:
1--8-TRACK TAPE TRANSLATED2--DATA EDITED3-DATA TRANSLATED TO 2 KIN ENGINEERING UNITS 4=DATA AVERAGED 5=DATA PLOTTED
7. DATA QUALITY KEY: 1=HO DATA2-DATA ALHOST COMPLETELY UNUSABLE 3=SOME LONG HISSING OR ll^ELJABLE SECTION 4=SOME GLITCHES OR SHORT UNRELIABLE SECTIONS 5-EXCELLENT DATA
-86-
DEPLOYMENTS BETWEEN 1 78 AND 365 78
COMPLETED DEPLOYMENTS
LAT LON UTM STATION HLLU IMETERS AT MTR TAPE HTR HOR PARAtt- DEPLMT RECVRY MRS DEB H1N DE6 MIN NORTH EAST NUMBER DEPTH STA t TYPE DEP NUMBER f TYP ETERS DATE DATE DATA
38. 2.6 121* 53.9 211.0 596.7 8S1 50 E E E 43 6S001A1 39 T 12340 214 78 250 78 865
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 5 . QUALITY OF DATA FOR CONDUCTIVITY IS 5 . QUALITY OF DATA FOR DIRECTION IS 5QUALITY OF DATA FOR SPEED IS 5 , QUALITY OF DATA FOR PRESSURE IS 1 .COMMENTStMINIMUN CONDUCTIVITY THRESHOLD TOO HIGH
38. 2.6 121. 53.9 211.0 596.7 3S1 50 E E E 24 6S001A2 41 T 12340 214 78 250 78 865
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 5 . QUALITY OF DATA FOR CONDUCTIVITY IS 2 . QUALITY OF DATA FOR DIRECTION IS 5QUALITY OF DATA FOR SPEED IS 5 . QUALITY OF DATA FOR PRESSURE IS 1 .COMHENTSJCONDUCTIVITY CORRECTION UNSTABLECONDUCTIVITY BAD.
38. 2.6 121.53.9 211.0596.7 6S1 50 E E E 5 6S001A3 42 T 12340 21478 25078 865
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 5 . QUALITY OF DATA FOR CONDUCTIVITY IS 4 . QUALITY OF DATA FOR DIRECTION IS 4QUALITY OF DATA FOR SPEED IS 5 . QUALITY OF DATA FOR PRESSURE IS 1 .COMMENTStCOND CORfi DECREASING RAPIDLY AT TAPE ENDCOND. DEFECTIVE BEYOND DAY 246.86COW. BELOW THRESHOLD IN SPOTS
38. 2.6 121. 53.9 211.0 596.7 GS1 50 E E E 24 6S001B2 35 T 12340 255 78 286 78 743
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 1 . QUALITY OF DATA FOR CONDUCTIVITY IS 5 . QUALITY OF DATA FOR DIRECTION IS 4QUALITY OF DATA FOR SPEED IS 5 . QUALITY OF DATA FOR PRESSURE IS 1 .CONMENTSJTEHPERATURE DATA ARE BAD.COND BELOW THRESHOLD
38. 2.6 121. 53.9 211.0 596.7 6S1 50 E E E 5 6S001B3 42 T 12340 255 78 286 78 743
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 5 . QUALITY OF DATA FOR CONDUCTIVITY IS 5 . QUALITY OF DATA FOR DIRECTION IS 4QUALITY OF DATA FOR SPEED IS 5 . QUALITY OF DATA FOR PRESSURE IS 1 .
-87-
COMHENTSiCOND BELOW THRESHOLD
38* 2*5 122. 7,5 210*6 576*8 682 50 E E E 43 GS002A1 35 T 12340 214 78 249 78 849
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 3 . QUALITY OF DATA FOR CONDUCTIVITY IS 5 * QUALITY OF DATA FOR DIRECTION IS 4QUALITY OF DATA FOR SPEED IS 5 . QUALITY OF DATA FOR PRESSURE IS 1 *CQHNENTSJTEHPERATURE VALUES BAD BEYOND JULIAN DAY 233
38* 2*5 122. 7*5 210*6 576*8 6S2 50 E E E 24 SS002A2 38 T 12340 214 78 249 78 849
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEHPERATURE IS 1 * QUALITY OF DATA FOR CONDUCTIVITY IS 5 * QUALITY OF DATA FOR DIRECTION IS 5QUALITY OF DATA FOR SPEED IS 3 * QUALITY OF DATA FOR PRESSURE IS 1 *COHHENTS:TEHPERATURE VALUES INCORRECT*SPEED ENCODER DROPPING BITS LAST HALF OF TAPE*
38* 2.5 122* 7*5 210*6 576*8 6S2 50 E E E 5 6S002A3 37 T 12340 214 78 249 78 849
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEHPERATURE IS 2 » QUALITY OF DATA FOR CONDUCTIVITY IS 5 * QUALITY OF DATA FOR DIRECTION IS 5QUALITY OF DATA FOR SPEED IS 5 * QUALITY OF DATA FOR PRESSURE IS 1 .CQHHENTSiTEHPERATURE BAD BEYOND DAY 10 OF RECORD*
38* 2*5 122* 7*5 210.6576*8 6S2 50 E E E 43 6S002B1 39 T 12340 25578 28678 754
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 5 * QUALITY OF DATA FOR CONDUCTIVITY IS 5 * QUALITY OF DATA FOR DIRECTION IS 5QUALITY OF DATA FOR SPEED IS 5 * QUALITY OF DATA FOR PRESSURE IS 1 *COHHENTSJSEVERAL HOURS OF DRAGGING TO RECOVER ARRAY
38* 2*5 122* 7*5 210*6 576.8 6S2 50 E E E 24 6S002B2 38 T 12340 255 78 286 78 754
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEHPERATURE IS 1 * QUALITY OF DATA FOR CONDUCTIVITY IS 5 * QUALITY OF DATA FOR DIRECTION IS 5QUALITY OF DATA FOR SPEED IS 4 * QUALITY OF DATA FOR PRESSURE IS 1 *CQHMENTSJSPEED ENCODER DROPPING BITS AT TAPE END*TEHPERATURE DATA BAD
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38. 2.5 122. 7.5 210.6 576.8 6S2 50 E E E 5 6S002B3 31 T 12340 255 78 286 78 754
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 4 . QUALITY OF DATA FOR CONDUCTIVITY IS 4 . QUALITY OF DATA FOR DIRECTION IS 4QUALITY OF DATA FOR SPEED IS 4 . QUALITY OF DATA FOR PRESSURE IS 1 .COMNENTSJ51 HOURS OF DATA MISSING AFTER HOUR 32.
38. 5.6 122. 1.1 216.4586.1 6S3 25 E E 18 6S003A1 36 T 12340 250 78 286 78 868
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 5 . QUALITY OF DATA FOR CONDUCTIVITY IS 5 . QUALITY OF DATA FOR DIRECTION IS 5QUALITY OF DATA FOR SPEED IS 5 . QUALITY OF DATA FOR PRESSURE IS 1 .COHHENTS:CONSIDERABLE MARINE GROWTH ALL COMPONENTSCOND. BELOW THRESHOLD IN SPOTS
38. 5.6 122. 1.1 216.4586.1 GS3 25 E E 5 6S003A2 33 T 12340 250 78 286 78 868
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 5 . QUALITY OF DATA FOR CONDUCTIVITY IS 5 . QUALITY OF DATA FOR DIRECTION IS 4QUALITY OF DATA FOR SPEED IS 5 . QUALITY OF DATA FOR PRESSURE IS 1 .COHMENTSJCOND BELOH THRESHOLD IN SPOTS
38. 5.8 122. 4.0 216.7 581.8 6S4 25 E E 18 6S004A1 34 T 12340 250 78 286 78 870
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 5 . QUALITY OF DATA FOR CONDUCTIVITY IS 5 . QUALITY OF DATA FOR DIRECTION IS 5QUALITY OF DATA FOR SPEED IS 5 . QUALITY OF DATA FOR PRESSURE IS 1 .COMMENTS:ARRAY RECOVERED I.SMI WEST OF LOGGED DEPLOYMENTSITE AT MK6 RATHER THAN HK8
38. 5.8 122. 4.0 216.7 581.8 6S4 25 E E 5 GS004A2 40 T 12340 250 78 286 78 870
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 5 . QUALITY OF DATA FOR CONDUCTIVITY IS 5 . QUALITY OF DATA FOR DIRECTION IS 4QUALITY OF DATA FOR SPEED IS 5 . QUALITY OF DATA FOR PRESSURE IS 1 .COMMENTS:
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37, 45.4 122* 21*9 178*2 555*9 6S5 40 E E E 28 6S005A1 36 T 12340 319 78 345 78 624
DATA HAS DEEM PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 5 * QUALITY OF DATA FOR CONDUCTIVITY IS 5 * QUALITY OF DATA FOR DIRECTION IS 5QUALITY OF DATA FOR SPEED IS 5 » QUALITY OF DATA FOR PRESSURE IS 1 *COMHENTS:POSSIDLE SPEED DEGRADATION FROH HARINE GROWTH,
37* 45*4 122* 21*9 178*2 555*9 6S5 40 E E E 16 GS005A2 42 T 12340 319 78 345 78 624
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 5 . QUALITY OF DATA FOR CONDUCTIVITY IS 5 . QUALITY OF DATA FOR DIRECTION IS 5QUALITY OF DATA FOR SPEED IS 5 * QUALITY OF DATA FOR PRESSURE IS 1 *COHHENTSJSOHE SPEED DEGRADATION FROH HARINE GROWTH*
37* 45.4 122* 21.9 178.2 555*9 GS5 40 E E E 5 GS005A3 34 T 12340 319 78 345 78 624
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 5 . QUALITY OF DATA FOR CONDUCTIVITY IS 5 * QUALITY OF DATA FOR DIRECTION IS 5QUALITY OF DATA FOR SPEED IS 5 . QUALITY OF DATA FOR PRESSURE IS 1 *COHKNTS:BRQKEN IMPELLER BLADE* HEAVY HARINE GROWTH EFFECTING SPEED.
37*46*2 122.21*3 180*3556.8 SS6 60 E E E 43 6S006A1 40 T 12340 31978 34578 626
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 5 . QUALITY OF DATA FOR CONDUCTIVITY IS 5 . QUALITY OF DATA FOR DIRECTION IS 5QUALITY OF DATA FOR SPEED IS 5 . QUALITY OF DATA FOR PRESSURE IS 1 .COHHENTSUHPELLER RESTRICTED DUE TO A PLASTIC SHEET IN IMPELLER,
37* 46*2 122. 21.3 180*3 556.8 BS6 60 E E E 24 6S006A2 41 T 12340 319 78 345 78 626
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 5 . QUALITY OF DATA FOR CONDUCTIVITY IS 5 . QUALITY OF DATA FOR DIRECTION IS 5QUALITY OF DATA FOR SPEED IS 5 * QUALITY OF DATA FOR PRESSURE IS 1 .COMMENTS: is HOURS OF DATA HISSING AT TIHE HETER LEFT WATER, FIRSTCONDUCTIVITY CORRECTION EDITED,
37* 46.2 122. 21*3 180*3 556.8 6S6 60 E E E 5 GS006A3 38 T 12340 319 78 345 78 626
DATA HAS BEEN PROCESSED THROUGH STEP 5-90-
QUALITY OF DATA FOR TEMPERATURE IS 5 . QUALITY OF DATA FOR CONDUCTIVITY IS 5 QUALITY OF DATA FOR SPEED IS 5 . QUALITY OF DATA FOR PRESSURE IS 1 . COMMENTS: MODERATE EFFECT ON SPEED DY MARINE GROWTH,
QUALITY OF DATA FOR DIRECTION IS 5
37, 46.2 122. 20.0 180.3 558*7 BS7 30 EE 18 GS007A1 39 T 12340 319 78 345 78 624
DATA HAS DEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 1 . QUALITY OF DATA FOR CONDUCTIVITY IS 5 . QUALITY OF DATA FOR DIRECTION IS 5QUALITY OF DATA FOR SPEED IS 5 . QUALITY OF DATA FOR PRESSURE IS 1 .COMMENTStTEMPERATURE DATA ARE DAD.
37. 46.2 122. 20.0 180.3 558.7 6S7 30 EE 5 GS007A2 31 T 12340 319 78 345 78 624
DATA HAS DEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 4 . QUALITY OF DATA FOR CONDUCTIVITY IS 4QUALITY OF DATA FOR SPEED IS 4 » QUALITY OF DATA FOR PRESSURE IS 1 .CQMNENTS.FIRST CONDUCTIVITY CORRECTION IMS EDITED. 6 HOURS OF PARTIALOR MISSING DATA (HOUR 26 TO 32).POSSIBLE SMALL EFFECT FROM GROWTH
QUALITY OF DATA FOR DIRECTION IS 4
37. 31.2 122. 8.0 152.7 576.6 6S8 30 EE 18 6S008A1 33 T 12340 319 78 345 78 24
DATA HAS BEEN PROCESSED THROUGH STEP 5QUALITY OF DATA FOR TEMPERATURE IS 2 . QUALITY OF DATA FOR CONDUCTIVITY IS 2 QUALITY OF DATA FOR SPEED IS 2. » QUALITY OF DATA FOR PRESSURE IS 1 . COMMENTStDEFECTIVE TAPE-ONLY ONE DAY OF DATA
QUALITY OF DATA FOR DIRECTION IS 2
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