Metadata Report for BODC Series Reference Number 739069

• Metadata Summary

• Problem Reports

• Data Access Policy

• Narrative Documents

• Project Information

• Data Activity or Cruise Information

• Fixed Station Information

• BODC Quality Flags

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Metadata Summary

Data Description

Data Category Currents -subsurface Eulerian Instrument Type Name Categories Nortek Aquadopp 3D doppler current meter   current meters; water temperature sensor Instrument Mounting subsurface mooring Originating Country United States Originator Prof Bill Johns Originating Organization Rosenstiel School of Marine and Atmospheric Science Processing Status banked Project(s) Rapid Climate Change Programme RAPIDMOC MOCHA

Data Identifiers

Originator's Identifier 36714/1156 BODC Series Reference 739069

Time Co-ordinates(UT)

Start Time (yyyy-mm-dd hh:mm) 2005-05-14 00:00 End Time (yyyy-mm-dd hh:mm) 2006-10-06 00:00 Nominal Cycle Interval 43200.0 seconds

Spatial Co-ordinates

Latitude 26.49550 N ( 26° 29.7' N ) Longitude 76.49967 W ( 76° 30.0' W ) Positional Uncertainty 0.0 to 0.01 n.miles Minimum Sensor Depth 4031.4 m Maximum Sensor Depth 4031.4 m Minimum Sensor Height 808.6 m Maximum Sensor Height 808.6 m Sea Floor Depth 4840.0 m Sensor Distribution Fixed common depth - All sensors are grouped effectively at the same depth which is effectively fixed for the duration of the series Sensor Depth Datum Approximate - Depth is only approximate Sea Floor Depth Datum Approximate - Depth is only approximate

Parameters

BODC CODE Rank Units Title AADYAA01 1 Days Date (time from 00:00 01/01/1760 to 00:00 UT on day) AAFDZZ01 1 Days Time (time between 00:00 UT and timestamp) ACYCAA01 1 Dimensionless Sequence number LCEWEL01 1 Centimetres per second Eastward current velocity (Eulerian) in the water body by in-situ current meter LCNSEL01 1 Centimetres per second Northward current velocity (Eulerian) in the water body by in-situ current meter PRSTPR01 1 Decibars Pressure (measured variable) exerted by the water body plus atmosphere by semi-fixed in-situ pressure sensor TEMPPR01 1 Degrees Celsius Temperature of the water body

Definition of Rank Rank 1 is a one-dimensional parameter Rank 2 is a two-dimensional parameter Rank 0 is a one-dimensional parameter describing the second dimension of a two-dimensional parameter (e.g. bin depths for moored ADCP data)

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Problem Reports

No Problem Report Found in the Database

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Data Access Policy

Public domain data

These data have no specific confidentiality restrictions for users. However, users must acknowledge data sources as it is not ethical to publish data without proper attribution. Any publication or other output resulting from usage of the data should include an acknowledgment.

The recommended acknowledgment is

"This study uses data from the data source/organisation/programme, provided by the British Oceanographic Data Centre and funded by the funding body."

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Narrative Documents

Nortek Aquadopp Open Water Current Meter

This instrument provides 3D acoustic doppler current measurements along with standard measurements of temperature, pressure, tilt and direction. It can be used in real time measurement situations or can log to an internal recorder powered by internal batteries. It can also be configured to measure surface wave height, period and direction concurrently. It has the unique feature of being run in 'diagnostic' mode when set to collect data at 1 Hz frequency in user specified intervals. This allows studies of mooring motion and the performance of other current meters to be conducted. It can be set in various configurations with titanium housings for deployment at greater depths.

Standard Measured Parameters

• 3D current velocity (East/North/Up, X/Y/Z or Beam 1/2/3)

• Acoustic signal strength (Beam 1/2/3)

• Compass

• Tilt

• Temperature

• Pressure

• Battery voltage

• Status code

• Error code

Surface wave monitoring

The standard Aquadopp is suitable for measuring surface wave height, period, and direction, which are calculated using the PUV method whereby spectra are estimated based on a combination of the pressure signal recorded by the instrument (P) and two horizontal components of the wave orbital velocity (U and V). More specifically, the pressure signal is used to provide an estimate of the wave frequency spectrum. The energy in this spectrum is then used to estimate wave height and period. The measurements of the wave orbital velocities are used to provide an estimate of the wave direction. Since these estimates are based on the distribution of wave energy and are not direct measurements of the free surface, they should be considered inferred estimates.

Both the dynamic pressure and the orbital velocities are driven by surface waves. The signals that are associated with these properties are complicated by the fact that they attenuate (that is the signals are weaker) with depth. The exact behaviour of the attenuation is determined by the water depth and the wavelength being observed. The greater the water depth the greater the attenuation; likewise, the shorter the wavelength (or higher the frequency of the wave) the greater the attenuation for a given water depth. This means that the estimation of wave parameters is limited by both water depth and wave frequency.

Specifications

Water Velocity Measurement
Range	± 5 m/s (standard 300 m version) ± 3 m/s (3000 m and 6000 m versions - higher ranges available on request)
Accuracy	1% of measured value ± 0.5 cm/s
Max. sampling rate	1 Hz, 4 Hz also available on request (standard version)
Internal sampling rate	23 Hz
Measurement Area
Measurement cell size	0.75 m
Measurement cell position	0.35 - 5.0 m
Default position	0.35 - 1.8 m
Doppler uncertainty (noise)
Typical	0.5 - 1.0 cm/s
At 1 Hz sampling rate	1.5 cm/s
Echo Intensity
Acoustic frequency	2 MHz
Resolution	0.45 dB
Dynamic range	90 dB
Sensors
Temperature	Thermistor embedded in head
Range	-4°C to 40°C
Accuracy/resolution	0.1°C / 0.01°C
Time response	10 min
Compass	Magnetometer
Accuracy/Resolution	2° / 0.1° for tilt < 20°
Tilt	Liquid level
Maximum tilt	30°
Up or down	Automatic detect
Pressure	Piezoresistive
Range	0 - 300 m (standard), 0 - 3000 m or 0 - 6000 m
Accuracy/resolution	0.5%
Analogue Inputs
No. of channels	2
Voltage supply	12 V
Voltage input	16 bit A/D
Materials
Standard version	Delrin with titanium screws
3000 m version	Delrin with titanium screws
6000 m version	Titanium with Delrin transducer head
Environmental
Operating temperature	-4°C to 40°C
Dimensions
Cylinder	568 mm x 75 mm (standard) 619 mm x 84 mm (3000 m version) 625 mm x 84 mm (6000 m version)
Weight in air	3.5 kg (standard) 3.6 kg (3000 m version) 7.6 kg (6000 m version)
Weight in water	Neutral (standard) 1.2 kg (3000 m version) 4.8 kg (6000 m version)

Further details can be found in the manufacturer's specification sheets for the Aquadopp, Aquadopp 3000 and Aquadopp 6000.

RAPIDMOC/MOCHA Current Meter data processing document

This document outlines the procedures undertaken to process and quality assure current meter data collected under the RAPIDMOC and MOCHA projects.

Originator's processing

The raw data are downloaded from the instrument and converted to ASCII format.

Once in ASCII format the data are corrected for the following -

• Speed bias (caused by the mooring motion)
• Sound speed (as electromagnetic current meter sensors use the speed of sound in water to calculate the doppler shift in the returned signal, they are corrected for variations in sound speed using temperature data as sound speed varies with temperature).
• Magnetic variation

A 40 hour low pass filter is also applied to the data.

Calculating and applying calibrations

Manufacturers calibrations are applied.

Quality Control

Data were visually inspected for out-lying data and instrument electrical spikes removed.

BODC processing

Data are received after quality checks have been made and calibrations have been applied. The data files are submitted in ASCII format as one file per instrument.

Once the submitted data files are safely archived, the data undergo reformatting and banking procedures:

• The data files are transferred into a common format, a NetCDF subset.

• Standard parameter codes are assigned that accurately describe the data (see Parameter mapping section below).

• Unit conversions are applied, if necessary, so that units are standardised (see Parameter mapping section below).

• The data are screened visually and any spikes or instrument malfunctions can be clearly labelled with quality control flags.

• Comprehensive documentation is prepared describing the collection, processing and quality of each data series.

• Detailed metadata and documents are loaded to the database and linked to each series so that the information is readily available to future users.

Parameter mapping

The following describes the parameters contained in the originator's files and their mapping to BODC parameter codes:

Identifier	Unit	Definition	BODC parameter code	Units	Unit conversion	Comments
YY	year	Year	AADYAA01	days	-	Combined with MM and DD to form a date and transferred
MM	month	Month	AADYAA01	days	-	Combined with MM and DD to form a date and transferred
DD	day	Day	AADYAA01	days	-	Combined with MM and DD to form a date and transferred
HH	hour	Decimal hours	AAFDZZ01	days	/24	Transferred
T	°C	Temperature	TEMPPR01	°C	-	Transferred
P	dbar	Pressure	PRSTPR01	dbar	-	Transferred
U	cm/s	Eastward velocity	LCEWEL01	cm/s	-	Transferred
V	cm/s	Northward velocity	LCNSEL01	cm/s	-	Transferred

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Project Information

Rapid Climate Change (RAPID) Programme

Rapid Climate Change (RAPID) is a £20 million, six-year (2001-2007) programme of the Natural Environment Research Council (NERC). The programme aims to improve our ability to quantify the probability and magnitude of future rapid change in climate, with a main (but not exclusive) focus on the role of the Atlantic Ocean's Thermohaline Circulation.

Scientific Objectives

• To establish a pre-operational prototype system to continuously observe the strength and structure of the Atlantic Meridional Overturning Circulation (MOC).
• To support long-term direct observations of water, heat, salt, and ice transports at critical locations in the northern North Atlantic, to quantify the atmospheric and other (e.g. river run-off, ice sheet discharge) forcing of these transports, and to perform process studies of ocean mixing at northern high latitudes.
• To construct well-calibrated and time-resolved palaeo data records of past climate change, including error estimates, with a particular emphasis on the quantification of the timing and magnitude of rapid change at annual to centennial time-scales.
• To develop and use high-resolution physical models to synthesise observational data.
• To apply a hierarchy of modelling approaches to understand the processes that connect changes in ocean convection and its atmospheric forcing to the large-scale transports relevant to the modulation of climate.
• To understand, using model experimentation and data (palaeo and present day), the atmosphere's response to large changes in Atlantic northward heat transport, in particular changes in storm tracks, storm frequency, storm strengths, and energy and moisture transports.
• To use both instrumental and palaeo data for the quantitative testing of models' abilities to reproduce climate variability and rapid changes on annual to centennial time-scales. To explore the extent to which these data can provide direct information about the thermohaline circulation (THC) and other possible rapid changes in the climate system and their impact.
• To quantify the probability and magnitude of potential future rapid climate change, and the uncertainties in these estimates.

Projects

Overall 38 projects have been funded by the RAPID programme. These include 4 which focus on Monitoring the Meridional Overturning Circulation (MOC), and 5 international projects jointly funded by the Netherlands Organisation for Scientific Research, the Research Council of Norway and NERC.

The RAPID effort to design a system to continuously monitor the strength and structure of the North Atlantic Meridional Overturning Circulation is being matched by comparative funding from the US National Science Foundation (NSF) for collaborative projects reviewed jointly with the NERC proposals. Three projects were funded by NSF.

A proportion of RAPID funding as been made available for Small and Medium Sized Enterprises (SMEs) as part of NERC's Small Business Research Initiative (SBRI). The SBRI aims to stimulate innovation in the economy by encouraging more high-tech small firms to start up or to develop new research capacities. As a result 4 projects have been funded.

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Monitoring the Meridional Overturning Circulation at 26.5N (RAPIDMOC)

Scientific Rationale

There is a northward transport of heat throughout the Atlantic, reaching a maximum of 1.3PW (25% of the global heat flux) around 24.5°N. The heat transport is a balance of the northward flux of a warm Gulf Stream, and a southward flux of cooler thermocline and cold North Atlantic Deep Water that is known as the meridional overturning circulation (MOC). As a consequence of the MOC northwest Europe enjoys a mild climate for its latitude: however abrupt rearrangement of the Atlantic Circulation has been shown in climate models and in palaeoclimate records to be responsible for a cooling of European climate of between 5-10°C. A principal objective of the RAPID programme is the development of a pre-operational prototype system that will continuously observe the strength and structure of the MOC. An initiative has been formed to fulfill this objective and consists of three interlinked projects:

• A mooring array spanning the Atlantic at 26.5°N to measure the southward branch of the MOC (Hirschi et al., 2003 and Baehr et al., 2004).
• Additional moorings deployed in the western boundary along 26.5°N (by Prof. Bill Johns, University of Miami) to resolve transport in the Deep Western Boundary Current (Bryden et al., 2005). These moorings allow surface-to-bottom density profiles along the western boundary, Mid-Atlantic Ridge, and eastern boundary to be observed. As a result, the transatlantic pressure gradient can be continuously measured.
• Monitoring of the northward branch of the MOC using submarine telephone cables in the Florida Straits (Baringer et al., 2001) led by Dr Molly Baringer (NOAA/AOML/PHOD).

The entire monitoring array system created by the three projects will be recovered and redeployed annually until 2008 under RAPID funding. From 2008 until 2014 the array will continue to be serviced annually under RAPID-WATCH funding.

The array will be focussed on three regions, the Eastern Boundary (EB), the Mid Atlantic Ridge (MAR) and the Western Boundary (WB). The geographical extent of these regions are as follows:

• Eastern Boundary (EB) array defined as a box with the south-east corner at 23.5°N, 25.5°W and the north-west corner at 29.0°N, 12.0°W
• Mid Atlantic Ridge (MAR) array defined as a box with the south-east corner at 23.0°N, 52.1°W and the north-west corner at 26.5°N, 40.0°W
• Western Boundary (WB) array defined as a box with the south-east corner at 26.0°N, 77.5°W and the north-west corner at 27.5°N, 69.5°W

References

Baehr, J., Hirschi, J., Beismann, J.O. and Marotzke, J. (2004) Monitoring the meridional overturning circulation in the North Atlantic: A model-based array design study. Journal of Marine Research, Volume 62, No 3, pp 283-312.

Baringer, M.O'N. and Larsen, J.C. (2001) Sixteen years of Florida Current transport at 27N Geophysical Research Letters, Volume 28, No 16, pp3179-3182

Bryden, H.L., Johns, W.E. and Saunders, P.M. (2005) Deep Western Boundary Current East of Abaco: Mean structure and transport. Journal of Marine Research, Volume 63, No 1, pp 35-57.

Hirschi, J., Baehr, J., Marotzke J., Stark J., Cunningham S.A. and Beismann J.O. (2003) A monitoring design for the Atlantic meridional overturning circulation. Geophysical Research Letters, Volume 30, No 7, article number 1413 (DOI 10.1029/2002GL016776)

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Meridional Overturning Circulation and Heatflux Array (MOCHA) Project

Introduction

Users of these data are referred to the Meridional Overturning Circulation and Heatflux Array (MOCHA) Project Website for more information. The following text has been taken from the website.

Scientific Rationale

To set in place a system for continuous observation of the meridional heat transport in the subtropical Atlantic, with which to document its variability and its relationship to oberved climate fluctuations, and to assess climate model predictions

Overview

MOCHA is a collaborative project, partnered with the UK RAPID Program, to measure the heat and freshwater transports of the North Atlantic Ocean. These transports are called the Thermohaline or Overturning Circulation. Simply put, warm waters move poleward at the surface of the ocean, where they cool and sink, to return equatorward in the deep ocean.

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Data Activity or Cruise Information

Data Activity

Start Date (yyyy-mm-dd)	2005-05-13
End Date (yyyy-mm-dd)	2006-10-06
Organization Undertaking Activity	Rosenstiel School of Marine and Atmospheric Science
Country of Organization	United States
Originator's Data Activity Identifier	WB3#2
Platform Category	subsurface mooring

RAPID Moored Instrument Rig WB3#2

This rig was deployed as part of the Western Boundary (WB) array of the MOCHA/RAPIDMOC project.

Deployment cruise	RV Knorr cruise KN182_2
Recovery cruise	RV Seward Johnson cruise SJ14-06

The rig was anchored by 5200lbs of railway wheels and was kept erect by a large sub-surface float supplemented by groups of smaller buoyancy glass floats attached throughout the mooring.

Instruments deployed on the rig

Depth	Instrument
60m	Sea-Bird SBE37 SMP MicroCAT (#486)
100m	SonTek Argonaut MD current meter (#D293)
114m	Sea-Bird SBE37 SMP MicroCAT (#482)
267m	Sea-Bird SBE37 SMP MicroCAT (#483)
401.1m	Nortek Aquadopp current meter (#1123)
413m	Sea-Bird SBE37 SMP MicroCAT (#3165)
611m	Sea-Bird SBE37 SMP MicroCAT (#485)
811.5m	Nortek Aquadopp current meter (#1136)
813m	Sea-Bird SBE37 SMP MicroCAT (#3167)
1012m	Sea-Bird SBE37 SMP MicroCAT (#3859)
1209.6m	Nortek Aquadopp current meter (#1138)
1211m	Sea-Bird SBE37 SMP MicroCAT (#3164)
1608m	Sea-Bird SBE37 SMP MicroCAT (#3860)
2011m	Sea-Bird SBE37 SMP MicroCAT (#3168)
2018.7m	Nortek Aquadopp current meter (#1144)
2511m	Sea-Bird SBE37 SMP MicroCAT (#3861)
3009m	Sea-Bird SBE37 SMP MicroCAT (#3163)
3025.5m	Nortek Aquadopp current meter (#1148)
3503m	Sea-Bird SBE37 SMP MicroCAT (#3862)
4003m	Sea-Bird SBE37 SMP MicroCAT (#3863)
4031.4m	Nortek Aquadopp current meter (#1156)
4492m	Sea-Bird SBE37 SMP MicroCAT (#3864)
5000m	Sea-Bird SBE37 SMP MicroCAT (#3865)

No data were recorded by instruments SonTek Argonaut MD #D293 and Sea-Bird SBE37 SMP MicroCAT #3865. Instrument Sea-Bird SBE37 SMP MicroCAT #486 was lost and no data are expected.

Other Series linked to this Data Activity - 812998 812974 812925 812937 812949 812950 739033 739045 812894 812913 739021 739057 812986 813001 739008 812882 812901 812962 813013

Cruise

Cruise Name	KN182_2
Departure Date	2005-05-02
Arrival Date	2005-05-26
Principal Scientist(s)	William E Johns (Rosenstiel School of Marine and Atmospheric Science)
Ship	RV Knorr

Complete Cruise Metadata Report is available here

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Fixed Station Information

Fixed Station Information

Station Name	Western Boundary Array
Category	Offshore area
Latitude	26° 37.50' N
Longitude	73° 37.50' W
Water depth below MSL

RAPIDMOC Western Boundary (WB) Array

The Western Boundary Array defines a box in which moorings were deployed at the western side of the North Atlantic as part of the RAPIDMOC project and the collaborative project Meridional Overturning Circulation and Heatflux Array (MOCHA). The box region has latitudinal limits of 26° N to 27.5° N and longitudinal limits of 69.5° W to 77.5° W. Moorings have occupied this region since 2004 and are typically deployed for 6 to 18 months.

Moored data summary

Year	Cruise ID	Number of moorings	Data types (number of instruments)
2004	D278	9 (6 RAPIDMOC, 3 MOCHA)	ADCP (2), BPR (8), CM (29), MCTD (52), MMP (1)
2005	KN182_2	11 (6 RAPIDMOC, 5 MOCHA)	ADCP (2), BPR (6), CM (27), MCTD (56)
2006	RB06-02, SJ14-06	11 (6 RAPIDMOC, 5 MOCHA)	ADCP (1), BPR (3), CM (22), IES (7), MCTD (60)
2007	RB07-01	7 (7 RAPIDMOC)	ADCP (1), BPR (4), CM (16), MCTD (47)
2008	SJ08-03	11 (8 RAPIDMOC, 3 MOCHA)	ADCP (2), BPR (3), CM (40), MCTD (80)
2009	RB0901, D344, D345	16 (11 RAPIDMOC, 5 MOCHA)	ADCP (2), BPR (5), CM (39), MCTD (91), DVS (1)
2010	OC459-1, RB1009	9 (8 RAPIDMOC, 1 MOCHA)	ADCP (1), BPR (7), CM (23), MCTD (54)
2011	KN200-4	7 (7 RAPIDMOC, 6 MOCHA)	ADCP (2), BPR (7), CM (43), MCTD (86), DVS (1), IES (1)

Cruise data summary

During the cruises to service the moored array, a variety of data types are collected. The table below is a summary of these data. The number of CTD profiles performed on these cruises within the box region defined above is also included. Trans-Atlantic hydrographic CTD sections have also been performed since 2004 and are included in the table.

Cruise ID	Cruise description	Data types	Number of CTD profiles performed within the box region
D277	Initial array deployment	DIS, MET, NAV, SADCP, SURF	1
D278	Initial array deployment	DIS, MET, NAV, SADCP, SURF	16
D279	Hydrographic section	CTD, DIS, LADCP, MET, NAV, SADCP, SURF	31
KN182_2	Array service	CTD, DIS, MET, NAV, SADCP, SURF	64
RB0601	Array service	CTD, DIS, LADCP, MET, NAV, SADCP, SURF	39
SJ14-06	Array service	CTD, DIS, LADCP, MET, NAV, SADCP, SURF	33
RB07-01	Array service	CTD, DIS, LADCP, MET, NAV, SADCP, SURF	36
SJ08-03	Array service	CTD, DIS, LADCP, MET, NAV, SADCP, SURF	33
RB0901	Array service	CTD, DIS, LADCP, MET, NAV, SADCP, SURF	35
D344	Array service	CTD, DIS, MET, NAV, SADCP, SURF	3
D345	Array service	CTD, DIS, LADCP, MET, NAV, SADCP, SURF	24
OC459-1	Array service	CTD, DIS, MET, NAV, SADCP, SURF	9
OC459-2	Western Boundary Hydrographic section	CTD, DIS, LADCP, MET, NAV, SADCP, SURF	27
D346	Hydrographic section	CTD, DIS, LADCP, MET, NAV, SADCP, SURF	31
RB1009	WB4 service	CTD, MET, SURF, NAV	2
KN200-4	Array service	CTD, DIS, MET, NAV, SURF	34

Data type ID and description

Data type ID	Description
ADCP	Acoustic Doppler Current Profiler
BATH	Bathymetry
BPR	Bottom Pressure Recorder
CM	Current Meter
CTD	Conductivity-Temperature-Depth profiler
DIS	Discrete water bottle samples
DVS	Doppler Volume sampler
IES	Inverted Echo Sounder
LADCP	Lowered Acoustic Doppler Current Profiler
MET	Meteorology
MCTD	Moored Conductivity-Temperature-Depth sensor
MMP	McLane Moored Profiler - profiling CTD and current meter
NAV	Navigation
SADCP	Shipborne Acoustic Doppler Current Profiler
SURF	Sea surface data

Other Series linked to this Fixed Station for this cruise - 738828 738841 738853 738865 738877 738889 738890 738908 738921 738933 738945 738957 738969 738970 738982 738994 739008 739021 739033 739045 739057 739070 739082 739094 739101 739113 739125 739137 739149 774528 774541 774553 774565 774577 774589 774590 774608 774621 774633 774645 774657 774669 774670 774682 774694 774701 774713 774725 774737 774749 812882 812894 812901 812913 812925 812937 812949 812950 812962 812974 812986 812998 813001 813013 813025 813037 813049 813050 813062 813074 813086 813098 813105 813117 813129 813130 813142 813154 813166 813178 946204 946216 946253 946265

Other Cruises linked to this Fixed Station (with the number of series) - D278 (90) D344 (8) D345 (41) D346 (31) KN182_2 (84) KN200-4 (86) OC459-1 (56) RB0602 (42) RB0701 (58) RB0901 (75) RB1009 (24) RB1201 (55) SJ-08-03 Leg 1 (37) SJ-08-03 Leg 2 (75) SJ-14-06 (62)

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BODC Quality Control Flags

The following single character qualifying flags may be associated with one or more individual parameters with a data cycle:

Flag	Description
Blank	Unqualified
<	Below detection limit
>	In excess of quoted value
A	Taxonomic flag for affinis (aff.)
B	Beginning of CTD Down/Up Cast
C	Taxonomic flag for confer (cf.)
D	Thermometric depth
E	End of CTD Down/Up Cast
G	Non-taxonomic biological characteristic uncertainty
H	Extrapolated value
I	Taxonomic flag for single species (sp.)
K	Improbable value - unknown quality control source
L	Improbable value - originator's quality control
M	Improbable value - BODC quality control
N	Null value
O	Improbable value - user quality control
P	Trace/calm
Q	Indeterminate
R	Replacement value
S	Estimated value
T	Interpolated value
U	Uncalibrated
W	Control value
X	Excessive difference

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