Metadata Report for BODC Series Reference Number 943126
Metadata Summary
Problem Reports
Data Access Policy
Narrative Documents
Project Information
Data Activity or Cruise Information
Fixed Station Information
BODC Quality Flags
SeaDataNet Quality Flags
Metadata Summary
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Problem Reports
No Problem Report Found in the Database
Data Quality Report
All hydrographic channels have been flagged from the beginning of the data series until 06:02:46 03/07/2009. Prior to this point a regular profiling pattern had not started so as a consequence data are highly varible during this period.
In addition all hydrographic data are flagged from cycle 11:35:37 03/07/2009 until the end of the data series as during this period the scanfish was being raised out of the water and consequently data are highly variable.
Data Access Policy
Open Data supplied by Natural Environment Research Council (NERC)
You must always use the following attribution statement to acknowledge the source of the information: "Contains data supplied by Natural Environment Research Council."
Narrative Documents
D340B Scanfish Instrumentation
CTD unit and auxiliary sensors
The scanfish CTD was deployed with a Sea-Bird 911 plus unit in addition to a Chelsea Aquatracka III Fluorometer. Temperature and fluoresence sensors were sited on the right side of the scanfish body with the conductivity cell mounted in-board. The scanfish was fitted with the following scientific sensors:
Sensor | Serial Number | Last calibration date |
---|---|---|
Primary Temperature Sensor | 4137 | 1 May 2008 |
Primary Conductivity Sensor | 2801 | 9 May 2008 |
Digiquartz Pressure Sensor | 44933 | 14 June 1991 |
Chelsea Aquatracka Mk III (chlorophyll a) fluorometer | 088126 | 2 January 2007 |
Sea-Bird Electronics SBE 911 and SBE 917 series CTD profilers
The SBE 911 and SBE 917 series of conductivity-temperature-depth (CTD) units are used to collect hydrographic profiles, including temperature, conductivity and pressure as standard. Each profiler consists of an underwater unit and deck unit or SEARAM. Auxiliary sensors, such as fluorometers, dissolved oxygen sensors and transmissometers, and carousel water samplers are commonly added to the underwater unit.
Underwater unit
The CTD underwater unit (SBE 9 or SBE 9 plus) comprises a protective cage (usually with a carousel water sampler), including a main pressure housing containing power supplies, acquisition electronics, telemetry circuitry, and a suite of modular sensors. The original SBE 9 incorporated Sea-Bird's standard modular SBE 3 temperature sensor and SBE 4 conductivity sensor, and a Paroscientific Digiquartz pressure sensor. The conductivity cell was connected to a pump-fed plastic tubing circuit that could include auxiliary sensors. Each SBE 9 unit was custom built to individual specification. The SBE 9 was replaced in 1997 by an off-the-shelf version, termed the SBE 9 plus, that incorporated the SBE 3 plus (or SBE 3P) temperature sensor, SBE 4C conductivity sensor and a Paroscientific Digiquartz pressure sensor. Sensors could be connected to a pump-fed plastic tubing circuit or stand-alone.
Temperature, conductivity and pressure sensors
The conductivity, temperature, and pressure sensors supplied with Sea-Bird CTD systems have outputs in the form of variable frequencies, which are measured using high-speed parallel counters. The resulting count totals are converted to numeric representations of the original frequencies, which bear a direct relationship to temperature, conductivity or pressure. Sampling frequencies for these sensors are typically set at 24 Hz.
The temperature sensing element is a glass-coated thermistor bead, pressure-protected inside a stainless steel tube, while the conductivity sensing element is a cylindrical, flow-through, borosilicate glass cell with three internal platinum electrodes. Thermistor resistance or conductivity cell resistance, respectively, is the controlling element in an optimized Wien Bridge oscillator circuit, which produces a frequency output that can be converted to a temperature or conductivity reading. These sensors are available with depth ratings of 6800 m (aluminium housing) or 10500 m (titanium housing). The Paroscientific Digiquartz pressure sensor comprises a quartz crystal resonator that responds to pressure-induced stress, and temperature is measured for thermal compensation of the calculated pressure.
Additional sensors
Optional sensors for dissolved oxygen, pH, light transmission, fluorescence and others do not require the very high levels of resolution needed in the primary CTD channels, nor do these sensors generally offer variable frequency outputs. Accordingly, signals from the auxiliary sensors are acquired using a conventional voltage-input multiplexed A/D converter (optional). Some Sea-Bird CTDs use a strain gauge pressure sensor (Senso-Metrics) in which case their pressure output data is in the same form as that from the auxiliary sensors as described above.
Deck unit or SEARAM
Each underwater unit is connected to a power supply and data logging system: the SBE 11 (or SBE 11 plus) deck unit allows real-time interfacing between the deck and the underwater unit via a conductive wire, while the submersible SBE 17 (or SBE 17 plus) SEARAM plugs directly into the underwater unit and data are downloaded on recovery of the CTD. The combination of SBE 9 and SBE 17 or SBE 11 are termed SBE 917 or SBE 911, respectively, while the combinations of SBE 9 plus and SBE 17 plus or SBE 11 plus are termed SBE 917 plus or SBE 911 plus.
Specifications
Specifications for the SBE 9 plus underwater unit are listed below:
Parameter | Range | Initial accuracy | Resolution at 24 Hz | Response time |
---|---|---|---|---|
Temperature | -5 to 35°C | 0.001°C | 0.0002°C | 0.065 sec |
Conductivity | 0 to 7 S m-1 | 0.0003 S m-1 | 0.00004 S m-1 | 0.065 sec (pumped) |
Pressure | 0 to full scale (1400, 2000, 4200, 6800 or 10500 m) | 0.015% of full scale | 0.001% of full scale | 0.015 sec |
Further details can be found in the manufacturer's specification sheet.
Aquatracka fluorometer
The Chelsea Instruments Aquatracka is a logarithmic response fluorometer. It uses a pulsed (5.5 Hz) xenon light source discharging between 320 and 800 nm through a blue filter with a peak transmission of 420 nm and a bandwidth at half maximum of 100 nm. A red filter with sharp cut off, 10% transmission at 664 nm and 678 nm, is used to pass chlorophyll-a fluorescence to the sample photodiode.
The instrument may be deployed either in a through-flow tank, on a CTD frame or moored with a data logging package.
Further details can be found in the manufacturer's specification sheet.
D340B Scanfish Originator Processing
Sampling Strategy
A total of 4 scanfish tow-yo surveys were conducted during the cruise D340B. The scanfish was generally 'flown' at tow speeds of 8.0 knots, from depths of 1-5 m below the surface to 100-110 m or within 10 m of the sea bed in shallower areas of the transect. This sampling regime produced an effective horizontal resolution of approximately 400 m by cycling the scanfish every 2 minutes.
Data Processing
Following the completion of each scanfish tow-yo survey the data were saved to the deck unit PC and transferred over the ship network to a Unix data disk. SBE Seasave Win32 V 5.37e software was used to perform all processing steps.
Raw data files were converted to engineering units and ASCII (.CNV) files containing 24Hz down and up cast data were produced using the DATCNV program. FILTER was run on all data with the pressure channel being filtered with a time constant of 0.5 seconds. It was necessary to apply shifts equal to 0.5 seconds to the temperature and conductivity sensor outputs by ALIGNCTD due to fast horizontal movement of the instrument during tow-yo surveys. The effect of thermal inertia on conductivity cells was removed by CELLTM and data were averaged using pressure with a 1 m bin size for up and downcasts using BINAVERAGE. Depth, potential temperature, salinity and Specific Volume Anomaly were all calculated by DERIVE and finally the binary .cnv files were converted into ASCII format .cnv files by ASCIIOUT.
At the end of the SBE processing routine the time series of EA500 Echo-Sounder data were aligned with the ship GPS navigation data to produce the bottom relief profiles during scanfish tow-yo transects.
References
Inall, M. E., (2009) 'Cruise D340B Dunstaffnage to Govan via Barra Head and the Surrounding Shelf', Internal Report No 265, Scottish Association for Marine Science.
Available - Cruise D340B Internal Report
D340B Scanfish Processing undertaken by BODC
Data arrived at BODC in a total of 9 ASCII files representing data collected from the 4 scanfish surveys conducted during D340B. These were reformatted to BODC's internal QXF format which also appended the consecutive data files from each scanfish survey together to produce one file for each.
The following table shows the mapping of variables within the ASCII files to appropriate BODC parameter codes:
Originator' Variable | Units | Description | BODC Parameter Code | Units | Comments |
---|---|---|---|---|---|
Pressure | dbar | Pressure exerted by water body | PRESPR01 | dbar | - |
Temperature | °C | Temperature of water body | TEMPS901 | °C | - |
Salinity | - | Practical salinity of water body | PSALPR01 | - | - |
Conductivity | S/m | Electrical conductivity of water body | CNDCPR01 | S/m | - |
Fluorescence | ug/l | Concentration of chlorophyll-a per unit volume of the water body | CPHLPM01 | mg/m3 | Manufacturer's calibration applied |
Latitude | deg | Latitude north by Trimble GPS | ALATTR01 | deg | - |
Longitude | deg | Longitude east by Trimble GPS | ALONTR01 | deg | - |
The reformatted data were visualised using the in-house EDSERPLO software. Suspect data were marked by adding an appropriate quality control flag, and missing data marked by both setting the data to an appropriate value and setting the quality control flag.
Project Information
Oceans 2025 Theme 3: Shelf and Coastal Processes
Over the next 20 years, UK local marine environments are predicted to experience ever-increasing rates of change - including increased temperature and seawater acidity, changing freshwater run-off, changes in sea level, and a likely increase in flooding events - causing great concern for those charged with their management and protection. The future quality, health and sustainability of UK marine waters require improved appreciation of the complex interactions that occur not only within the coastal and shelf environment, but also between the environment and human actions. This knowledge must primarily be provided by whole-system operational numerical models, able to provide reliable predictions of short and long-term system responses to change.
However, such tools are only viable if scientists understand the underlying processes they are attempting to model and can interpret the resulting data. Many fundamental processes in shelf edge, shelf, coastal and estuarine systems, particularly across key interfaces in the environment, are not fully understood.
Theme 3 addresses the following broad questions:
- How do biological, physical and chemical processes interact within shelf, coastal and estuarine systems, particularly at key environmental interfaces (e.g. coastline, sediment-water interface, thermocline, fronts and the shelf edge)?
- What are the consequences of these interactions on the functioning of the whole coastal system, including its sensitivity and/or resilience to change?
- Ultimately, what changes should be expected to be seen in the UK coastal environment over the next 50 years and beyond and how might these changes be transmitted into the open ocean?
Within Oceans 2025, Theme 3 will develop the necessary understanding of interacting processes to enable the consequences of environmental and anthropogenic change on UK shelf seas, coasts and estuaries to be predicted. Theme 3 will also provide knowledge that can improve the forecasting capability of models being used for the operational management of human activities in the coastal marine environment. Theme 3 is therefore directly relevant to all three of NERC's current strategic priorities; Earth's Life-Support Systems, Climate Change, and Sustainable Economies
The official Oceans 2025 documentation for this Theme is available from the following link: Oceans 2025 Theme 3
Weblink: http://www.oceans2025.org/
Data Activity or Cruise Information
Cruise
Cruise Name | D340B |
Departure Date | 2009-06-25 |
Arrival Date | 2009-07-04 |
Principal Scientist(s) | Mark E Inall (Scottish Association for Marine Science) |
Ship | RRS Discovery |
Complete Cruise Metadata Report is available here
Fixed Station Information
No Fixed Station Information held for the Series
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 |
SeaDataNet Quality Control Flags
The following single character qualifying flags may be associated with one or more individual parameters with a data cycle:
Flag | Description |
---|---|
0 | no quality control |
1 | good value |
2 | probably good value |
3 | probably bad value |
4 | bad value |
5 | changed value |
6 | value below detection |
7 | value in excess |
8 | interpolated value |
9 | missing value |
A | value phenomenon uncertain |
B | nominal value |
Q | value below limit of quantification |