Video Plankton Recorder data from R/V Columbus Iselin, R/V Endeavor cruises CI9407, EN259, and EN262 in the Gulf of Maine and Georges Bank from 1994-1995 (GB project)

Website: https://www.bco-dmo.org/dataset/2331
Data Type: Cruise Results
Version: 1
Version Date: 2012-07-25

Project
» U.S. GLOBEC Georges Bank (GB)

Program
» U.S. GLOBal ocean ECosystems dynamics (U.S. GLOBEC)
ContributorsAffiliationRole
Ashjian, Carin J.Woods Hole Oceanographic Institution (WHOI)Principal Investigator
Allison, DickyWoods Hole Oceanographic Institution (WHOI)BCO-DMO Data Manager

Abstract
Video Plankton Recorder data from R/V Columbus Iselin, R/V Endeavor cruises CI9407, EN259, and EN262 in the Gulf of Maine and Georges Bank from 1994-1995


Coverage

Spatial Extent: N:42.38351 E:-66.286005 S:40.9115 W:-67.541526
Temporal Extent: 1994 - 1995

Dataset Description

This dataset includes ALL the abundance values, zero and non-zero.  The data files are very large.  In order to map the VPR data, see the VPR_ashjian_nonzero [http://globec.whoi.edu/jg/serv/globec/gb/vpr_cashjian_nonzero.html0]. In the 'nonzero' dataset, values of 0 in the abund_L column (taxon abundance) have been removed.

For an alternate display, including both zero and non-zero data, see VPR_ashjian_alt [http://globec.whoi.edu/jg/serv/globec/gb/vpr_cashjian_read.html0].

Methodology
The following information was extracted from C.J. Ashjian et al., Deep- Sea Research II 48(2001) 245-282 . An in-depth discussion of the data and sampling methods can be found there.

The Video Plankton Recorder was towed at 2 m/s, collecting data from the surface to the bottom (towyo). The VPR was equipped with 2-4 cameras, temperature and conductivity probes, fluorometer and transmissometer. Environmental data was collected at 0.25 Hz (CI9407) or 0.5 Hz (EN259, EN262). Video images were recorded at 60 fields per second (fps).

Video tapes were analyzed for plankton abundances using a semi-automated method discussed in Davis, C.S. et al., Deep-Sea Research II 43 (1996) 1946-1970. In-focus images were extracted from the video tapes and identified by hand to particle type, taxon, or species. Plankton and particle observations were merged with environmental and navigational data by binning the observations for each category into the time intervals at which the environmental data were collected (again see above Davis citation). Concentrations were calculated utilizing the total volume (liters) imaged during that period. For less-abundant categories, usually only a single organism was observed during each time interval so that the resulting concentrations are close to presence or absence data rather than covering a range of values.


Methods & Sampling

The Video Plankton Recorder was towed at 2 m/s, collecting data from the surface to the bottom (towyo). The VPR was equipped with 2-4 cameras, temperature and conductivity probes, fluorometer and transmissometer. Environmental data was collected at 0.25 Hz (CI9407) or 0.5 Hz (EN259, EN262). Video images were recorded at 60 fields per second (fps).


Data Processing Description

Video tapes were analyzed for plankton abundances using a semi-automated method discussed in Davis, C.S. et al., Deep-Sea Research II 43 (1996) 1946-1970. In-focus images were extracted from the video tapes and identified by hand to particle type, taxon, or species. Plankton and particle observations were merged with environmental and navigational data by binning the observations for each category into the time intervals at which the environmental data were collected (again see above Davis citation). Concentrations were calculated utilizing the total volume (liters) imaged during that period. For less-abundant categories, usually only a single organism was observed during each time interval so that the resulting concentrations are close to presence or absence data rather than covering a range of values.


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Data Files

File
vpr_cashjian.csv
(Comma Separated Values (.csv), 26.21 MB)
MD5:40b8cf6215a648a98a0d0ed478b25868
Primary data file for dataset ID 2331

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Parameters

ParameterDescriptionUnits
cruiseid

Cruise identification

year

year GMT

yrday0_gmt

year day, Jan 1 = 0, GMT

YYY.Y
month_gmt

month, GMT

day_gmt

day of tow, GMT

time_gmt

hour and decimal minute of binned video image, GMT

HHmm.m
lat

latitude, negative = south

decimal degrees
lon

longitude, negative = west

decimal degrees
press

pressure, depth of data interval

decibars
temp

temperature

degrees centigrade
sal

salinity, derived using Neil Brown software

PSU
sigma_t

sigma_t, density

kilograms/meter^3
flvolt

fluorescence

volts
fluor

fluorescence

relative units
trans_v

light transmission

volts
dist_along_track

distance along ship's track

kilometers
brief_desc

Brief description of the type of cruise.

dimensionless
Hydroids

asexual hydroid phase of Cnidarians

number/liter; close to presence or absence
Other

other zooplankton not categorized

number/liter; close to presence or absence
Cerianthid

Cerianthids

number/liter; close to presence or absence
Calanus

Calanus sp. but likely finmarchicus

number/liter; close to presence or absence
Earlyphaeoproto

Early phaeocystis spp. Protocolonies

number/liter; close to presence or absence
Phaeoproto

Phaeocystis spp. protocolonies

number/liter; close to presence or absence
Marinesnow

Particles of plankton marine snow

number/liter; close to presence or absence
Pteropod

Pteropods

number/liter; close to presence or absence
Chaetognath

Chaetognaths

number/liter; close to presence or absence
Pseudocalanus

Pseudocalanus spp.

number/liter; close to presence or absence
Cope_uid

unidentified copepods

number/liter; close to presence or absence
Pseudowegg

Pseudocalanus with eggs

number/liter; close to presence or absence
Amphipods

Amphipods

number/liter; close to presence or absence
Euphausiid

Euphausiids

number/liter; close to presence or absence
Hydromedusa

Hydromedusae

number/liter; close to presence or absence
Medusa_uid

unidentified medusae

number/liter; close to presence or absence
Algalmat

Collections of diatom chains

number/liter; close to presence or absence
Larvacean

Larvaceans

number/liter; close to presence or absence
Echinoderm

Echinoderm

number/liter; close to presence or absence
Dino_Ceratium

Dinoflagellate Ceratium species

number/liter; close to presence or absence
Diat_Csocialis

Diatom Chaetoceros socialis

number/liter; close to presence or absence
Diat_Chaetoceros

Diatom Chaetoceros

number/liter; close to presence or absence
Diatomchain

Diatom chains

number/liter; close to presence or absence
Cyclopoid_uid

unidentified Cyclopoids

number/liter; close to presence or absence
Ctenophore

Ctenophores

number/liter; close to presence or absence
Polychaete

Polychaetes

number/liter; close to presence or absence
Unidentified

Unidentified objects

number/liter; close to presence or absence
Centropages

Centropages species

number/liter; close to presence or absence
Oithona

Oithona species

number/liter; close to presence or absence
Phytoplankton

Phytoplankton taxa

number/liter; close to presence or absence


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Instruments

Dataset-specific Instrument Name
Video Plankton Recorder
Generic Instrument Name
Video Plankton Recorder
Dataset-specific Description
Video Plankton Recorder, a towed vehicle. The Video Plankton Recorder was towed at 2 m/s, collecting data from the surface to the bottom (towyo). The VPR was equipped with 2-4 cameras, temperature and conductivity probes, fluorometer and transmissometer. Environmental data was collected at 0.25 Hz (CI9407) or 0.5 Hz (EN259, EN262). Video images were recorded at 60 fields per second (fps).
Generic Instrument Description
The Video Plankton Recorder (VPR) is a video-microscope system used for imaging plankton and other particulate matter in the size range from a few micrometers to several centimeters. The VPR is essentially an underwater microscope. It consists of four video cameras (with magnifying optics) synchronized at 60 fields per second (fps) to a red-filtered 80 W xenon strobe (pulse duration = 1 microsecond). The current lens on each camera can be adjusted to provide a field of view between 5 mm and 10 cm. Use of higher magnification lenses is currently being explored for viewing protozoans (less than 1 micrometer resolution). The four cameras are set for concentric viewing fields so that a range of up to four magnifications can be viewed simultaneously, allowing a wide size range of plankton to be sampled. Depth of field is adjusted by the lens aperture setting, and the volume sampled in each video field ranges from about 1 ml to 1 liter, depending on lens settings. The cameras have been configured for stereoscopic viewing as well.A strobe on the other arm illuminates the imaged volume and flashes 60 times per second, producing 60 images per second of the particles and plankton in the water. The images are then saved internally on a computer hard disk and later plotted. Deployment: Most commonly, the VPR is mounted in a frame and lowered into the water from the stern of the ship. Sometimes, a CTD also is mounted next to the VPR to collect depth, temperature, and salinity information at the same time as each video image. The instrument is lowered down through the water to a maximum depth of 350 meters to generate a profile of plankton/particle abundance and taxon group along with temperature and salinity. In addition to the towed configuration for mapping plankton distributions, it is possible to deploy the VPR in a fixed position (on a mooring) for viewing plankton swimming behaviors in two or three dimensions. The VPR instrument system has been used in both configurations, and deployment on ROVs has been proposed. This definition was taken from the WHOI Ocean Instruments Web site and from a US GLOBEC Newsletter.


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Deployments

CI9407

Website
Platform
R/V Columbus Iselin
Report
Start Date
1994-05-25
End Date
1994-06-16
Description
process zoology

Methods & Sampling
The Video Plankton Recorder was towed at 2 m/s, collecting data from the surface to the bottom (towyo). The VPR was equipped with 2-4 cameras, temperature and conductivity probes, fluorometer and transmissometer. Environmental data was collected at 0.25 Hz (CI9407) or 0.5 Hz (EN259, EN262). Video images were recorded at 60 fields per second (fps).

Processing Description
Video tapes were analyzed for plankton abundances using a semi-automated method discussed in Davis, C.S. et al., Deep-Sea Research II 43 (1996) 1946-1970. In-focus images were extracted from the video tapes and identified by hand to particle type, taxon, or species. Plankton and particle observations were merged with environmental and navigational data by binning the observations for each category into the time intervals at which the environmental data were collected (again see above Davis citation). Concentrations were calculated utilizing the total volume (liters) imaged during that period. For less-abundant categories, usually only a single organism was observed during each time interval so that the resulting concentrations are close to presence or absence data rather than covering a range of values.

EN259

Website
Platform
R/V Endeavor
Report
Start Date
1995-01-10
End Date
1995-01-22
Description
process zoology

Methods & Sampling
The Video Plankton Recorder was towed at 2 m/s, collecting data from the surface to the bottom (towyo). The VPR was equipped with 2-4 cameras, temperature and conductivity probes, fluorometer and transmissometer. Environmental data was collected at 0.25 Hz (CI9407) or 0.5 Hz (EN259, EN262). Video images were recorded at 60 fields per second (fps).

Processing Description
Video tapes were analyzed for plankton abundances using a semi-automated method discussed in Davis, C.S. et al., Deep-Sea Research II 43 (1996) 1946-1970. In-focus images were extracted from the video tapes and identified by hand to particle type, taxon, or species. Plankton and particle observations were merged with environmental and navigational data by binning the observations for each category into the time intervals at which the environmental data were collected (again see above Davis citation). Concentrations were calculated utilizing the total volume (liters) imaged during that period. For less-abundant categories, usually only a single organism was observed during each time interval so that the resulting concentrations are close to presence or absence data rather than covering a range of values.

EN262

Website
Platform
R/V Endeavor
Report
Start Date
1995-02-23
End Date
1995-03-10
Description
process zoology

Methods & Sampling
The Video Plankton Recorder was towed at 2 m/s, collecting data from the surface to the bottom (towyo). The VPR was equipped with 2-4 cameras, temperature and conductivity probes, fluorometer and transmissometer. Environmental data was collected at 0.25 Hz (CI9407) or 0.5 Hz (EN259, EN262). Video images were recorded at 60 fields per second (fps).

Processing Description
Video tapes were analyzed for plankton abundances using a semi-automated method discussed in Davis, C.S. et al., Deep-Sea Research II 43 (1996) 1946-1970. In-focus images were extracted from the video tapes and identified by hand to particle type, taxon, or species. Plankton and particle observations were merged with environmental and navigational data by binning the observations for each category into the time intervals at which the environmental data were collected (again see above Davis citation). Concentrations were calculated utilizing the total volume (liters) imaged during that period. For less-abundant categories, usually only a single organism was observed during each time interval so that the resulting concentrations are close to presence or absence data rather than covering a range of values.


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Project Information

U.S. GLOBEC Georges Bank (GB)


Coverage: Georges Bank, Gulf of Maine, Northwest Atlantic Ocean


The U.S. GLOBEC Georges Bank Program is a large multi- disciplinary multi-year oceanographic effort. The proximate goal is to understand the population dynamics of key species on the Bank - Cod, Haddock, and two species of zooplankton (Calanus finmarchicus and Pseudocalanus) - in terms of their coupling to the physical environment and in terms of their predators and prey. The ultimate goal is to be able to predict changes in the distribution and abundance of these species as a result of changes in their physical and biotic environment as well as to anticipate how their populations might respond to climate change.

The effort is substantial, requiring broad-scale surveys of the entire Bank, and process studies which focus both on the links between the target species and their physical environment, and the determination of fundamental aspects of these species' life history (birth rates, growth rates, death rates, etc).

Equally important are the modelling efforts that are ongoing which seek to provide realistic predictions of the flow field and which utilize the life history information to produce an integrated view of the dynamics of the populations.

The U.S. GLOBEC Georges Bank Executive Committee (EXCO) provides program leadership and effective communication with the funding agencies.



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Program Information

U.S. GLOBal ocean ECosystems dynamics (U.S. GLOBEC)


Coverage: Global


U.S. GLOBEC (GLOBal ocean ECosystems dynamics) is a research program organized by oceanographers and fisheries scientists to address the question of how global climate change may affect the abundance and production of animals in the sea.

The U.S. GLOBEC Program currently had major research efforts underway in the Georges Bank / Northwest Atlantic Region, and the Northeast Pacific (with components in the California Current and in the Coastal Gulf of Alaska). U.S. GLOBEC was a major contributor to International GLOBEC efforts in the Southern Ocean and Western Antarctic Peninsula (WAP).



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Funding

Funding SourceAward
National Science Foundation (NSF)
National Oceanic and Atmospheric Administration (NOAA)

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