Contributors | Affiliation | Role |
---|---|---|
Keister, Julie E. | University of Washington (UW) | Principal Investigator, Contact |
Grunbaum, Daniel | University of Washington (UW) | Co-Principal Investigator |
Crouser, Deana | National Oceanic and Atmospheric Administration - Alaska Fisheries Science Center (NOAA-AFSC) | Student |
Wyeth, Amy | University of Washington (UW) | Student |
Newman, Sawyer | Woods Hole Oceanographic Institution (WHOI BCO-DMO) | BCO-DMO Data Manager |
Image Directory Category Descriptions
Gelatinous:
Lobata:
Copepoda:
Amphipoda:
Phytoplankton:
Other:
These images were collected by the SPC-UW-Zoocam, which is an underwater imaging system that was mounted on a profiling mooring. Images were collected during profiling of the mooring at depths between 5 - 110 meters.
Image data processing (Region of Interest (ROI) selection) was conducted internally, with processed and compressed images streamed to shore over cellular networks.
Image processing
Images were visually (manually) identified for taxonomy and sorted into folders. In this dataset, some images were duplicated and rotated to create an augmented dataset to train a Machine Learning algorithm (labeled as “augmented” in each file name).
Images that are too blurry to confidently classify are stored within the "Unknown" folder in the zipped image directory file.
Image File Naming Convention
File name example: SPC-UW-1534792542343244-337276376507-004392-154-2546-848-756-780.png
SPC: Scripps Plankton Camera
UW: University of Washington
1534792542343244: Unix Date/Timestamp [To convert to UTC, use (X / 86400) + 25569.]
337276376507: Directory and subdirectory extension specific to this directory organization system.
154-2546-848-756-780: ROI (Region of Interest) details (x, y, w, h, image size)
Processing for Reuse
This dataset needs to undergo pre-processing steps (i.e., image augmentation and balancing) before it should be used to train an algorithm for best results.
- Latitude and longitude values added to the data file
- augmented_image_flag column added to indicate if an image file has gone through augmentation
- A human readable datetime column was created from the unix_datetimestamp value present in the filename
- roi_x, roi_y, roi_h, and roi_image_size columns added from the image file name; this was parsed from the image file name
Parameter | Description | Units |
filename | Filename of an individual zooplankton image, i.e., region of interest (ROI) | unitless |
relative_filepath | Relative directory path where the "filename" image is stored within the zip file, SPC-UW-ZooCam_Training_Photos.zip | unitless |
filesize_bytes | Image file size | bytes |
md5sum | Image file md5sum value | unitless |
latitude | Latitude of mooring location where the ZooCam camera was deployed and the image file was collected in decimal degrees; a positive value indicates a Northern coordinate | decimal degrees |
longitude | Longitude of mooring location where the ZooCam camera was deployed and the image file was collected in decimal degrees; a negative value indicates a Western coordinate | decimal degrees |
augmented_image_flag | A "augmented_image" value indicates that an image was duplicated and rotated to create an augmented dataset; blank data values in this column indicate that an image was not augmented | unitless |
datetime_utc | Datetime value derived from the unix timestamp represented in the image filename. | unitless |
roi_x | ROI (region of interest) x value of image file | image_analysis |
roi_y | ROI (region of interest) y value of image file | image_analysis |
roi_w | ROI (region of interest) w value of image file | image_analysis |
roi_h | ROI (region of interest) h value of image file | image_analysis |
roi_image_size | ROI (region of interest) image size | pixels |
Dataset-specific Instrument Name | SPC-UW-Zoocam |
Generic Instrument Name | Underwater Camera |
Dataset-specific Description | The SPC-UW-Zoocam designed and built specifically for this project. The Zoocam was custom-built by Paul Roberts in the Jaffe Imaging Laboratory at the University of California San Diego. It is an underwater camera system that captured still images of zooplankton within a 500-mL imaged area using lighting in the visible wavelength range. |
Generic Instrument Description | All types of photographic equipment that may be deployed underwater including stills, video, film and digital systems. |
Website | |
Platform | ORCA-UW-Hoodsport |
Start Date | 2018-06-26 |
End Date | 2018-10-24 |
Description | A University of Washington SPC-2 Zoocam was deployed on UW/APL Hoodsport, Hood Canal ORCA buoy. |
NSF Award Abstract:
Low oxygen (hypoxia) and low pH are known to have profound physiological effects on zooplankton, the microscopic animals of the sea. It is likely that many individual zooplankton change vertical mirgration behaviors to reduce or avoid these stresses. However, avoidance responses and their consequences for zooplankton distributions, and for interactions of zooplankton with their predators and prey, are poorly understood. This study will provide information on small-scale behavioral responses of zooplankton to oxygen and pH using video systems deployed in the field in a seasonally hypoxic estuary. The results will deepen our understanding of how zooplankton respond to low oxygen and pH conditions in ways that could profoundly affect marine ecosystems and fisheries through changes in their populations and distributions. This project will train graduate students and will engage K-12 students and teachers in under-served coastal communities by developing ocean technology-based citizen-scientist activities and curricular materials in plankton ecology, ocean change, construction and use of biological sensors, and quantitative analysis of environmental data.
Individual directional motility is a primary mechanism underlying spatio-temporal patterns in zooplankton population distributions. Motility is used by most zooplankton species to select among water column positions that differ in biotic and abiotic variables such as prey, predators, light, oxygen concentration, and pH. Species-specific movement responses to de-oxygenation and acidification are likely mechanisms through which short-term, localized impacts of these stressful conditions on individual zooplankton will be magnified or suppressed as they propagate up to population, community, and ecosystem-level dynamics. This study will quantify responses by key zooplankton species to oxygen and pH using in situ video systems to measure changes in individual behavior in hypoxic, low- pH versus well-oxygenated, high-pH regions of a seasonally hypoxic estuary. Distributions and movements of zooplankton will be quantified using three approaches: 1) an imaging system deployed in situ on a profiling mooring over two summers in a hypoxic region, 2) imagers deployed on Lagrangian drifters to sample simultaneously throughout the water column, and 3) vertically-stratified pumps and net tows to verify species identification and video-based abundance estimates. These field observations will be combined with laboratory analysis of zooplankton movements in oxygen and pH gradients, and with spatially-explicit models to predict how behavioral mechanisms lead to large-scale impacts of environmental stresses.
The following deployments were conducted in 2017 and 2018:
CB1077: https://www.bco-dmo.org/deployment/735746
CB1072: https://www.bco-dmo.org/deployment/735748
Zoocam_ORCA_Twanoh_2017: https://www.bco-dmo.org/deployment/735762
RC0008: https://www.bco-dmo.org/deployment/775288
Mooring ORCA_Hoodsport; NANOOS-APL4: https://www.bco-dmo.org/deployment/775291
Funding Source | Award |
---|---|
NSF Division of Ocean Sciences (NSF OCE) |