Churchill Beluga Boat Drone Imagery

Aerial imagery surveys are commonly used in marine mammal research to determine population size, habitat distribution and habitat use. Analysis of aerial photos involves hours of manually identifying individuals present in each image and converting raw counts into useable biological statistics. Our...

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Bibliographic Details
Format:	Dataset
Language:	unknown
Published:	Canadian Watershed Information Network (CanWIN) 2022
Subjects:	Beluga Unmanned Aerial Vehicle kayak boat AERIAL PHOTOGRAPHS video Churchill estuary Kayak Beluga*
Online Access:	https://search.dataone.org/view/sha256:2d723b77e9f300ec35c0386fd68fe718b44605726a87f9a22f63d6ee44b7bc03

id	dataone:sha256:2d723b77e9f300ec35c0386fd68fe718b44605726a87f9a22f63d6ee44b7bc03
record_format	openpolar
spelling	dataone:sha256:2d723b77e9f300ec35c0386fd68fe718b44605726a87f9a22f63d6ee44b7bc03 2024-11-03T19:45:10+00:00 Churchill Beluga Boat Drone Imagery 2022-01-01T00:00:00Z https://search.dataone.org/view/sha256:2d723b77e9f300ec35c0386fd68fe718b44605726a87f9a22f63d6ee44b7bc03 unknown Canadian Watershed Information Network (CanWIN) Beluga Unmanned Aerial Vehicle kayak boat AERIAL PHOTOGRAPHS video Churchill estuary Dataset 2022 dataone:urn:node:CANWIN 2024-11-03T19:18:20Z Aerial imagery surveys are commonly used in marine mammal research to determine population size, habitat distribution and habitat use. Analysis of aerial photos involves hours of manually identifying individuals present in each image and converting raw counts into useable biological statistics. Our research proposes the use of deep learning algorithms as an assistive technology to increase the efficiency of the marine mammal research workflow. To test the feasibility of this proposal, the existing YOLOv4 convolutional neural network model was trained to detect belugas, kayaks and motorized boats in unmanned aerial vehicle (UAV) imagery. Computer-based object detection achieved an average precision of 61.17% for belugas, 98.58% for boats, and 95.97% for kayaks. We then tested the performance of computer vision tracking of belugas and manned watercraft in UAV videos using the DeepSORT tracking algorithm, achieving a multiple object tracking accuracy (MOTA) ranging from 37% – 88% and multiple object tracking precision (MOTP) between 63% – 86%. Results from this research indicate that deep learning technology can perform at a similar caliber as human annotators in beluga and watercraft detection and tracking, allowing for larger datasets to be processed within a fraction of the time. Dataset Beluga Beluga* Canadian Watershed Information Network (CanWIN) (via DataONE) Kayak ENVELOPE(103.217,103.217,71.533,71.533)
institution	Open Polar
collection	Canadian Watershed Information Network (CanWIN) (via DataONE)
op_collection_id	dataone:urn:node:CANWIN
language	unknown
topic	Beluga Unmanned Aerial Vehicle kayak boat AERIAL PHOTOGRAPHS video Churchill estuary
spellingShingle	Beluga Unmanned Aerial Vehicle kayak boat AERIAL PHOTOGRAPHS video Churchill estuary Churchill Beluga Boat Drone Imagery
topic_facet	Beluga Unmanned Aerial Vehicle kayak boat AERIAL PHOTOGRAPHS video Churchill estuary
description	Aerial imagery surveys are commonly used in marine mammal research to determine population size, habitat distribution and habitat use. Analysis of aerial photos involves hours of manually identifying individuals present in each image and converting raw counts into useable biological statistics. Our research proposes the use of deep learning algorithms as an assistive technology to increase the efficiency of the marine mammal research workflow. To test the feasibility of this proposal, the existing YOLOv4 convolutional neural network model was trained to detect belugas, kayaks and motorized boats in unmanned aerial vehicle (UAV) imagery. Computer-based object detection achieved an average precision of 61.17% for belugas, 98.58% for boats, and 95.97% for kayaks. We then tested the performance of computer vision tracking of belugas and manned watercraft in UAV videos using the DeepSORT tracking algorithm, achieving a multiple object tracking accuracy (MOTA) ranging from 37% – 88% and multiple object tracking precision (MOTP) between 63% – 86%. Results from this research indicate that deep learning technology can perform at a similar caliber as human annotators in beluga and watercraft detection and tracking, allowing for larger datasets to be processed within a fraction of the time.
format	Dataset
title	Churchill Beluga Boat Drone Imagery
title_short	Churchill Beluga Boat Drone Imagery
title_full	Churchill Beluga Boat Drone Imagery
title_fullStr	Churchill Beluga Boat Drone Imagery
title_full_unstemmed	Churchill Beluga Boat Drone Imagery
title_sort	churchill beluga boat drone imagery
publisher	Canadian Watershed Information Network (CanWIN)
publishDate	2022
url	https://search.dataone.org/view/sha256:2d723b77e9f300ec35c0386fd68fe718b44605726a87f9a22f63d6ee44b7bc03
long_lat	ENVELOPE(103.217,103.217,71.533,71.533)
geographic	Kayak
geographic_facet	Kayak
genre	Beluga Beluga*
genre_facet	Beluga Beluga*
_version_	1814735282149261312

Churchill Beluga Boat Drone Imagery

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