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On April 7, 2022 at 2:50:12 PM CDT, Casey Clair:
Updated description of Detection and tracking of belugas, kayaks and motorized boats in drone video using deep learning from
"Aerial imagery surveys are commonly used in marine mammal research to determine population size, 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 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 oblique drone imagery, collected from a stationary tethered system. Automated computer-based object detection achieved the following precision and recall, respectively, for each class: beluga = 74%/72%; boat = 97%/99%; and kayak = 96%/96%. We then tested the performance of computer vision tracking of belugas and occupied watercraft in drone videos using the DeepSORT tracking algorithm, which achieved a multiple-object tracking accuracy (MOTA) ranging from 37% to 88% and multiple object tracking precision (MOTP) between 63% and 86%. Results from this research indicate that deep learning technology can detect and track features more consistently than human annotators, allowing for larger datasets to be processed within a fraction of the time while avoiding discrepancies introduced by labeling fatigue or multiple human annotators."
to
Aerial imagery surveys are commonly used in marine mammal research to determine population size, 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 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 oblique drone imagery, collected from a stationary tethered system. Automated computer-based object detection achieved the following precision and recall, respectively, for each class: beluga = 74%/72%; boat = 97%/99%; and kayak = 96%/96%. We then tested the performance of computer vision tracking of belugas and occupied watercraft in drone videos using the DeepSORT tracking algorithm, which achieved a multiple-object tracking accuracy (MOTA) ranging from 37% to 88% and multiple object tracking precision (MOTP) between 63% and 86%. Results from this research indicate that deep learning technology can detect and track features more consistently than human annotators, allowing for larger datasets to be processed within a fraction of the time while avoiding discrepancies introduced by labeling fatigue or multiple human annotators.
Changed value of field keywords to Unmanned Aerial Vehicle,beluga,computer vision,deep learning,object detection,object tracking in Detection and tracking of belugas, kayaks and motorized boats in drone video using deep learning
              
    
          
          
        
        
            f 1 { f 1 {
            2   "Author": [ 2   "Author": [
            3     { 3     {
            4       "affiliation": "Centre for Earth Observation Science -  4       "affiliation": "Centre for Earth Observation Science - 
            5 University of Manitoba", 5 University of Manitoba",
            6       "creatorName": "Harasyn, Madison", 6       "creatorName": "Harasyn, Madison",
            7       "email": "Madison.harasyn@umanitoba.ca", 7       "email": "Madison.harasyn@umanitoba.ca",
            8       "nameIdentifier": "https://orcid.org/0000-0002-5741-6766", 8       "nameIdentifier": "https://orcid.org/0000-0002-5741-6766",
            9       "nameIdentifierScheme": "ORCID", 9       "nameIdentifierScheme": "ORCID",
            10       "nameType": "Personal", 10       "nameType": "Personal",
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            12     }, 12     },
            13     { 13     {
            14       "affiliation": "Centre for Earth Observation Science -  14       "affiliation": "Centre for Earth Observation Science - 
            15 University of Manitoba", 15 University of Manitoba",
            16       "creatorName": "Chan, Wayne", 16       "creatorName": "Chan, Wayne",
            17       "email": "wayne.chan@umanitoba.ca", 17       "email": "wayne.chan@umanitoba.ca",
            18       "nameIdentifier": "", 18       "nameIdentifier": "",
            19       "nameType": "Personal" 19       "nameType": "Personal"
            20     }, 20     },
            21     { 21     {
            22       "affiliation": "Centre for Earth Observation Science -  22       "affiliation": "Centre for Earth Observation Science - 
            23 University of Manitoba", 23 University of Manitoba",
            24       "creatorName": "Ausen, Emma", 24       "creatorName": "Ausen, Emma",
            25       "email": "emma.ausen@umanitoba.ca", 25       "email": "emma.ausen@umanitoba.ca",
            26       "nameIdentifier": "", 26       "nameIdentifier": "",
            27       "nameType": "Personal" 27       "nameType": "Personal"
            28     }, 28     },
            29     { 29     {
            30       "affiliation": "Centre for Earth Observation Science -  30       "affiliation": "Centre for Earth Observation Science - 
            31 University of Manitoba", 31 University of Manitoba",
            32       "creatorName": "Barber, David", 32       "creatorName": "Barber, David",
            33       "email": "david.barber@umanitoba.ca", 33       "email": "david.barber@umanitoba.ca",
            34       "nameIdentifier": "0000-0001-9466-3291", 34       "nameIdentifier": "0000-0001-9466-3291",
            35       "nameIdentifierScheme": "ORCID", 35       "nameIdentifierScheme": "ORCID",
            36       "nameType": "Personal", 36       "nameType": "Personal",
            37       "schemeURI": "http://orcid.org/" 37       "schemeURI": "http://orcid.org/"
            38     } 38     }
            39   ], 39   ],
            40   "Identifier": "10.1139/juvs-2021-0024", 40   "Identifier": "10.1139/juvs-2021-0024",
            41   "PublicationYear": "2022", 41   "PublicationYear": "2022",
            42   "Publisher": "Drone Systems and Applications", 42   "Publisher": "Drone Systems and Applications",
            43   "ResourceType": "journal article", 43   "ResourceType": "journal article",
            44   "Rights": "Creative Commons Attribution 4.0 International", 44   "Rights": "Creative Commons Attribution 4.0 International",
            45   "Version": "1.0", 45   "Version": "1.0",
            46   "author": null, 46   "author": null,
            47   "author_email": null, 47   "author_email": null,
            48   "awardTitle": "The Canada Excellence Research Chair (CERC) and the  48   "awardTitle": "The Canada Excellence Research Chair (CERC) and the 
            49 Canada Research Chair (CRC programs)", 49 Canada Research Chair (CRC programs)",
            50   "awardURI": "https://www.cerc.gc.ca/", 50   "awardURI": "https://www.cerc.gc.ca/",
            51   "citation": "Madison L.Harasyn, Wayne S.Chan, Emma L.Ausen, and  51   "citation": "Madison L.Harasyn, Wayne S.Chan, Emma L.Ausen, and 
            52 David G.Barber. Detection and tracking of belugas, kayaks and  52 David G.Barber. Detection and tracking of belugas, kayaks and 
            53 motorized boats in drone video using deep learning. Drone Systems and  53 motorized boats in drone video using deep learning. Drone Systems and 
            54 Applications. 10(1): 77-96. https://doi.org/10.1139/juvs-2021-0024", 54 Applications. 10(1): 77-96. https://doi.org/10.1139/juvs-2021-0024",
            55   "creator_user_id": "cde7b848-a882-4fc7-97c9-670417bd6b43", 55   "creator_user_id": "cde7b848-a882-4fc7-97c9-670417bd6b43",
            56   "descriptionType": "Abstract", 56   "descriptionType": "Abstract",
            57   "funderIdentifier": "", 57   "funderIdentifier": "",
            58   "funderIdentifierType": "", 58   "funderIdentifierType": "",
            59   "funderName": "", 59   "funderName": "",
            60   "funderSchemeURI": "", 60   "funderSchemeURI": "",
            61   "grantNumber": "", 61   "grantNumber": "",
            n 62   "groups": [ n 62   "groups": [],
            63     { 
            64       "description": "Inland water features, drainage systems and  
            65 their characteristics. Examples of data you can find here include  
            66 river and lake data, water quality data. \r\n\r\nIn CEOS, related  
            67 research themes include biogeochemistry, Inland lakes and waters,  
            68 modelling, remote sensing and technology, trace metals and  
            69 contaminants.", 
            70       "display_name": "Freshwater", 
            71       "id": "8f8cd877-b037-4b1a-b928-f86d9e093741", 
            72       "image_display_url":  
            73 /data/uploads/group/2021-10-31-211937.658599hyinspirehydrography.svg", 
            74       "name": "freshwater", 
            75       "title": "Freshwater" 
            76     }, 
            77     { 
            78       "description": "Features and characteristics of salt water  
            79 bodies.\r\n\r\nIn CEOS, related research themes include  
            80 biogeochemistry, modelling, marine mammals, oil spill response,  
            81 physical oceanography, remote sensing and technology and trace metals  
            82 and contaminants", 
            83       "display_name": "Marine", 
            84       "id": "98238b1c-5be8-41ad-8c6e-74cdc4f5f369", 
            85       "image_display_url":  
            86 ata/uploads/group/2021-10-31-211516.365746ofinspireoceanographic.svg", 
            87       "name": "marine", 
            88       "title": "Marine" 
            89     } 
            90   ], 
            91   "id": "54b0d7a1-8536-4d40-b1bb-daad81805f43", 63   "id": "54b0d7a1-8536-4d40-b1bb-daad81805f43",
            92   "isopen": false, 64   "isopen": false,
            n 93   "keywords": "computer vision,deep learning,Unmanned Aerial  n 65   "keywords": "Unmanned Aerial Vehicle,beluga,computer vision,deep 
            94 Vehicle,beluga,object detection,object tracking", 66 learning,object detection,object tracking",
            95   "language": "English", 67   "language": "English",
            96   "licenceType": "Open", 68   "licenceType": "Open",
            97   "license_id": null, 69   "license_id": null,
            98   "license_title": null, 70   "license_title": null,
            99   "maintainer": null, 71   "maintainer": null,
            100   "maintainer_email": null, 72   "maintainer_email": null,
            101   "metadata_created": "2022-04-07T19:45:13.021227", 73   "metadata_created": "2022-04-07T19:45:13.021227",
            n 102   "metadata_modified": "2022-04-07T19:49:14.245866", n 74   "metadata_modified": "2022-04-07T19:50:12.725300",
            103   "name":  75   "name": 
            104 elugas-kayaks-and-motorized-boats-in-drone-video-using-deep-learning", 76 elugas-kayaks-and-motorized-boats-in-drone-video-using-deep-learning",
            n 105   "notes": "\"Aerial imagery surveys are commonly used in marine  n 77   "notes": "Aerial imagery surveys are commonly used in marine mammal 
            106 mammal research to determine population size, distribution and habitat  78 research to determine population size, distribution and habitat use. 
            107 use. Analysis of aerial photos involves hours of manually identifying  79 Analysis of aerial photos involves hours of manually identifying 
            108 individuals present in each image and converting raw counts into  80 individuals present in each image and converting raw counts into 
            109 useable biological statistics. Our research proposes the use of deep  81 useable biological statistics. Our research proposes the use of deep 
            110 learning algorithms to increase the efficiency of the marine mammal  82 learning algorithms to increase the efficiency of the marine mammal 
            111 research workflow. To test the feasibility of this proposal, the  83 research workflow. To test the feasibility of this proposal, the 
            112 existing YOLOv4 convolutional neural network model was trained to  84 existing YOLOv4 convolutional neural network model was trained to 
            113 detect belugas, kayaks and motorized boats in oblique drone imagery,  85 detect belugas, kayaks and motorized boats in oblique drone imagery, 
            114 collected from a stationary tethered system. Automated computer-based  86 collected from a stationary tethered system. Automated computer-based 
            115 object detection achieved the following precision and recall,  87 object detection achieved the following precision and recall, 
            116 respectively, for each class: beluga = 74%/72%; boat = 97%/99%; and  88 respectively, for each class: beluga = 74%/72%; boat = 97%/99%; and 
            117 kayak = 96%/96%. We then tested the performance of computer vision  89 kayak = 96%/96%. We then tested the performance of computer vision 
            118 tracking of belugas and occupied watercraft in drone videos using the  90 tracking of belugas and occupied watercraft in drone videos using the 
            119 DeepSORT tracking algorithm, which achieved a multiple-object tracking  91 DeepSORT tracking algorithm, which achieved a multiple-object tracking 
            120 accuracy (MOTA) ranging from 37% to 88% and multiple object tracking  92 accuracy (MOTA) ranging from 37% to 88% and multiple object tracking 
            121 precision (MOTP) between 63% and 86%. Results from this research  93 precision (MOTP) between 63% and 86%. Results from this research 
            122 indicate that deep learning technology can detect and track features  94 indicate that deep learning technology can detect and track features 
            123 more consistently than human annotators, allowing for larger datasets  95 more consistently than human annotators, allowing for larger datasets 
            124 to be processed within a fraction of the time while avoiding  96 to be processed within a fraction of the time while avoiding 
            125 discrepancies introduced by labeling fatigue or multiple human  97 discrepancies introduced by labeling fatigue or multiple human 
            t 126 annotators.\"", t 98 annotators.",
            127   "num_resources": 1, 99   "num_resources": 1,
            128   "num_tags": 6, 100   "num_tags": 6,
            129   "organization": { 101   "organization": {
            130     "approval_status": "approved", 102     "approval_status": "approved",
            131     "created": "2017-07-21T13:15:49.935872", 103     "created": "2017-07-21T13:15:49.935872",
            132     "description": "The Centre for Earth Observation Science (CEOS)  104     "description": "The Centre for Earth Observation Science (CEOS) 
            133 was established in 1994 with a mandate to research, preserve and  105 was established in 1994 with a mandate to research, preserve and 
            134 communicate knowledge of Earth system processes using the technologies  106 communicate knowledge of Earth system processes using the technologies 
            135 of Earth Observation Science. Research is multidisciplinary and  107 of Earth Observation Science. Research is multidisciplinary and 
            136 collaborative seeking to understand the complex interrelationships  108 collaborative seeking to understand the complex interrelationships 
            137 between elements of Earth systems, and how these systems will likely  109 between elements of Earth systems, and how these systems will likely 
            138 respond to climate change. Although researchers have worked in many  110 respond to climate change. Although researchers have worked in many 
            139 regions, the Arctic marine system has always been a unifying focus of  111 regions, the Arctic marine system has always been a unifying focus of 
            140 activity.\r\n\r\nIn 2012, CEOS, along with the Greenland Climate  112 activity.\r\n\r\nIn 2012, CEOS, along with the Greenland Climate 
            141 Research Centre (GCRC, Nuuk, Greenland) and the Arctic Research Centre  113 Research Centre (GCRC, Nuuk, Greenland) and the Arctic Research Centre 
            142 (ARC, Aarhus, Denmark) established the Arctic Science Partnership,  114 (ARC, Aarhus, Denmark) established the Arctic Science Partnership, 
            143 thereby integrating academic and research initiatives.\r\n\r\nAreas of  115 thereby integrating academic and research initiatives.\r\n\r\nAreas of 
            144 existing research activity are divided among key themes:\r\n\r\nArctic  116 existing research activity are divided among key themes:\r\n\r\nArctic 
            145 Anthropology/Paleoclimatology: LiDAR scanning and digital site  117 Anthropology/Paleoclimatology: LiDAR scanning and digital site 
            146 preservation, archaeo-geophysics, permafrost degredation, lithic  118 preservation, archaeo-geophysics, permafrost degredation, lithic 
            147 morphometrics, zooarchaeology, proxy studies, paleodistribution of sea  119 morphometrics, zooarchaeology, proxy studies, paleodistribution of sea 
            148 ice, landscape learning, Paleo-Eskimo culture, Thule Inuit culture,  120 ice, landscape learning, Paleo-Eskimo culture, Thule Inuit culture, 
            149 ethnographic analogy, traditional knowledge, climate change and  121 ethnographic analogy, traditional knowledge, climate change and 
            150 northern heritage resource management.\r\n\r\nAtmospheric  122 northern heritage resource management.\r\n\r\nAtmospheric 
            151 Studies/Meteorology: Boundary layer, precipitation, clouds, storms and  123 Studies/Meteorology: Boundary layer, precipitation, clouds, storms and 
            152 extreme weather, circulation, eddy correlations, polar vortex,  124 extreme weather, circulation, eddy correlations, polar vortex, 
            153 climate, teleconnections, geophysical fluid dynamics, flux and energy  125 climate, teleconnections, geophysical fluid dynamics, flux and energy 
            154 budgets, ocean-sea ice-atmosphere interface, radiative transfer, ice  126 budgets, ocean-sea ice-atmosphere interface, radiative transfer, ice 
            155 albedo feedback, cloud radiative forcing, pCO2.  127 albedo feedback, cloud radiative forcing, pCO2. 
            156 \r\n\r\nBiogeochemistry: Organic carbon, greenhouse gases, bubbles,  128 \r\n\r\nBiogeochemistry: Organic carbon, greenhouse gases, bubbles, 
            157 Ikaite, carbonate chemistry, CO2 fluxes, mercury and other trace  129 Ikaite, carbonate chemistry, CO2 fluxes, mercury and other trace 
            158 metals, minerals, hydrocarbons, brine processes, otolith  130 metals, minerals, hydrocarbons, brine processes, otolith 
            159 microchemistry, sediments, biomarkers. \r\n\r\nContaminants: Mercury,  131 microchemistry, sediments, biomarkers. \r\n\r\nContaminants: Mercury, 
            160 trace metals, PAHs, source, transport, transformation, pathways,  132 trace metals, PAHs, source, transport, transformation, pathways, 
            161 bioaccumulations, marine ecosystems, marine chemistry. \r\nEarth  133 bioaccumulations, marine ecosystems, marine chemistry. \r\nEarth 
            162 Observation Science: Active and passive microwave, LiDAR, EM  134 Observation Science: Active and passive microwave, LiDAR, EM 
            163 induction, spatial-temporal analysis, forward and inverse scattering  135 induction, spatial-temporal analysis, forward and inverse scattering 
            164 models, complex permittivity, ocean colour, ocean surface roughness,  136 models, complex permittivity, ocean colour, ocean surface roughness, 
            165 NIR, TIR, satellite telemetry, GPS. Ice-Associated Biology:  137 NIR, TIR, satellite telemetry, GPS. Ice-Associated Biology: 
            166 Biophysical processes, primary production; ice algae, ice  138 Biophysical processes, primary production; ice algae, ice 
            167 microbiology, bio-optics, under-ice phytoplankton. \r\n\r\nInland  139 microbiology, bio-optics, under-ice phytoplankton. \r\n\r\nInland 
            168 Lakes and Waters: Hydrologic connectivity, watershed systems, sediment  140 Lakes and Waters: Hydrologic connectivity, watershed systems, sediment 
            169 transport, nutrient transport, contaminants, landscape processes,  141 transport, nutrient transport, contaminants, landscape processes, 
            170 remote sensing, freshwater-marine coupling. Marine Mammals: Seals,  142 remote sensing, freshwater-marine coupling. Marine Mammals: Seals, 
            171 whales, habitat, conservation, satellite telemetry, distribution,  143 whales, habitat, conservation, satellite telemetry, distribution, 
            172 population studies, prey behaviour, bioacoustics.\r\n\r\nModelling:  144 population studies, prey behaviour, bioacoustics.\r\n\r\nModelling: 
            173 Simulation of sea ice and oceanic regional processes, Nucleus for  145 Simulation of sea ice and oceanic regional processes, Nucleus for 
            174 European Modelling of the Ocean (NEMO), ice-ocean modelling and  146 European Modelling of the Ocean (NEMO), ice-ocean modelling and 
            175 interactions, hind cast simulations and projections for sea ice state  147 interactions, hind cast simulations and projections for sea ice state 
            176 and ocean variables based on CMIP5 scenarios and MIROC5 forcing,  148 and ocean variables based on CMIP5 scenarios and MIROC5 forcing, 
            177 validation.\r\n\r\nOceanography: Circulation, temperature, in-flow and  149 validation.\r\n\r\nOceanography: Circulation, temperature, in-flow and 
            178 out-flow shelves, water dynamics, microturbulence, Beaufort Gyre, eddy  150 out-flow shelves, water dynamics, microturbulence, Beaufort Gyre, eddy 
            179 correlations.\r\n\r\nSea Ice Geophysics:Thermodynamic and dynamic  151 correlations.\r\n\r\nSea Ice Geophysics:Thermodynamic and dynamic 
            180 processes, extreme ice features and hazards, snow, ridges,  152 processes, extreme ice features and hazards, snow, ridges, 
            181 polynyas.\r\n\r\nTraditional and Local Knowledge: Indigenous cultures,  153 polynyas.\r\n\r\nTraditional and Local Knowledge: Indigenous cultures, 
            182 Inuit, Inuvialuit, oral history, toponomy, mobility and settlement,  154 Inuit, Inuvialuit, oral history, toponomy, mobility and settlement, 
            183 hunting, food security, sea ice use, community-based research,  155 hunting, food security, sea ice use, community-based research, 
            184 community-based monitoring, two ways of knowing.", 156 community-based monitoring, two ways of knowing.",
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