Quantifying photogrammetric accuracy for measuring humpback whales using Unmanned Aerial Systems
Photogrammetry is the practice of obtaining accurate and valid measurements from 2D images. This practice can be useful in applications where it is dangerous or difficult to reach the target. In recent years, this practice is becoming more common in the marine science field to measure large and pote...
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| Format: | Master Thesis |
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2017
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| Online Access: | https://hdl.handle.net/10161/14118 |
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ftdukeunivdsp:oai:localhost:10161/14118 2023-11-12T04:06:18+01:00 Quantifying photogrammetric accuracy for measuring humpback whales using Unmanned Aerial Systems Mason, Elizabeth Johnston, David 2017-04-26 application/pdf https://hdl.handle.net/10161/14118 unknown https://hdl.handle.net/10161/14118 photogrammetry whale Unmanned Aerial Systems Master's project 2017 ftdukeunivdsp 2023-10-17T09:41:33Z Photogrammetry is the practice of obtaining accurate and valid measurements from 2D images. This practice can be useful in applications where it is dangerous or difficult to reach the target. In recent years, this practice is becoming more common in the marine science field to measure large and potentially dangerous marine mammals. Even more recently, Unmanned Aerial Systems (UAS) technology is being utilized to further minimize the dangers to humans, as well as to decrease the disturbance to animals To establish the accuracy of measurements taken from aerial imagery with UAS technology, this study calculates the distortion values from 3 different cameras, on three different UAS platforms. Lens correction values were calculated for images taken with the three cameras, a GoPro 4 Black, an Olympus E-pm2, and a Sony a5100. These lens correction values were then applied to images taken on the ground of a wooden board approximately 99.9cm long. The static ground images were taken every 10 meters up to 50 meters, to calculate the impact that distance and distortion has on the accuracy of photogrammetric measurements. Finally, each camera was attached to a different UAS platform, GoPro 4 Black with a 3D Robotics Iris+, Olympus E-pm2 with a Microcomputer HexaXL, and the Sony a5100 with a LemHex44. Images were taken at varying altitudes and were then able to be compared to the static ground images to quantify the impact that UAS has on the accuracy. The 3D Robotics Iris+ altitude measurements needed for photogrammetric calculations were derived solely from the onboard barometric sensor, while the MikroKopter and the LemHex44, altitude data were collected by an onboard barometric sensor as well as a Lightware SF11 pulse laser altimeter, thus allowing a comparison of the improved measurements obtained by using a more accurate reading of altitude. These methods were then applied to images of humpback whales (Megaptera novaeangliae) collected in the Antarctic Peninsula in January and February of 2017 with the Sony a5100. A ... Master Thesis Antarc* Antarctic Antarctic Peninsula Megaptera novaeangliae Duke University Libraries: DukeSpace Antarctic Antarctic Peninsula Olympus ENVELOPE(156.767,156.767,-80.217,-80.217) The Antarctic |
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Open Polar |
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Duke University Libraries: DukeSpace |
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ftdukeunivdsp |
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unknown |
| topic |
photogrammetry whale Unmanned Aerial Systems |
| spellingShingle |
photogrammetry whale Unmanned Aerial Systems Mason, Elizabeth Quantifying photogrammetric accuracy for measuring humpback whales using Unmanned Aerial Systems |
| topic_facet |
photogrammetry whale Unmanned Aerial Systems |
| description |
Photogrammetry is the practice of obtaining accurate and valid measurements from 2D images. This practice can be useful in applications where it is dangerous or difficult to reach the target. In recent years, this practice is becoming more common in the marine science field to measure large and potentially dangerous marine mammals. Even more recently, Unmanned Aerial Systems (UAS) technology is being utilized to further minimize the dangers to humans, as well as to decrease the disturbance to animals To establish the accuracy of measurements taken from aerial imagery with UAS technology, this study calculates the distortion values from 3 different cameras, on three different UAS platforms. Lens correction values were calculated for images taken with the three cameras, a GoPro 4 Black, an Olympus E-pm2, and a Sony a5100. These lens correction values were then applied to images taken on the ground of a wooden board approximately 99.9cm long. The static ground images were taken every 10 meters up to 50 meters, to calculate the impact that distance and distortion has on the accuracy of photogrammetric measurements. Finally, each camera was attached to a different UAS platform, GoPro 4 Black with a 3D Robotics Iris+, Olympus E-pm2 with a Microcomputer HexaXL, and the Sony a5100 with a LemHex44. Images were taken at varying altitudes and were then able to be compared to the static ground images to quantify the impact that UAS has on the accuracy. The 3D Robotics Iris+ altitude measurements needed for photogrammetric calculations were derived solely from the onboard barometric sensor, while the MikroKopter and the LemHex44, altitude data were collected by an onboard barometric sensor as well as a Lightware SF11 pulse laser altimeter, thus allowing a comparison of the improved measurements obtained by using a more accurate reading of altitude. These methods were then applied to images of humpback whales (Megaptera novaeangliae) collected in the Antarctic Peninsula in January and February of 2017 with the Sony a5100. A ... |
| author2 |
Johnston, David |
| format |
Master Thesis |
| author |
Mason, Elizabeth |
| author_facet |
Mason, Elizabeth |
| author_sort |
Mason, Elizabeth |
| title |
Quantifying photogrammetric accuracy for measuring humpback whales using Unmanned Aerial Systems |
| title_short |
Quantifying photogrammetric accuracy for measuring humpback whales using Unmanned Aerial Systems |
| title_full |
Quantifying photogrammetric accuracy for measuring humpback whales using Unmanned Aerial Systems |
| title_fullStr |
Quantifying photogrammetric accuracy for measuring humpback whales using Unmanned Aerial Systems |
| title_full_unstemmed |
Quantifying photogrammetric accuracy for measuring humpback whales using Unmanned Aerial Systems |
| title_sort |
quantifying photogrammetric accuracy for measuring humpback whales using unmanned aerial systems |
| publishDate |
2017 |
| url |
https://hdl.handle.net/10161/14118 |
| long_lat |
ENVELOPE(156.767,156.767,-80.217,-80.217) |
| geographic |
Antarctic Antarctic Peninsula Olympus The Antarctic |
| geographic_facet |
Antarctic Antarctic Peninsula Olympus The Antarctic |
| genre |
Antarc* Antarctic Antarctic Peninsula Megaptera novaeangliae |
| genre_facet |
Antarc* Antarctic Antarctic Peninsula Megaptera novaeangliae |
| op_relation |
https://hdl.handle.net/10161/14118 |
| _version_ |
1782327381437972480 |