Tracking Dynamic Northern Surface Water Changes with High-Frequency Planet CubeSat Imagery

Tracking Dynamic Northern Surface Water Changes with High-Frequency Planet CubeSat Imagery

Recent deployments of CubeSat imagers by companies such as Planet may advance hydrological remote sensing by providing an unprecedented combination of high temporal and high spatial resolution imagery at the global scale. With approximately 170 CubeSats orbiting at full operational capacity, the Pla...

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Bibliographic Details
Main Authors: Sarah W. Cooley, Laurence C. Smith, Leon Stepan, Joseph Mascaro
Format: Article
Language:English
Published: MDPI AG 2017-12-01
Series:Remote Sensing
Subjects:
Arctic hydrology
CubeSats
remote sensing of lakes and rivers
Yukon Flats
Online Access:https://www.mdpi.com/2072-4292/9/12/1306
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spelling doaj-0b8ebfeee5de4b7284b65cc9a8153da42020-11-24T22:25:29ZengMDPI AGRemote Sensing2072-42922017-12-01912130610.3390/rs9121306rs9121306Tracking Dynamic Northern Surface Water Changes with High-Frequency Planet CubeSat ImagerySarah W. Cooley0Laurence C. Smith1Leon Stepan2Joseph Mascaro3Department of Geography, University of California Los Angeles, Los Angeles, CA 90095, USADepartment of Geography, University of California Los Angeles, Los Angeles, CA 90095, USAPlanet Labs, Inc., San Francisco, CA 94103, USAPlanet Labs, Inc., San Francisco, CA 94103, USARecent deployments of CubeSat imagers by companies such as Planet may advance hydrological remote sensing by providing an unprecedented combination of high temporal and high spatial resolution imagery at the global scale. With approximately 170 CubeSats orbiting at full operational capacity, the Planet CubeSat constellation currently offers an average revisit time of <1 day for the Arctic and near-daily revisit time globally at 3 m spatial resolution. Such data have numerous potential applications for water resource monitoring, hydrologic modeling and hydrologic research. Here we evaluate Planet CubeSat imaging capabilities and potential scientific utility for surface water studies in the Yukon Flats, a large sub-Arctic wetland in north central Alaska. We find that surface water areas delineated from Planet imagery have a normalized root mean square error (NRMSE) of <11% and geolocation accuracy of <10 m as compared with manual delineations from high resolution (0.3–0.5 m) WorldView-2/3 panchromatic satellite imagery. For a 625 km2 subarea of the Yukon Flats, our time series analysis reveals that roughly one quarter of 268 lakes analyzed responded to changes in Yukon River discharge over the period 23 June–1 October 2016, one half steadily contracted, and one quarter remained unchanged. The spatial pattern of observed lake changes is heterogeneous. While connections to Yukon River control the hydrologically connected lakes, the behavior of other lakes is complex, likely driven by a combination of intricate flow paths, underlying geology and permafrost. Limitations of Planet CubeSat imagery include a lack of an automated cloud mask, geolocation inaccuracies, and inconsistent radiometric calibration across multiple platforms. Although these challenges must be addressed before Planet CubeSat imagery can achieve its full potential for large-scale hydrologic research, we conclude that CubeSat imagery offers a powerful new tool for the study and monitoring of dynamic surface water bodies.https://www.mdpi.com/2072-4292/9/12/1306Arctic hydrologyCubeSatsremote sensing of lakes and riversYukon Flats
collection DOAJ
language English
format Article
sources DOAJ
author Sarah W. Cooley
Laurence C. Smith
Leon Stepan
Joseph Mascaro
spellingShingle Sarah W. Cooley
Laurence C. Smith
Leon Stepan
Joseph Mascaro
Tracking Dynamic Northern Surface Water Changes with High-Frequency Planet CubeSat Imagery
Remote Sensing
Arctic hydrology
CubeSats
remote sensing of lakes and rivers
Yukon Flats
author_facet Sarah W. Cooley
Laurence C. Smith
Leon Stepan
Joseph Mascaro
author_sort Sarah W. Cooley
title Tracking Dynamic Northern Surface Water Changes with High-Frequency Planet CubeSat Imagery
title_short Tracking Dynamic Northern Surface Water Changes with High-Frequency Planet CubeSat Imagery
title_full Tracking Dynamic Northern Surface Water Changes with High-Frequency Planet CubeSat Imagery
title_fullStr Tracking Dynamic Northern Surface Water Changes with High-Frequency Planet CubeSat Imagery
title_full_unstemmed Tracking Dynamic Northern Surface Water Changes with High-Frequency Planet CubeSat Imagery
title_sort tracking dynamic northern surface water changes with high-frequency planet cubesat imagery
publisher MDPI AG
series Remote Sensing
issn 2072-4292
publishDate 2017-12-01
description Recent deployments of CubeSat imagers by companies such as Planet may advance hydrological remote sensing by providing an unprecedented combination of high temporal and high spatial resolution imagery at the global scale. With approximately 170 CubeSats orbiting at full operational capacity, the Planet CubeSat constellation currently offers an average revisit time of <1 day for the Arctic and near-daily revisit time globally at 3 m spatial resolution. Such data have numerous potential applications for water resource monitoring, hydrologic modeling and hydrologic research. Here we evaluate Planet CubeSat imaging capabilities and potential scientific utility for surface water studies in the Yukon Flats, a large sub-Arctic wetland in north central Alaska. We find that surface water areas delineated from Planet imagery have a normalized root mean square error (NRMSE) of <11% and geolocation accuracy of <10 m as compared with manual delineations from high resolution (0.3–0.5 m) WorldView-2/3 panchromatic satellite imagery. For a 625 km2 subarea of the Yukon Flats, our time series analysis reveals that roughly one quarter of 268 lakes analyzed responded to changes in Yukon River discharge over the period 23 June–1 October 2016, one half steadily contracted, and one quarter remained unchanged. The spatial pattern of observed lake changes is heterogeneous. While connections to Yukon River control the hydrologically connected lakes, the behavior of other lakes is complex, likely driven by a combination of intricate flow paths, underlying geology and permafrost. Limitations of Planet CubeSat imagery include a lack of an automated cloud mask, geolocation inaccuracies, and inconsistent radiometric calibration across multiple platforms. Although these challenges must be addressed before Planet CubeSat imagery can achieve its full potential for large-scale hydrologic research, we conclude that CubeSat imagery offers a powerful new tool for the study and monitoring of dynamic surface water bodies.
topic Arctic hydrology
CubeSats
remote sensing of lakes and rivers
Yukon Flats
url https://www.mdpi.com/2072-4292/9/12/1306
work_keys_str_mv AT sarahwcooley trackingdynamicnorthernsurfacewaterchangeswithhighfrequencyplanetcubesatimagery
AT laurencecsmith trackingdynamicnorthernsurfacewaterchangeswithhighfrequencyplanetcubesatimagery
AT leonstepan trackingdynamicnorthernsurfacewaterchangeswithhighfrequencyplanetcubesatimagery
AT josephmascaro trackingdynamicnorthernsurfacewaterchangeswithhighfrequencyplanetcubesatimagery
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