Analysis of Wetland Extent Retrieval Accuracy Using Cygnss

Spaceborne GNSS Reflectometry (GNSS-R) measurements have shown strong coherent scattering over inland waters. It has been recognized that GNSS-R could be utilized for monitoring the global surface water distribution by making dynamic maps of wetlands as well as rapid response to flood events. Using...

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Bibliographic Details
Main Authors: Loria, Eric, O'Brien, Andrew, Zavorotny, Valery, Lavalle, Marco, Chew, Clara, Shah, Rashmi, Zuffada, Cinzia
Format: Conference Proceeding
Language:English
Subjects:
Bistatic radar
CYGNSS
Fresnel reflection
Geometry
GNSS-R
Rivers
Scattering
Sea measurements
Signal to noise ratio
Wetlands
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Summary:Spaceborne GNSS Reflectometry (GNSS-R) measurements have shown strong coherent scattering over inland waters. It has been recognized that GNSS-R could be utilized for monitoring the global surface water distribution by making dynamic maps of wetlands as well as rapid response to flood events. Using the strength of the reflected signals, one can make maps that reveal the presence of water over land. In this paper, we used simulations to analyze the accuracy of these maps. The CYGNSS End-to-end Simulator (E2ES) was extended to include coherent scattering in the heterogeneous scenes where the region around the specular point is composed of both land and water in complex geometries. The simulation is then used to evaluate the accuracy of a simple fractional water in footprint approach to mapping wetland extent. We find that scattering from outside the first Fresnel zone and CYGNSS measurement processing effects significantly impact the accuracy of this approach. However, the accuracy can be improved by combining multiple measurements into a gridded map.
ISSN:2153-7003
DOI:10.1109/IGARSS.2019.8898132