AirSWOT InSAR Mapping of Surface Water Elevations and Hydraulic Gradients Across the Yukon Flats Basin, Alaska

Abstract: AirSWOT, an experimental airborne Ka-band interferometric synthetic aperture radar, was developed for hydrologic research and validation of the forthcoming Surface Water and Ocean Topography (SWOT) satellite mission (to be launched in 2021). AirSWOT and SWOT aim to improve understanding of surface water processes by mapping water surface elevation (WSE) and water surface slope (WSS) in rivers, lakes, and wetlands. However, the utility of AirSWOT for these purposes remains largely unexamined. We present the fir… Show more

“…These elevation and slope errors compared with in situ data are slightly higher than those previously reported (Altenau et al, 2017;Pitcher et al, 2018), and exceed the SWOT science requirements for 100-m rivers (10-cm elevation/1.7-cm/km slope RMSE), but the Willamette is a narrower river than the rivers investigated in previous studies and we are therefore evaluating elevation uncertainty over a smaller water surface area for 10-km reaches. At the pixel level, AirSWOT elevation RMSEs compared with in situ data are 99.1 cm, dropping to 80.4 cm when the incidence angle and land/water buffer filters were implemented.…”

“…We evaluate slope as a rise-over-run approach using only the nodes at the start and end of the reach; slope RMSE compared with in situ data for four reaches across 6 days of data was 3.2 cm/km. These elevation and slope errors compared with in situ data are slightly higher than those previously reported (Altenau et al, 2017;Pitcher et al, 2018), and exceed the SWOT science requirements for 100-m rivers (10-cm elevation/1.7-cm/km slope RMSE), but the Willamette is a narrower river than the rivers investigated in previous studies and we are therefore evaluating elevation uncertainty over a smaller water surface area for 10-km reaches.…”

“…As in Altenau et al (2017) and Pitcher et al (2018), the data used in this study were from the outer swath of the Kaband AirSWOT instrument, which provides data at incidence angles between nadir and 25°off nadir, leading to a~3-km swath width for the flight altitudes used over the Willamette (8,600 m above mean sea level). As in Altenau et al (2017) and Pitcher et al (2018), the data used in this study were from the outer swath of the Kaband AirSWOT instrument, which provides data at incidence angles between nadir and 25°off nadir, leading to a~3-km swath width for the flight altitudes used over the Willamette (8,600 m above mean sea level).…”

“…AirSWOT overflights occurred on 16, 17, 24, 25, 30, and 31 March 2015 and were timed to coincide with an atmospheric river event, which was expected to provide dynamic hydraulic conditions during an otherwise dry period for the region. As in Altenau et al (2017) and Pitcher et al (2018), the data used in this study were from the outer swath of the Kaband AirSWOT instrument, which provides data at incidence angles between nadir and 25°off nadir, leading to a~3-km swath width for the flight altitudes used over the Willamette (8,600 m above mean sea level). Compared to SWOT, which operates at incidence angles ranging from 1°to 5°, AirSWOT's broader range of incidence angles leads to larger variabilities in backscatter, interferometric coherence, and phase ambiguity across the swath and does not allow for land-water delineation using radar return data.…”

Estimating River Discharge With Swath Altimetry: A Proof of Concept Using AirSWOT Observations

“…These elevation and slope errors compared with in situ data are slightly higher than those previously reported (Altenau et al, 2017;Pitcher et al, 2018), and exceed the SWOT science requirements for 100-m rivers (10-cm elevation/1.7-cm/km slope RMSE), but the Willamette is a narrower river than the rivers investigated in previous studies and we are therefore evaluating elevation uncertainty over a smaller water surface area for 10-km reaches. At the pixel level, AirSWOT elevation RMSEs compared with in situ data are 99.1 cm, dropping to 80.4 cm when the incidence angle and land/water buffer filters were implemented.…”

“…We evaluate slope as a rise-over-run approach using only the nodes at the start and end of the reach; slope RMSE compared with in situ data for four reaches across 6 days of data was 3.2 cm/km. These elevation and slope errors compared with in situ data are slightly higher than those previously reported (Altenau et al, 2017;Pitcher et al, 2018), and exceed the SWOT science requirements for 100-m rivers (10-cm elevation/1.7-cm/km slope RMSE), but the Willamette is a narrower river than the rivers investigated in previous studies and we are therefore evaluating elevation uncertainty over a smaller water surface area for 10-km reaches.…”

“…As in Altenau et al (2017) and Pitcher et al (2018), the data used in this study were from the outer swath of the Kaband AirSWOT instrument, which provides data at incidence angles between nadir and 25°off nadir, leading to a~3-km swath width for the flight altitudes used over the Willamette (8,600 m above mean sea level). As in Altenau et al (2017) and Pitcher et al (2018), the data used in this study were from the outer swath of the Kaband AirSWOT instrument, which provides data at incidence angles between nadir and 25°off nadir, leading to a~3-km swath width for the flight altitudes used over the Willamette (8,600 m above mean sea level).…”

“…AirSWOT overflights occurred on 16, 17, 24, 25, 30, and 31 March 2015 and were timed to coincide with an atmospheric river event, which was expected to provide dynamic hydraulic conditions during an otherwise dry period for the region. As in Altenau et al (2017) and Pitcher et al (2018), the data used in this study were from the outer swath of the Kaband AirSWOT instrument, which provides data at incidence angles between nadir and 25°off nadir, leading to a~3-km swath width for the flight altitudes used over the Willamette (8,600 m above mean sea level). Compared to SWOT, which operates at incidence angles ranging from 1°to 5°, AirSWOT's broader range of incidence angles leads to larger variabilities in backscatter, interferometric coherence, and phase ambiguity across the swath and does not allow for land-water delineation using radar return data.…”

Estimating River Discharge With Swath Altimetry: A Proof of Concept Using AirSWOT Observations

“…In total, these four study areas cover 226,553 km 2 of the western Arctic-Boreal region of North America (Figure 1, inset), and span Arctic tundra, boreal forest, peat plateau, lowland wetland, and upland shield terrains. The 33,383 km 2 YFB study area is characterized by fluvially disconnected wetlands surrounding a wide low-gradient reach of the Yukon River in north central Alaska (e.g., Anderson et al, 2013;Pitcher et al, 2019). The 82,200 km 2 MRV study area includes the Mackenzie River Delta, a vast, fluvially connected wetland, the Tuktoyaktuk Peninsula, a polar desert with continuous permafrost and thousands of thermokarst lakes, and boreal forest and plateaus further south along the Mackenzie and Peel Rivers (Burn & Kokelj, 2009;Plug et al, 2008).…”

Arctic‐Boreal Lake Dynamics Revealed Using CubeSat Imagery

Earth Observation and Hydraulic Data Assimilation for Improved Flood Inundation Forecasting