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Benefits of Fully Focused SAR Altimetry to Coastal Wave Height Estimates: A Case Study in the North Sea
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  • Florian Schlembach,
  • Frithjof Ehlers,
  • Marcel Kleinherenbrink,
  • Marcello Passaro,
  • Denise Dettmering,
  • Florian Seitz,
  • Cornelis Slobbe
Florian Schlembach
Deutsches Geodätisches Forschungsinstitut

Corresponding Author:[email protected]

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Frithjof Ehlers
Geoscience and Remote Sensing
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Marcel Kleinherenbrink
Geoscience and Remote Sensing
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Marcello Passaro
Geoscience and Remote Sensing
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Denise Dettmering
Deutsches Geodätisches Forschungsinstitut
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Florian Seitz
Deutsches Geodätisches Forschungsinstitut
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Cornelis Slobbe
Geoscience and Remote Sensing
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Abstract

Estimating the three geophysical variables significant wave height (SWH), sea surface height, and wind speed from satellite altimetry continues to be challenging in the coastal zone because the received radar echoes exhibit significant interference from strongly reflective targets such as mud banks, sheltered bays, ships etc. Fully focused SAR (FF-SAR) processing exhibits a theoretical along-track resolution of up to less than half a metre. This suggests that the application of FF-SAR altimetry might give potential gains over unfocused SAR (UF-SAR) altimetry to resolve and mitigate small-scale interferers in the along-track direction to improve the accuracy and precision of the geophysical estimates. The objective of this study is to assess the applicability of FF-SAR-processed Sentinel-6 Michael Freilich (S6-MF) coastal altimetry data to obtain SWH estimates as close as possible to the coast. We have developed a multi-mission FF-SAR processor and applied the coastal retracking algorithm CORALv2 to estimate SWH. We assess different FF-SAR and UF-SAR processing configurations, as well as the baseline Level-2 product from EUMETSAT, by comparison with the coastal, high-resolution SWAN-Kuststrook wave model from the Deltares RWsOS North Sea operational forecasting system. This includes the evaluation of the correlation, the median offset, and the percentage of cycles with high correlation as a function of distance to the nearest coastline. Moreover, we analyse the number of valid records and the L2 noise of the records. The case study comprises five coastal crossings of S6-MF that are located along the Dutch coast and the German coast along the East Frisian Islands in the North Sea. We find that the FF-SAR-processed dataset with a Level-1b posting rate of 140 Hz shows the greatest similarity with the wave model. We achieve a correlation of ~0.8 at 80% of valid records and a gain in precision of up to 29% of FF-SAR vs UF-SAR for 1-3 km from the coast. FF-SAR shows, for all cycles, a high correlation of greater than or equal to 0.8 for 1-3 km from the coast. We estimate the decay of SWH from offshore at 30 km to up to 1 km from the coast to amount to 26.4% +- 3.1%.
07 Mar 2023Submitted to ESS Open Archive
09 Mar 2023Published in ESS Open Archive
May 2023Published in Remote Sensing of Environment volume 289 on pages 113517. 10.1016/j.rse.2023.113517