A New Operational Northern Hemisphere Snow Water Equivalent Retrieval Algorithm for FY-3F/MWRI-II Based on Pixel-Based Regression Coefficients
Satellite passive microwave (PMW) remote sensing is widely used for monitoring the snow water equivalent (SWE) in the Northern Hemisphere. Existing operational SWE retrieval methods, especially those without assimilating ground-based snow depth priors, still utilize globally constant coefficients to...
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Veröffentlicht in: | IEEE transactions on geoscience and remote sensing 2024, Vol.62, p.1-15 |
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Zusammenfassung: | Satellite passive microwave (PMW) remote sensing is widely used for monitoring the snow water equivalent (SWE) in the Northern Hemisphere. Existing operational SWE retrieval methods, especially those without assimilating ground-based snow depth priors, still utilize globally constant coefficients to construct regression-based retrieval algorithms. The current Fengyun-3 (FY-3) series of SWE product algorithms has made improvements in China, where biases have been significantly reduced locally but not in other regions. Within the context of the successful launch of the FY-3F satellites in 2023, we developed a better Northern Hemisphere algorithm for the Microwave Radiation Imager-II (FY-3F/MWRI-II) using pixel-sensitive coefficients regressed on a reference SWE dataset. We utilized the random forest model coupled with the snow emission model (HUT-RF) to obtain a high-accuracy SWE reference dataset. Then, we employed linear regression equations to fit the reference HUT-RF dataset at each pixel to construct the new operational FY-3F algorithms. We innovatively introduced the brightness temperature differences between 18.7 and 89 GHz and the polarization differences at 10.65 GHz in the regression after noting their sensitivity in deep snow estimation. The proposed FY-3F algorithm was extensively validated via four spatially independent datasets. The results demonstrated that the proposed FY-3F algorithm performed well in non-mountainous and sparsely forested areas, e.g., the overall unbiased root mean square error (unRMSE) values were 27.15 mm over Russia and 13.70 mm over China. High uncertainties still occurred in complex terrains and densely forested areas, e.g., the overall unRMSE values were 75.30 mm over Canada and 129.06 mm over western North America. The proposed FY-3F algorithm could improve global snow cover monitoring capabilities and enhance the complete and timely understanding of SWE changes. |
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ISSN: | 0196-2892 1558-0644 |
DOI: | 10.1109/TGRS.2024.3479452 |