Abstract
Traditional studies on mapping wet snow cover extent (SCE) often feature limitations, especially in vegetated and mountainous areas. The aim of this study is to propose a new total and wet SCE mapping strategy based on freely accessible spaceborne synthetic aperture radar (SAR) data. The approach is transferable on a global scale as well as for different land cover types (including densely vegetated forest and agricultural regions), and is based on the use of backscattering coefficient, interferometric SAR coherence, and polarimetric parameters. Furthermore, four topographical factors were included in the simple tuning of random forest-based land cover type-dependent classification strategy. Results showed the classification accuracy was above 0.75, with an F-measure higher than 0.70, in all five selected regions of interest located around globally distributed mountain ranges. Whilst excluding forest-type land cover classes, the accuracy and F-measure increases to 0.80 and 0.75. In cross-location model set, the accuracy can also be maintained at 0.80 with non-forest accuracy up to 0.85. It has been found that the elevation and polarimetric parameters are the most critical factors, and that the quality of land cover information would also affect the subsequent mapping reliability. In conclusion, through comprehensive validation using optical satellite and in-situ data, our land cover-dependent total SCE mapping approach has been confirmed to be robustly applicable, and the holistic SCE map for different months were eventually derived.
Highlights
Snow cover is an important parameter in the context of water availability, the global radiation balance, and natural disasters such as floods and avalanches
Based on the optimized input variable combinations tested in Section 3.2.4, the same modelling approach was applied to all five study areas
Almost all land cover types within all study areas were still characterized by a satisfyinthgeaZcGcurreagcioyn(.>H0o.w6)e,vweri,tahlmthoesteaxllcelapntdiocnovoefr ftyopreesstwedithcilnaaslslesstuodfythareeaMs Rwerreegsitoilnl .chTahraicstearffiizerdmed the by a satisfying accuracy (>0.6), with the exception of forested classes of the Monte Rosa (MR) region
Summary
Snow cover is an important parameter in the context of water availability, the global radiation balance, and natural disasters such as floods and avalanches. It is a crucial resource for tourism and hydropower generation [1,2,3,4]. Climate change has been affecting snow cover extent (SCE), its amount, and its distribution globally, generally leading to a decline of the aforementioned parameters [5,6,7,8]. Based on climate model simulations and the IPCC special report [6], a declining trend of SCE must be expected, with an even more severe impact on mountain regions [5,11]
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