Abstract
Abstract. The presence of snow cover has significant impacts on the both global and regional climate and water balance on earth. The accurate estimation of snow cover area can be used for forecasting runoff due to snow melt and output of hydroelectric power. With development of remote sensing techniques at different scopes in earth science, enormous algorithms for retrieval hydrometeor parameters have been developed. Some of these algorithms are used to provide snow cover map such as NLR with AVHRR/MODIS sensor for Norway, Finnish with AVHRR sensor for Finland and NASA with MODIS sensor for global maps. Monitoring snow cover at different parts of spectral electromagnetic is detectable (visible, near and thermal infrared, passive and active microwave). Recently, specific capabilities of active microwave remote sensing such as snow extent map, snow depth, snow water equivalent (SWE), snow state (wet/dry) and discrimination between rain and snow region were given a strong impetus for using this technology in snow monitoring, hydrology, climatology, avalanche research and etc. This paper evaluates the potentials and feasibility of polarimetric ground microwave measurements of snow in active remote sensing field. We will consider the behavior co- and cross-polarized backscattering coefficients of snowpack response with polarimetric scatterometer in Ku and L band at the different incident angles. Then we will show how to retrieve snow cover depth, snow permittivity and density parameters at the local scale with ground-based SAR (GB-SAR). Finally, for the sake of remarkable significant the transition region between rain and snow; the variables role of horizontal reflectivity (ZHH) and differential reflectivity (ZDR) in delineation boundary between snow and rain and some others important variables at polarimetric weather radar are presented.
Highlights
The radar hydrology provides data that can be used for input to runoff, flood, storm and avalanche prediction models and related natural disasters
The phase comparison of a pair of complex coherent radar images of the same scene that acquired in different time and Repeat-pass can generate a differential interferometry
There are many methods for cover and depth snow parameters retrieval both in passive and active remote sensing. Retrieval of those parameters in active remote sensing can be done by space born and air born radar imaging
Summary
The radar hydrology provides data that can be used for input to runoff, flood, storm and avalanche prediction models and related natural disasters. One most important aspects of radar meteorology is the use of polarimetric radar techniques at various frequencies for measuring SWE. Demonstration of satellite SAR data for SWE measurements was first reported by (Shi and Dozier, 2000a, b). Some researches' modeling (Shi, 2004 and 2006) are shown that dual frequencies at combination of X- and Ku-bands are more suitable for monitoring of SWE. One of the most sophisticated methods for retrieving hydrological parameters of snow is SAR differential interferometry (DInSAR) and use of the differential phase. Retrieving SWE by interferometric phase shift in snow due to differences in travelled paths was first. The peer-review was conducted on the basis of the abstract
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