Abstract
As rain drops change the radiation and scattering characteristic of the oceans and the atmosphere, the wind speed measuring by spaceborne remote sensors under rainy conditions remains challenging for years. On the basis of a microwave radiometer (RM) loaded on HY-2 satellite, the sensitivity of some brightness temperature (TB) channels to a rain rate and the wind speed are analyzed. Consequently, two TB combinations which show minor sensitivity to rain are obtained. Meanwhile, the sensitivity of the TB combination to the wind speed is even better to the original TB channel. On the basis of these TB combinations, a wind speed retrieval algorithm is developed and compared with WindSat all-weather wind speed product, HY-2 RM original wind speed product and buoy in situ data. The wind speed retrieval accuracy is better than 2 m/s for rainy conditions, which is evidently superior to HY-2 RM original product. The applicability of this new algorithm is testified for the wind speed measuring in rainy weather with HY-2 RM.
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The authors thank the National Ocean Satellite Application Center, State Oceanic Administration, Remote Sensing Systems, NDBC, ECMWF for providing access to data involved in the research.
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Foundation item: The National Science Foundation for Young Scientists of China under contract 41306183; the National High Technology Research and Development Program (863 Program) of China under contract Nos 2013AA09A505 and 2013AA122803.
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Wang, J., Zhang, J. & Wang, J. Sea surface wind speed retrieval under rain with the HY-2 microwave radiometer. Acta Oceanol. Sin. 36, 32–38 (2017). https://doi.org/10.1007/s13131-017-1080-5
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DOI: https://doi.org/10.1007/s13131-017-1080-5