Abstract
An improved cloud shadow removal algorithm for high spatial resolution optical satellite data over land is presented. The method is based on the matched filter method, which consists of the calculation of a covariance matrix and the corresponding zero-reflectance matched filter vector and the computation of the shadow function. The new additions consist of the usage of an improved cloud shadow map and further evaluations performed on the shadow function. The performance of the cloud shadow removal algorithm incorporated in the software package Python-based atmospheric correction (PACO) is compared to the deshadowing algorithm in atmospheric correction on a set of 25 Sentinel-2 scenes distributed over the globe covering a wide variety of environments and climates. Furthermore, an evaluation of the relative ratio between clear and shadow pixels with and without deshadowing is performed. The visual, spectral, and statistical results show that the new additions performed on the deshadowing algorithm can improve the cloud shadow removal performance used so far.
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