Abstract
The opacity of clouds is the main problem for optical and thermal space-borne sensors, like the Moderate-Resolution Imaging Spectroradiometer (MODIS). Especially during polar nighttime, the low thermal contrast between clouds and the underlying snow/ice results in deficiencies of the MODIS cloud mask and affected products. There are different approaches to retrieve information about frequently cloud-covered areas, which often operate with large amounts of days aggregated into single composites for a long period of time. These approaches are well suited for static-nature, slow changing surface features (e.g., fast-ice extent). However, this is not applicable to fast-changing features, like sea-ice polynyas. Therefore, we developed a spatial feature reconstruction to derive information for cloud-covered sea-ice areas based on the surrounding days weighted directly proportional with their temporal proximity to the initial day of interest. Its performance is tested based on manually-screened and artificially cloud-covered case studies of MODIS-derived polynya area data for the polynya in the Brunt Ice Shelf region of Antarctica. On average, we are able to completely restore the artificially cloud-covered test areas with a spatial correlation of 0.83 and a mean absolute spatial deviation of 21%.
Highlights
Cloud cover is the crucial deficit of optical and thermal-infrared space-borne remote sensing compared to microwave systems
We present a simple, yet robust, statistical approach to reconstruct cloud-covered surface features based on daily binary Moderate-Resolution Imaging Spectroradiometer (MODIS) composites for adaptable time intervals
We focus on the reconstruction of data gaps in the daily composites, which result from detected cloud cover by the MODIS cloud mask
Summary
Cloud cover is the crucial deficit of optical and thermal-infrared space-borne remote sensing compared to microwave systems. Satellite products, such as the Moderate-Resolution Imaging. Spectroradiometer (MODIS) cloud mask (MOD35), which incorporates a total of 19 different spectral bands of passive-reflected and infrared radiation, show in general good results for polar daytime (e.g., [1,2]). Their performance decreases drastically during polar nighttime (e.g., [1,3,4,5]). While strong improvements were achieved, confident cloud cover detection in polar nighttime over snow and ice surfaces remains a problem [1]
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