Abstract
ABSTRACT Many applications require remotely sensed brightness temperature (BT) data acquired with high temporal and spatial resolutions. In this regard, a viable strategy to overtake the physical limitations of space-borne sensors to achieve these data relies on fusing low temporal but high spatial resolution (HSR) data with high temporal but low spatial resolution data. The most promising methods rely on the fusion of spatially interpolated high temporal resolution data with temporally interpolated HSR data. However, the unavoidable presence of cloud masses in the acquired image sequences is often neglected, compromising the functionality and/or the effectiveness of the most of these fusion algorithms. To overcome this problem, a framework combining techniques of temporal smoothing and spatial enhancement is proposed to estimate surface BTs with high spatial and high temporal resolutions even when cloud masses corrupt the scene. Numerical results using real thermal data acquired by the SEVIRI sensor show the ability of the proposed approach to reach better performance than techniques based on either only interpolation or only spatial sharpening, even dealing with missing data due to the presence of cloud masses.
Highlights
Sensors on-board satellite platforms acquire everyday thousands of images in order to continuously monitor huge geographical areas
A viable strategy to overtake the physical limitations of space-borne sensors to achieve these data relies on fusing low temporal but high spatial resolution (HSR) data with high temporal but low spatial resolution data
A Bayesian smoother based on the Rauch– Tung–Striebel (RTS) algorithm and a pansharpening method belonging to the multi-resolution analysis family are exploited for temporal smoothing and spatial sharpening, respectively
Summary
Sensors on-board satellite platforms acquire everyday thousands of images in order to continuously monitor huge geographical areas. This amount of data is usually processed to achieve synthetic information (features) related to geophysical quantities. A product of broad interest, provided by the processing of brightness temperature (BT) data, is the land surface temperature (LST). This is used as input in several applications (Running et al, 1994), such as forest fires (Eckmann, Roberts, & Still, 2008), urban, regional and global climate models (Meehl, 1994; Weng, 2009), crop growth modeling (de Wit & Van Diepen, 2008) and water resource management (Allen, Tasumi, & Trezza, 2007; IRRISAT Project). Data fusion is increasing attention into the scientific community
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