Abstract
Remote-sensing time-series data are significant for global environmental change research and a better understanding of the Earth. However, remote-sensing acquisitions often provide sparse time series due to sensor resolution limitations and environmental factors, such as cloud noise for optical data. Image interpolation is the method that is often used to deal with this issue. This paper considers the deep learning method to learn the complex mapping of an interpolated intermediate image from predecessor and successor images, called separable convolution network for sequence image interpolation. The separable convolution network uses a separable 1D convolution kernel instead of 2D kernels to capture the spatial characteristics of input sequence images and then is trained end-to-end using sequence images. Our experiments, which were performed with unmanned aerial vehicle (UAV) and Landsat-8 datasets, show that the method is effective to produce high-quality time-series interpolated images, and the data-driven deep model can better simulate complex and diverse nonlinear image data information.
Highlights
IntroductionRemote-sensing time-series data are an important part of big earth observation data
Remote-sensing time-series data are an important part of big earth observation data.As standard spatiotemporal spectral data, remote-sensing time-series data can be applied to research and applications in global changes, such as vegetation phenology changes, land-surface parameter relationships, and land degradation
This site is a large flooded grassland of 174 ha located in the floodplain of the Couesnon River, upstream of Mont-Saint-Michel Bay [17]
Summary
Remote-sensing time-series data are an important part of big earth observation data. As standard spatiotemporal spectral data, remote-sensing time-series data can be applied to research and applications in global changes, such as vegetation phenology changes, land-surface parameter relationships, and land degradation. The value and successful application of remote-sensing time-series data are significant for earth science to expand the growth to a deeper level and to better understand the Earth [1,2]. Remote-sensing acquisitions often provide sparse time series due to sensor resolution limitations and environmental factors [3], such as cloud noise for optical data. A conventional method to solve missing data is 1D data interpolation, as is usually done for moderate-resolution imaging spectroradiometer (MODIS) data sequences with the following processing characteristics. This method is not suitable for high-spatial-resolution sequence images containing fine spatial pattern information
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