Abstract
Abstract. Pan-sharpening refers to the technology which fuses a low resolution multispectral image (MS) and a high resolution panchromatic (PAN) image into a high resolution multispectral image (HRMS). In this paper, we propose a Component Substitution Network (CSN) for pan-sharpening. By adding a feature exchange module (FEM) to the widely used encoder-decoder framework, we design a network following the general procedure of the traditional component substitution (CS) approaches. Encoder of the network decomposes the input image into spectral feature and structure feature. The FEM regroups the extracted features and combines the spectral feature of the MS image with the structure feature of the PAN image. The decoder is an inverse process of the encoder and reconstructs the image. The MS and the PAN image share the same encoder and decoder, which makes the network robust to spectral and spatial variations. To reduce the burden of data preparation and improve the performance on full-resolution data, the network is trained through semi-supervised learning with image patches at both reduced-resolution and full-resolution. Experiments performed on GeoEye-1 data verifies that the proposed network has achieved state-of-the-art performance, and the semi-supervised learning stategy further improves the performance on full-resolution data.
Highlights
Most optical remote sensing satellites provide both multispectral (MS) image and panchromatic (PAN) image
Downsampled multispectral image (MS) image and downsampled PAN image are used as inputs to the network, and the original MS image is used as ground truth for the pan-sharpened image
The acquirement of full-resolution data is easier compared to the reduced-resolution data, and much fewer images is needed to produce the same number of training samples
Summary
Most optical remote sensing satellites provide both multispectral (MS) image and panchromatic (PAN) image. The MRA methods extract multiscale details from the PAN image and inject them into the MS image. Pan-sharpening is different from SISR because the details are extracted from the PAN image rather than inferred from the low resolution image In these methods, the networks are trained on PAN image but directly applied for the MS image, the quality of the output image cannot be fully guaranteed. Yuan et al (Yuan et al, 2018) proposed a two-stream network and used convolutional kernels of different sizes to extract multiscale features Though these networks can output the pan-sharpened image end to end, the theoretical supports of these networks are scarce, it is difficult to explain how the networks handling the pan-sharpening task. The transformations can not completely separate the spatial structure from the spectral information, and the injection process inevitablely introduces spectral distortion
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