Abstract
Hyperspectral (HS) pansharpening aims at fusing a low-resolution HS (LRHS) image with a panchromatic image to obtain a full-resolution HS image. Most of the existing HS pansharpening approaches are usually based on traditional multispectral pansharpening techniques, which are not especially tailored for two inherent challenges of the HS pansharpening, i.e., much wider spectral range gap between the two kinds of images and having to recover details in many continuous spectral bands simultaneously. In this article, we develop new spectral-fidelity convolutional neural networks (called HSpeNets) for HS pansharpening to keep the fidelity of a pansharpened image to its true spectra as much as possible. Our methods particularly focus on the decomposability of HS details, accordingly synthesizing these details progressively, and meanwhile introduce a spectral-fidelity loss. We give theoretical justifications and provide detailed experimental results, showing the superiorities of the proposed HSpeNets with regard to other state-of-the-art pansharpening approaches.
Highlights
I MAGING spectroscopy captures the electromagnetic spectrum in many narrow contiguous bands, yielding hyperspectral (HS) images, which comprise both spatial and abundant spectral information from the observed scenes
HS images usually have lower spatial resolution when compared to panchromatic (PAN) images, which may not be sufficient in some practical applications where both high spatial and spectral resolutions are desired simultaneously [6]
We have focused on convolutional neural networks (CNNs) for HS pansharpening and designed two HSpeNets, i.e., HSpeNet1 and HSpeNet2
Summary
I MAGING spectroscopy captures the electromagnetic spectrum in many narrow contiguous bands, yielding hyperspectral (HS) images, which comprise both spatial and abundant spectral information from the observed scenes. Such a characteristic makes HS image data very valuable in many application. Manuscript received May 26, 2020; revised August 10, 2020; accepted September 4, 2020. Due to the physical limitations of sensors, improving the spectral resolution during image collection tends to negatively affect the spatial resolution. One way to overcome this obstacle is to perform HS pansharpening, which is dedicated to generate high-spatial-resolution HS (HRHS) images by fusing low-resolution HS (LRHS) images with their PAN (high-resolution) counterparts [4], while traditional pansharpening, in contrast, merges multispectral (MS) images with PANs
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