Abstract
As the hyperspectral images (HSIs) usually have a low spatial resolution, HSI super-resolution has recently attracted more and more attention to enhance the spatial resolution of HSIs. A common method is to fuse the low-resolution (LR) HSI with a multispectral image (MSI) whose spatial resolution is higher than the HSI. In this article, we proposed a novel adaptive nonnegative sparse representation-based model to fuse an HSI and its corresponding MSI. First, basing the linear spectral unmixing, the nonnegative structured sparse representation model estimates the sparse codes of the desired high-resolution HSI from both the LR-HSI and the MSI. Then, the adaptive sparse representation can balance the relationship between the sparsity and collaboration by generating a suitable coefficient. Finally, in order to obtain more accurate results, we alternately optimize the spectral basis and coefficients rather than keeping the spectral basis fixed. The alternating direction method of multipliers is applied to solve the proposed optimization problem. The experimental results on both ground-based HSIs and real remote sensing HSIs show the superiority of our proposed approach to some other state-of-the-art HSI super-resolution methods.
Highlights
Hyperspectral (HS) imaging has attracted wide attention in recent years since it can simultaneously obtain images of the same scenario across plenty of different successive wavelengths at the same time [1]–[3]
Since there is a limited amount of incident energy in optical remote sensing systems, the imaging systems have to compromise between the spectral resolution and spatial resolution [8]
Inspired by the trace least absolute shrinkage and selection operator (LASSO) [53], [54], we propose a novel spatial–spectral adaptive nonnegative sparse representation (ANSR) method for hyperspectral images (HSIs) super-resolution by fusing the low spatial resolution HSI (LR-HSI) and the corresponding HR-multispectral image (MSI)
Summary
Hyperspectral (HS) imaging has attracted wide attention in recent years since it can simultaneously obtain images of the same scenario across plenty of different successive wavelengths at the same time [1]–[3]. Because hyperspectral image (HSI) has rich spectral information, it has been widely used in many fields, such as target detection [4], environmental monitoring [5], military [6], and remote sensing [7]. Since there is a limited amount of incident energy in optical remote sensing systems, the imaging systems have to compromise between the spectral resolution and spatial resolution [8]. Manuscript received November 17, 2020; revised January 7, 2021 and March 17, 2021; accepted April 3, 2021. Date of publication April 9, 2021; date of current version May 3, 2021.
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