Abstract
Fusion from a spatially low resolution hyperspectral image (LR-HSI) and a spectrally low resolution multispectral image (MSI) to produce a high spatial-spectral HSI (HR-HSI), known as hyperspectral super resolution, has risen to a preferred topic for reinforcing the spatial-spectral resolution of HSI in recent years. In this work, we propose a new model, namely, low-rank tensor ring decomposition based on tensor nuclear norm (LRTRTNN), for HSI-MSI fusion. Specifically, for each spectrally subspace cube, similar patches are grouped to exploit both the global low-rank property of LR-HSI and the nonlocal similarity of HR-MSI. Afterward, a joint optimization of all groups via the presented LRTRTNN approximation is implemented in a unified cost function. With the introduced tensor nuclear norm (TNN) constraint, all 3D tensor ring factors are no longer unfolded to suit the matrix nuclear norm used in conventional methods, and the internal tensor structure can be naturally retained. The alternating direction method of multipliers is introduced for coefficients update. Numerical and visual experiments on real data show that our LRTRTNN method outperforms most state-of-the-art algorithms in terms of fusing performance.
Highlights
Hyperspectral imaging is a rising modality where a camera acquires images with tens or even hundreds of spectral bands in wide-range spectral coverage from a scene across
We further introduce some definitions about tensor nuclear norm (TNN) and tensor singular value decomposition (t-SVD)
From the error maps, especially in the magnified regions, one can find that our proposed method tends to generate much bluer and smoother results, which demonstrates that the fused high spatial-spectral hyperspectral images (HSIs) (HR-HSI) by NSSR, CSTF, UTV, STEREO, SC-LL1, and LTMR are with more flaws and scattered points
Summary
Hyperspectral imaging is a rising modality where a camera acquires images with tens or even hundreds of spectral bands in wide-range spectral coverage from a scene across. There is invariably a certain compromise between the spectral dimension and spatial dimension for existing cameras due to the quantity of the incident energy is restricted in the optical remote sensing systems [11]. The acquired MSIs have a higher spatial dimension, but the spectral resolution is lower. It is an increasingly promising and economical approach to generate the high spatial resolution HSI (HRHSI) by fusing a high spatial resolution MSI (HR-MSI) with the corresponding low spatial resolution HSI (LR-HSI) of the same scene
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