Abstract
Multispectral image denoising is a basic problem whose results affect subsequent processes such as target detection and classification. Numerous approaches have been proposed, but there are still many challenges, particularly in using prior knowledge of multispectral images, which is crucial for solving the ill-posed problem of noise removal. This paper considers both non-local self-similarity in space and global correlation in spectrum. We propose a novel low-rank Tucker decomposition model for removing the noise, in which sparse and graph Laplacian regularization terms are employed to encode this prior knowledge. It can jointly learn a sparse and low-rank representation while preserving the local geometrical structure between spectral bands, so as to better capture simultaneously the correlation in spatial and spectral directions. We adopt the alternating direction method of multipliers to solve the resulting problem. Experiments demonstrate that the proposed method outperforms the state-of-the-art, such as cube-based and tensor-based methods, both quantitatively and qualitatively.
Highlights
A multispectral image (MSI) contains dozens of bands, each of which is captured over a specific wavelength range of the electromagnetic spectrum
Driven by the idea of using prior knowledge to improve the results of denoising, this paper investigates the priors of nonlocal self-similarity and spectral correlation based on a patch framework
peak signal-to-noise ratio (PSNR), structural similarity (SSIM), or feature similarity (FSIM) for an MSI is computed on each band image separately, and averaged
Summary
A multispectral image (MSI) contains dozens of bands, each of which is captured over a specific wavelength range of the electromagnetic spectrum It provides rich spectral-spatial information for improved performance of applications in remote sensing, such as target detection [1], classification [2], and tracking [3]. Straightforward denoising employs conventional methods for 1D signals and grayscale images, such as wavelet domain soft thresholding [5], K-SVD [6], and block-matching and 3D filtering (BM3D) [7]. Those methods only take into account spectral correlation or spatial correlation, and satisfactory results cannot be generally achieved. Some examples include the use of principal component analysis [8], multidimensional Wiener filtering [9], and tensor decompositions [10,11,12]
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