Abstract
Image deblurring under the background of impulse noise is a typically ill-posed inverse problem which attracted great attention in the fields of image processing and computer vision. The fast total variation deconvolution (FTVd) algorithm proved to be an effective way to solve this problem. However, it only considers sparsity of the first-order total variation, resulting in staircase artefacts. The L1 norm is adopted in the FTVd model to depict the sparsity of the impulse noise, while the L1 norm has limited capacity of depicting it. To overcome this limitation, we present a new algorithm based on the Lp-pseudo-norm and total generalized variation (TGV) regularization. The TGV regularization puts sparse constraints on both the first-order and second-order gradients of the image, effectively preserving the image edge while relieving undesirable artefacts. The Lp-pseudo-norm constraint is employed to replace the L1 norm constraint to depict the sparsity of the impulse noise more precisely. The alternating direction method of multipliers is adopted to solve the proposed model. In the numerical experiments, the proposed algorithm is compared with some state-of-the-art algorithms in terms of peak signal-to-noise ratio (PSNR), structural similarity (SSIM), signal-to-noise ratio (SNR), operation time, and visual effects to verify its superiority.
Highlights
Image deblurring under impulse noise is important in digital image processing research
This study focused on exploring image restoration in the presence of impulse noise pollution
Combining the Lp-pseudo-norm with the total generalized variation (TGV) regularization, this study proposes a new regularization model for image restoration to more thoroughly extract the structural characteristics of the first-order and second-order gradient matrices of the image, and obtain a sparser solution
Summary
Image deblurring under impulse noise is important in digital image processing research. Image restoration of degraded images is an inverse problem whose solution is often ill-posed [1]. For such types of problems, regularization proved to be an effective method. This involves the proper use of some prior information of the degraded image as a fidelity term and an image optimization model that contains an efficient solution algorithm as a regularization term, because recovering a clear image is of great importance for advanced image processing in the later stages
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