Abstract
We proposed a new efficient image denoising scheme, which mainly leads to four important contributions whose approaches are different from existing ones. The first is to show the equivalence between the group-based sparse representation and the Schatten-p norm minimization problem, so that the sparsity of the coefficients for each group can be measured by estimating the underlying singular values. The second is that we construct the proximal operator for sparse optimization in ℓp space with p ∈ (0, 1] by using fixed-point iteration and obtained a new solution of Schatten-p norm minimization problem, which is more rigorous and accurate than current available results. The third is that we analyze the suitable setting of power p for each noise level σ = 20, 30, 50, 60, 75, 100, respectively. We find that the optimal value of p is inversely proportional to the noise level except for high level of noise, where the best values of p are 1 and 0.95, when the noise levels are respectively 75 and 100. Last we measure the structural similarity between two image patches and extends previous deterministic annealing-based solution to sparsity optimization problem through incorporating the idea of dictionary learning. Experimental results demonstrate that for every given noise level, the proposed Spatially Adaptive Fixed Point Iteration (SAFPI) algorithm attains the best denoising performance on the value of Peak Signal-to-Noise Ratio (PSNR) and structure similarity (SSIM), being able to retain the image structure information, which outperforms many state-of-the-art denoising methods such as Block-matching and 3D filtering (BM3D), Weighted Nuclear Norm Minimization (WNNM) and Weighted Schatten p-Norm Minimization (WSNM).
Highlights
To demonstrate the effectiveness of the proposed denoising algorithm, we compared the denoising performance with recently proposed state-of-the-art denoising methods, such as BM3D [37], WNNM [38], WSNM [21], Expected Patch Log-likelihood (EPLL) [39], Spatially Adaptive Iterative Singular-value Thresholding (SAIST) [17], Patch-Based Near-Optimal image denoising (PBNO) [40], Global Image Denoising (GID) [41], iterative denoising system based on Wiener filtering (WIENER) [34], and Linear Complex Diffusion Process (LCDP) [35]
We evaluated the performance with three criterion: Structure Similarity Index (SSIM), kurtosis and Peak Signal-to-Noise Ratio (PSNR) which defined maximum intensity of the underlying image and MSE
A fixed-point iteration scheme was developed for sparse optimization in lp space with p 2
Summary
Non-local image denoising using fixed-point iteration for non-convex lp sparse optimization model the noise [1,2,3,4,5,6,7,8]. We unify the group-based sparse coding in [20] and the Schatten-p norm minimization problem in [21] by proving their mathematical equivalence. 2. A fixed-point iteration scheme is developed for sparse optimization in lp space with p 2
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