Nonconvex L1/2-Regularized Nonlocal Self-similarity Denoiser for Compressive Sensing based CT Reconstruction

J. Frankl. Inst. Pub Date : 2022-05-15 DOI:10.48550/arXiv.2205.07185

Yunyi Li, Yiqiu Jiang, Hengmin Zhang, Jianxun Liu, Xiangling Ding, Guan Gui

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Abstract

Compressive sensing (CS) based computed tomography (CT) image reconstruction aims at reducing the radiation risk through sparse-view projection data. It is usually challenging to achieve satisfying image quality from incomplete projections. Recently, the nonconvex ${{L_ {{1/2}}}} $-norm has achieved promising performance in sparse recovery, while the applications on imaging are unsatisfactory due to its nonconvexity. In this paper, we develop a ${{L_ {{1/2}}}} $-regularized nonlocal self-similarity (NSS) denoiser for CT reconstruction problem, which integrates low-rank approximation with group sparse coding (GSC) framework. Concretely, we first split the CT reconstruction problem into two subproblems, and then improve the CT image quality furtherly using our ${{L_ {{1/2}}}} $-regularized NSS denoiser. Instead of optimizing the nonconvex problem under the perspective of GSC, we particularly reconstruct CT image via low-rank minimization based on two simple yet essential schemes, which build the equivalent relationship between GSC based denoiser and low-rank minimization. Furtherly, the weighted singular value thresholding (WSVT) operator is utilized to optimize the resulting nonconvex ${{L_ {{1/2}}}} $ minimization problem. Following this, our proposed denoiser is integrated with the CT reconstruction problem by alternating direction method of multipliers (ADMM) framework. Extensive experimental results on typical clinical CT images have demonstrated that our approach can further achieve better performance than popular approaches.

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基于压缩感知的CT重构非凸l1 /2正则化非局部自相似去噪

基于压缩感知(CS)的计算机断层扫描(CT)图像重建旨在通过稀疏视图投影数据降低辐射风险。从不完整的投影中获得令人满意的图像质量通常是具有挑战性的。近年来，非凸范数${{L_{{1/2}}}} $-范数在稀疏恢复方面取得了很好的效果，但由于其非凸性，在成像方面的应用并不理想。本文针对CT重构问题，提出了一种${{L_{{1/2}}}} $正则化非局部自相似(NSS)去噪方法，该方法将低秩近似与群稀疏编码(GSC)框架相结合。具体来说，我们首先将CT重建问题分解为两个子问题，然后使用我们的${L_{1/2}}}} $-正则化NSS去噪进一步提高CT图像质量。我们没有从GSC的角度对非凸问题进行优化，而是基于两种简单但必要的方案，通过低秩最小化重构CT图像，这两种方案在基于GSC的去噪和低秩最小化之间建立了等价关系。进一步，利用加权奇异值阈值(WSVT)算子对得到的非凸${{L_{{1/2}}}} $最小化问题进行优化。在此基础上，利用交替方向乘法器(ADMM)框架，将所提出的去噪方法与CT重建问题相结合。在典型临床CT图像上的大量实验结果表明，我们的方法可以进一步取得比常用方法更好的性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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J. Frankl. Inst.

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