Unfolded Proximal Neural Networks for Robust Image Gaussian Denoising

Hoang Trieu Vy Le;Audrey Repetti;Nelly Pustelnik
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Abstract

A common approach to solve inverse imaging problems relies on finding a maximum a posteriori (MAP) estimate of the original unknown image, by solving a minimization problem. In this context, iterative proximal algorithms are widely used, enabling to handle non-smooth functions and linear operators. Recently, these algorithms have been paired with deep learning strategies, to further improve the estimate quality. In particular, proximal neural networks (PNNs) have been introduced, obtained by unrolling a proximal algorithm as for finding a MAP estimate, but over a fixed number of iterations, with learned linear operators and parameters. As PNNs are based on optimization theory, they are very flexible, and can be adapted to any image restoration task, as soon as a proximal algorithm can solve it. They further have much lighter architectures than traditional networks. In this article we propose a unified framework to build PNNs for the Gaussian denoising task, based on both the dual-FB and the primal-dual Chambolle-Pock algorithms. We further show that accelerated inertial versions of these algorithms enable skip connections in the associated NN layers. We propose different learning strategies for our PNN framework, and investigate their robustness (Lipschitz property) and denoising efficiency. Finally, we assess the robustness of our PNNs when plugged in a forward-backward algorithm for an image deblurring problem.
用于鲁棒图像高斯去噪的折叠近端神经网络
解决逆成像问题的常用方法是通过解决最小化问题,找到原始未知图像的最大后验(MAP)估计值。在这种情况下,迭代近似算法被广泛使用,能够处理非光滑函数和线性算子。最近,这些算法与深度学习策略搭配使用,进一步提高了估计质量。特别是,近端神经网络(PNN)被引入,它是通过展开近端算法来获得的,就像寻找 MAP 估计值一样,但要经过固定次数的迭代,并使用学习到的线性算子和参数。由于 PNN 以优化理论为基础,因此非常灵活,只要近似算法能够解决,就能适用于任何图像修复任务。与传统网络相比,它们的架构更加轻巧。在这篇文章中,我们提出了一个统一的框架,以双 FB 算法和原始双 Chambolle-Pock 算法为基础,为高斯去噪任务构建 PNN。我们进一步证明,这些算法的加速惯性版本可以在相关的 NN 层中实现跳过连接。我们为 PNN 框架提出了不同的学习策略,并研究了它们的鲁棒性(Lipschitz 属性)和去噪效率。最后,我们评估了我们的 PNN 在插入图像去模糊问题的前向后向算法时的鲁棒性。
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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