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动量网络:用于反问题的快速收敛迭代神经网络。

Momentum-Net: Fast and Convergent Iterative Neural Network for Inverse Problems.

出版信息

IEEE Trans Pattern Anal Mach Intell. 2023 Apr;45(4):4915-4931. doi: 10.1109/TPAMI.2020.3012955. Epub 2023 Mar 10.

DOI:10.1109/TPAMI.2020.3012955
PMID:32750839
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8011286/
Abstract

Iterative neural networks (INN) are rapidly gaining attention for solving inverse problems in imaging, image processing, and computer vision. INNs combine regression NNs and an iterative model-based image reconstruction (MBIR) algorithm, often leading to both good generalization capability and outperforming reconstruction quality over existing MBIR optimization models. This paper proposes the first fast and convergent INN architecture, Momentum-Net, by generalizing a block-wise MBIR algorithm that uses momentum and majorizers with regression NNs. For fast MBIR, Momentum-Net uses momentum terms in extrapolation modules, and noniterative MBIR modules at each iteration by using majorizers, where each iteration of Momentum-Net consists of three core modules: image refining, extrapolation, and MBIR. Momentum-Net guarantees convergence to a fixed-point for general differentiable (non)convex MBIR functions (or data-fit terms) and convex feasible sets, under two asymptomatic conditions. To consider data-fit variations across training and testing samples, we also propose a regularization parameter selection scheme based on the "spectral spread" of majorization matrices. Numerical experiments for light-field photography using a focal stack and sparse-view computational tomography demonstrate that, given identical regression NN architectures, Momentum-Net significantly improves MBIR speed and accuracy over several existing INNs; it significantly improves reconstruction quality compared to a state-of-the-art MBIR method in each application.

摘要

迭代神经网络 (INN) 在医学影像、图像处理和计算机视觉领域的反问题求解中迅速受到关注。INN 结合了回归神经网络和基于迭代的图像重建 (MBIR) 算法,通常具有良好的泛化能力,并在现有 MBIR 优化模型的基础上提高了重建质量。本文提出了第一个快速收敛的 INN 架构 Momentum-Net,它通过回归神经网络推广了一种使用动量和优势函数的分块 MBIR 算法。为了实现快速 MBIR,Momentum-Net 在外推模块中使用动量项,在每个迭代中非迭代 MBIR 模块中使用优势函数,其中 Momentum-Net 的每个迭代由三个核心模块组成:图像精炼、外推和 MBIR。Momentum-Net 在两个渐近条件下保证了对一般可微 (非)凸 MBIR 函数(或数据拟合项)和凸可行集的收敛到一个固定点。为了考虑训练和测试样本中数据拟合的变化,我们还提出了一种基于优势矩阵的“谱展度”的正则化参数选择方案。基于聚焦堆叠的光场摄影和稀疏视图计算层析成像的数值实验表明,在具有相同回归神经网络架构的情况下,Momentum-Net 显著提高了几种现有 INN 的 MBIR 速度和准确性;与每种应用中的最先进的 MBIR 方法相比,它显著提高了重建质量。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9c11/8011286/97016b562cd0/nihms-1681579-f0010.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9c11/8011286/ffcdd17c7e16/nihms-1681579-f0006.jpg
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