自适应 Bregman-Kaczmarz：精确解决具有独立噪声的线性逆问题的方法

IF 2 2区数学 Q1 MATHEMATICS, APPLIED

Inverse Problems Pub Date : 2024-07-24 DOI:10.1088/1361-6420/ad5fb1

Lionel Tondji, Idriss Tondji and Dirk Lorenz

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引用次数: 0

摘要

我们考虑用块 Bregman-Kaczmarz 方法来解决有限维线性逆问题。块 Bregman-Kaczmarz 方法使用线性系统的块，并只对这些块执行迭代步骤。我们假定一种称为独立噪声的噪声模型，即每次该方法对某个区块执行一个步骤时，都会获得右侧相应部分的噪声样本，该样本受到与该方法之前所有步骤无关的新噪声的污染。我们可以将这些噪声模型视为每次使用时对相应区块进行的全新噪声测量。在此框架下，我们能够证明，块 Bregman-Kaczmarz 方法的自适应步长经过精心选择后，能够收敛到线性逆问题的精确解。这种自适应步长的普通形式依赖于未知量（如到解的布雷格曼距离），但我们展示了一种方法，即如何纯粹根据给定数据估算这些量。我们在数值实验中说明了这一发现，并证实这些启发式估计能带来有效的步长。

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Adaptive Bregman–Kaczmarz: an approach to solve linear inverse problems with independent noise exactly

We consider the block Bregman–Kaczmarz method for finite dimensional linear inverse problems. The block Bregman–Kaczmarz method uses blocks of the linear system and performs iterative steps with these blocks only. We assume a noise model that we call independent noise, i.e. each time the method performs a step for some block, one obtains a noisy sample of the respective part of the right-hand side which is contaminated with new noise that is independent of all previous steps of the method. One can view these noise models as making a fresh noisy measurement of the respective block each time it is used. In this framework, we are able to show that a well-chosen adaptive stepsize of the block Bregman–Kaczmarz method is able to converge to the exact solution of the linear inverse problem. The plain form of this adaptive stepsize relies on unknown quantities (like the Bregman distance to the solution), but we show a way how these quantities can be estimated purely from given data. We illustrate the finding in numerical experiments and confirm that these heuristic estimates lead to effective stepsizes.

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来源期刊

Inverse Problems 数学-物理：数学物理

CiteScore

4.40

自引率

14.30%

发文量

115

审稿时长

2.3 months

期刊介绍： An interdisciplinary journal combining mathematical and experimental papers on inverse problems with theoretical, numerical and practical approaches to their solution. As well as applied mathematicians, physical scientists and engineers, the readership includes those working in geophysics, radar, optics, biology, acoustics, communication theory, signal processing and imaging, among others. The emphasis is on publishing original contributions to methods of solving mathematical, physical and applied problems. To be publishable in this journal, papers must meet the highest standards of scientific quality, contain significant and original new science and should present substantial advancement in the field. Due to the broad scope of the journal, we require that authors provide sufficient introductory material to appeal to the wide readership and that articles which are not explicitly applied include a discussion of possible applications.