逆问题的自适应各向异性贝叶斯网格划分

IF 2 2区数学 Q1 MATHEMATICS, APPLIED

Inverse Problems Pub Date : 2024-02-23 DOI:10.1088/1361-6420/ad2696

A Bocchinfuso, D Calvetti, E Somersalo

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引用次数: 0

摘要

我们考虑的逆问题是，通过对偏微分方程或积分方程描述的连续模型进行离散化，从间接噪声观测中估计分布参数。众所周知，离散化产生的误差会对问题不明确的逆问题产生不利影响，因为离散化误差表现为相关噪声。虽然可以通过精细离散化（例如正则化）来避免这一问题，从而将建模误差水平降至低于外生噪声的水平，但处理额外自由度所需的计算资源可能会大幅增加，以至于需要高性能计算环境。按照早先的想法，我们主张将离散化作为逆问题的未知数之一，与解一起迭代更新。在这种方法中，只有在当前网格的表示能力不足时，才会有选择性地细化离散化，而离散化是根据基本度量定义的。在本文中，我们允许度量和网格是各向异性的，并证明这将显著减少内存分配和计算时间。

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Adaptive anisotropic Bayesian meshing for inverse problems

We consider inverse problems estimating distributed parameters from indirect noisy observations through discretization of continuum models described by partial differential or integral equations. It is well understood that errors arising from the discretization can be detrimental for ill-posed inverse problems, as discretization error behaves as correlated noise. While this problem can be avoided with a discretization fine enough to decrease the modeling error level below that of the exogenous noise that is addressed, e.g. by regularization, the computational resources needed to deal with the additional degrees of freedom may increase so much as to require high performance computing environments. Following an earlier idea, we advocate the notion of the discretization as one of the unknowns of the inverse problem, which is updated iteratively together with the solution. In this approach, the discretization, defined in terms of an underlying metric, is refined selectively only where the representation power of the current mesh is insufficient. In this paper we allow the metrics and meshes to be anisotropic, and we show that this leads to significant reduction of memory allocation and computing time.

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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.