Algebraic Multigrid Methods for Metric-Perturbed Coupled Problems

IF 3 2区数学 Q1 MATHEMATICS, APPLIED SIAM Journal on Scientific Computing Pub Date : 2024-05-02 DOI:10.1137/23m1572076

Ana Budiša, Xiaozhe Hu, Miroslav Kuchta, Kent-Andre Mardal, Ludmil Zikatanov

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Abstract

SIAM Journal on Scientific Computing, Volume 46, Issue 3, Page A1461-A1486, June 2024.
Abstract. We develop multilevel methods for interface-driven multiphysics problems that can be coupled across dimensions and where complexity and strength of the interface coupling deteriorates the performance of standard methods. We focus on aggregation-based algebraic multigrid methods with custom smoothers that preserve the coupling information on each coarse level. We prove that, with the proper choice of subspace splitting, we obtain uniform convergence in discretization and physical parameters in the two-level setting. Additionally, we show parameter robustness and scalability with regard to the number of the degrees of freedom of the system on several numerical examples related to the biophysical processes in the brain, namely, the electric signaling in excitable tissue modeled by bidomain, the extracellular-membrane-intracellular (EMI) model, and reduced EMI equations. Reproducibility of computational results. This paper has been awarded the “SIAM Reproducibility Badge: Code and data available” as a recognition that the authors have followed reproducibility principles valued by SISC and the scientific computing community. Code and data that allow readers to reproduce the results in this paper are available at https://github.com/anabudisa/metric-amg-examples and in the supplementary materials (metric-amg-examples-master.zip [30KB]).

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针对度量扰动耦合问题的代数多网格方法

SIAM 科学计算期刊》，第 46 卷第 3 期，第 A1461-A1486 页，2024 年 6 月。摘要。我们为界面驱动的多物理场问题开发了多层次方法，这些问题可以跨维度耦合，而界面耦合的复杂性和强度会降低标准方法的性能。我们的重点是基于聚合的代数多网格方法，该方法带有自定义平滑器，可保留每个粗级别上的耦合信息。我们证明，通过适当选择子空间分割，我们可以在两级设置中获得离散化和物理参数的均匀收敛。此外，我们还通过几个与大脑生物物理过程有关的数值示例，即双域模型、细胞外-膜-细胞内（EMI）模型和简化的 EMI 方程，展示了参数的鲁棒性和系统自由度数量的可扩展性。计算结果的可重复性。本文被授予 "SIAM 可重复性徽章"：代码和数据可用"，以表彰作者遵循了 SISC 和科学计算界重视的可重现性原则。读者可在 https://github.com/anabudisa/metric-amg-examples 和补充材料（metric-amg-examples-master.zip [30KB]）中获取代码和数据，以便重现本文中的结果。

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来源期刊

SIAM Journal on Scientific Computing 数学-应用数学

CiteScore

5.50

自引率

3.20%

发文量

209

审稿时长

1 months

期刊介绍： The purpose of SIAM Journal on Scientific Computing (SISC) is to advance computational methods for solving scientific and engineering problems. SISC papers are classified into three categories: 1. Methods and Algorithms for Scientific Computing: Papers in this category may include theoretical analysis, provided that the relevance to applications in science and engineering is demonstrated. They should contain meaningful computational results and theoretical results or strong heuristics supporting the performance of new algorithms. 2. Computational Methods in Science and Engineering: Papers in this section will typically describe novel methodologies for solving a specific problem in computational science or engineering. They should contain enough information about the application to orient other computational scientists but should omit details of interest mainly to the applications specialist. 3. Software and High-Performance Computing: Papers in this category should concern the novel design and development of computational methods and high-quality software, parallel algorithms, high-performance computing issues, new architectures, data analysis, or visualization. The primary focus should be on computational methods that have potentially large impact for an important class of scientific or engineering problems.