Space-time Multilevel Quadrature Methods and their Application for Cardiac Electrophysiology

IF 2.1 3区工程技术 Q2 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS Siam-Asa Journal on Uncertainty Quantification Pub Date : 2023-12-05 DOI:10.1137/21m1418320

Seif Ben Bader, Helmut Harbrecht, Rolf Krause, Michael D. Multerer, Alessio Quaglino, Marc Schmidlin

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Abstract

SIAM/ASA Journal on Uncertainty Quantification, Volume 11, Issue 4, Page 1329-1356, December 2023.
Abstract. We present a novel approach which aims at high-performance uncertainty quantification for cardiac electrophysiology simulations. Employing the monodomain equation to model the transmembrane potential inside the cardiac cells, we evaluate the effect of spatially correlated perturbations of the heart fibers on the statistics of the resulting quantities of interest. Our methodology relies on a close integration of multilevel quadrature methods, parallel iterative solvers, and space-time finite element discretizations, allowing for a fully parallelized framework in space, time, and stochastics. Extensive numerical studies are presented to evaluate convergence rates and to compare the performance of classical Monte Carlo methods such as standard Monte Carlo (MC) and quasi-Monte Carlo (QMC), as well as multilevel strategies, i.e., multilevel Monte Carlo (MLMC) and multilevel quasi-Monte Carlo (MLQMC) on hierarchies of nested meshes. We especially also employ a recently suggested variant of the multilevel approach for nonnested meshes to deal with a realistic heart geometry.

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时空多层正交方法及其在心脏电生理研究中的应用

SIAM/ASA不确定度量化杂志，第11卷，第4期，1329-1356页，2023年12月。摘要。我们提出了一种新的方法，旨在为心脏电生理模拟提供高性能的不确定度量化。利用单域方程来模拟心脏细胞内的跨膜电位，我们评估了心脏纤维的空间相关扰动对产生的感兴趣量的统计的影响。我们的方法依赖于多层正交方法、并行迭代求解器和时空有限元离散化的紧密集成，允许在空间、时间和随机性上完全并行化的框架。广泛的数值研究提出了评估收敛速度和比较经典蒙特卡罗方法，如标准蒙特卡罗(MC)和准蒙特卡罗(QMC)，以及多层策略，即多层蒙特卡罗(MLMC)和多层拟蒙特卡罗(MLQMC)在嵌套网格层次上的性能。我们还特别采用了最近提出的一种针对非嵌套网格的多层方法的变体来处理逼真的心脏几何形状。

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Siam-Asa Journal on Uncertainty Quantification Mathematics-Statistics and Probability

CiteScore

3.70

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期刊介绍： SIAM/ASA Journal on Uncertainty Quantification (JUQ) publishes research articles presenting significant mathematical, statistical, algorithmic, and application advances in uncertainty quantification, defined as the interface of complex modeling of processes and data, especially characterizations of the uncertainties inherent in the use of such models. The journal also focuses on related fields such as sensitivity analysis, model validation, model calibration, data assimilation, and code verification. The journal also solicits papers describing new ideas that could lead to significant progress in methodology for uncertainty quantification as well as review articles on particular aspects. The journal is dedicated to nurturing synergistic interactions between the mathematical, statistical, computational, and applications communities involved in uncertainty quantification and related areas. JUQ is jointly offered by SIAM and the American Statistical Association.