对艾伦-卡恩方程的高效高分辨率解进行卷积张量分解

IF 6.9 1区 工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY Computer Methods in Applied Mechanics and Engineering Pub Date : 2024-11-07 DOI:10.1016/j.cma.2024.117507
Ye Lu , Chaoqian Yuan , Han Guo
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引用次数: 0

摘要

本文提出了一种基于卷积张量分解的模型还原法,用于求解 Allen-Cahn 方程。Allen-Cahn 方程通常用于描述材料中的相分离或反相边界运动。当涉及高分辨率网格和大时间尺度积分时,其求解非常耗时。为了解决这些问题,我们开发了卷积张量分解法,并结合稳定的半隐式时间积分方案。该方法为 Allen-Cahn 问题的高分辨率求解提供了一个强大的计算框架,并允许在不违反离散能量定律的情况下使用相对较大的时间增量进行时间积分。为了进一步提高该方法的效率和鲁棒性,还提出了一种自适应算法。数值示例证实了该方法在二维和三维问题中的效率。与有限元方法相比,该方法处理高分辨率问题的速度提高了几个数量级。所提出的计算框架为在大体积高分辨率网格上模拟材料中复杂微结构的形成提供了大量机会,同时大大降低了计算成本。
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Convolution tensor decomposition for efficient high-resolution solutions to the Allen–Cahn equation
This paper presents a convolution tensor decomposition based model reduction method for solving the Allen–Cahn equation. The Allen–Cahn equation is usually used to characterize phase separation or the motion of anti-phase boundaries in materials. Its solution is time-consuming when high-resolution meshes and large time scale integration are involved. To resolve these issues, the convolution tensor decomposition method is developed, in conjunction with a stabilized semi-implicit scheme for time integration. The development enables a powerful computational framework for high-resolution solutions of Allen–Cahn problems, and allows the use of relatively large time increments for time integration without violating the discrete energy law. To further improve the efficiency and robustness of the method, an adaptive algorithm is also proposed. Numerical examples have confirmed the efficiency of the method in both 2D and 3D problems. Orders-of-magnitude speedups were obtained with the method for high-resolution problems, compared to the finite element method. The proposed computational framework opens numerous opportunities for simulating complex microstructure formation in materials on large-volume high-resolution meshes at a deeply reduced computational cost.
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来源期刊
CiteScore
12.70
自引率
15.30%
发文量
719
审稿时长
44 days
期刊介绍: Computer Methods in Applied Mechanics and Engineering stands as a cornerstone in the realm of computational science and engineering. With a history spanning over five decades, the journal has been a key platform for disseminating papers on advanced mathematical modeling and numerical solutions. Interdisciplinary in nature, these contributions encompass mechanics, mathematics, computer science, and various scientific disciplines. The journal welcomes a broad range of computational methods addressing the simulation, analysis, and design of complex physical problems, making it a vital resource for researchers in the field.
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