平流扩散问题的受约束局部近似理想限制

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Ahsan Ali, James J. Brannick, Karsten Kahl, Oliver A. Krzysik, Jacob B. Schroder, Ben S. Southworth
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引用次数: 0

摘要

SIAM 科学计算期刊》,提前印刷。 摘要本文的重点是开发一种基于还原的代数多网格(AMG)方法,该方法适用于求解一般(非)对称线性系统,并且从纯平流到纯扩散都具有天然鲁棒性。最初的动力来自于一种新的基于还原的 AMG 方法 [math](局部近似理想限制),这种方法是为解决平流主导问题而开发的。虽然这种新的求解器在平流主导机制下非常有效,但在扩散成为主导的情况下,其性能就会下降。这与以下事实是一致的:一般来说,随着问题规模的增大,基于还原的 AMG 方法往往会出现复杂性和/或收敛率增长的问题,尤其是对于二维或三维的扩散主导型问题。受[math]在平流系统中取得成功的启发,我们在本文中的目标是推广 AIR 框架,以提高求解器在扩散主导系统中的性能。为此,我们提出了一种新方法,将能量最小化 AMG 方法中常用的模式约束与[math]中使用的理想算子局部逼近相结合。由此产生的[math]约束算法能够在平流和扩散问题上实现快速可扩展的收敛。此外,它还能通过积极的粗化在扩散机制中实现标准的低复杂度分层,而这在以前的基于还原的方法中是很难实现的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Constrained Local Approximate Ideal Restriction for Advection-Diffusion Problems
SIAM Journal on Scientific Computing, Ahead of Print.
Abstract. This paper focuses on developing a reduction-based algebraic multigrid (AMG) method that is suitable for solving general (non)symmetric linear systems and is naturally robust from pure advection to pure diffusion. Initial motivation comes from a new reduction-based AMG approach, [math] (local approximate ideal restriction), that was developed for solving advection-dominated problems. Though this new solver is very effective in the advection-dominated regime, its performance degrades in cases where diffusion becomes dominant. This is consistent with the fact that in general, reduction-based AMG methods tend to suffer from growth in complexity and/or convergence rates as the problem size is increased, especially for diffusion-dominated problems in two or three dimensions. Motivated by the success of [math] in the advective regime, our aim in this paper is to generalize the AIR framework with the goal of improving the performance of the solver in diffusion-dominated regimes. To do so, we propose a novel way to combine mode constraints as used commonly in energy-minimization AMG methods with the local approximation of ideal operators used in [math]. The resulting constrained [math] algorithm is able to achieve fast scalable convergence on advective and diffusive problems. In addition, it is able to achieve standard low complexity hierarchies in the diffusive regime through aggressive coarsening, something that was previously difficult for reduction-based methods.
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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