脉动流体力学中Dean-Kawasaki方程的多层蒙特卡罗方法

IF 2.9 2区数学 Q1 MATHEMATICS, APPLIED

SIAM Journal on Numerical Analysis Pub Date : 2025-01-31 DOI:10.1137/23m1617345

Federico Cornalba, Julian Fischer

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引用次数: 0

摘要

SIAM数值分析杂志，第63卷，第1期，262-287页，2025年2月。摘要。波动流体力学的随机偏微分方程是描述多粒子系统波动的有力工具。在本文中，我们开发并分析了Dean-Kawasaki方程的多层蒙特卡罗格式，这是这类SPDEs的关键代表。我们通过分析和数值证明了我们的MLMC方案在Dean-Kawasaki方程的模拟中显著降低了计算成本（相对于标准蒙特卡罗方法）。具体来说，我们将成本的降低与足够大的平均粒子密度联系起来，并表明即使我们有低密度区域的解决方案，也可以获得相当大的成本降低。在二维情况下进行了数值模拟，证实了我们的理论预测。我们的结果完全是根据分布规律而不是根据强空间规范来表述的：这至关重要地允许MLMC加速，尽管Dean-Kawasaki方程是高度奇异的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Multilevel Monte Carlo Methods for the Dean–Kawasaki Equation from Fluctuating Hydrodynamics

SIAM Journal on Numerical Analysis, Volume 63, Issue 1, Page 262-287, February 2025.
Abstract. Stochastic PDEs of fluctuating hydrodynamics are a powerful tool for the description of fluctuations in many-particle systems. In this paper, we develop and analyze a multilevel Monte Carlo (MLMC) scheme for the Dean–Kawasaki equation, a pivotal representative of this class of SPDEs. We prove analytically and demonstrate numerically that our MLMC scheme provides a significant reduction in computational cost (with respect to a standard Monte Carlo method) in the simulation of the Dean–Kawasaki equation. Specifically, we link this reduction in cost to having a sufficiently large average particle density and show that sizeable cost reductions can be obtained even when we have solutions with regions of low density. Numerical simulations are provided in the two-dimensional case, confirming our theoretical predictions. Our results are formulated entirely in terms of the law of distributions rather than in terms of strong spatial norms: this crucially allows for MLMC speed-ups altogether despite the Dean–Kawasaki equation being highly singular.

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来源期刊

SIAM Journal on Numerical Analysis 数学-应用数学

CiteScore

4.80

自引率

6.90%

发文量

110

审稿时长

4-8 weeks

期刊介绍： SIAM Journal on Numerical Analysis (SINUM) contains research articles on the development and analysis of numerical methods. Topics include the rigorous study of convergence of algorithms, their accuracy, their stability, and their computational complexity. Also included are results in mathematical analysis that contribute to algorithm analysis, and computational results that demonstrate algorithm behavior and applicability.