多尺度演化偏微分方程的自适应时间分裂方法

Q4 Mathematics

Confluentes Mathematici Pub Date : 2011-04-19 DOI:10.1142/S1793744211000412

S. Descombes, Max Duarte, T. Dumont, V. Louvet, M. Massot

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引用次数: 27

摘要

本文介绍了一种用于求解刚性进化偏微分方程的自适应时间分裂技术，该技术保证了仿真的有效误差控制，而不依赖于高度非定常问题的最快物理时间尺度。该策略考虑了二阶Strang方法和另一种低阶嵌入分裂方案，该方案考虑了时空多尺度现象所具有的刚度可能导致的阶损失。然后，该方案建立在对该方法的精确数值分析和互补数值过程的基础上，旨在克服基于低阶嵌入方法的自适应时间步进方案的经典限制，每当渐近估计无法预测问题的动力学时。通过对来自非线性化学动力学模型的刚性传播波以及高多尺度纳秒重复脉冲气体放电的数值模拟，评估了该方法在控制积分误差方面的性能，从而证明了该方法能够一致地描述广泛的时间尺度和连续放电/放电后阶段的不同物理场景。

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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Adaptive time splitting method for multi-scale evolutionary partial differential equations

This paper introduces an adaptive time splitting technique for the solution of stiff evolutionary PDEs that guarantees an effective error control of the simulation, independent of the fastest physical time scale for highly unsteady problems. The strategy considers a second-order Strang method and another lower order embedded splitting scheme that takes into account potential loss of order due to the stiffness featured by time-space multi-scale phenomena. The scheme is then built upon a precise numerical analysis of the method and a complementary numerical procedure, conceived to overcome classical restrictions of adaptive time stepping schemes based on lower order embedded methods, whenever asymptotic estimates fail to predict the dynamics of the problem. The performance of the method in terms of control of integration errors is evaluated by numerical simulations of stiff propagating waves coming from nonlinear chemical dynamics models as well as highly multi-scale nanosecond repetitively pulsed gas discharges, which allow to illustrate the method capabilities to consistently describe a broad spectrum of time scales and different physical scenarios for consecutive discharge/post-discharge phases.

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来源期刊

Confluentes Mathematici Mathematics-Mathematics (miscellaneous)

CiteScore

0.60

自引率

0.00%

发文量

期刊介绍： Confluentes Mathematici is a mathematical research journal. Since its creation in 2009 by the Institut Camille Jordan UMR 5208 and the Unité de Mathématiques Pures et Appliquées UMR 5669 of the Université de Lyon, it reflects the wish of the mathematical community of Lyon—Saint-Étienne to participate in the new forms of scientific edittion. The journal is electronic only, fully open acces and without author charges. The journal aims to publish high quality mathematical research articles in English, French or German. All domains of Mathematics (pure and applied) and Mathematical Physics will be considered, as well as the History of Mathematics. Confluentes Mathematici also publishes survey articles. Authors are asked to pay particular attention to the expository style of their article, in order to be understood by all the communities concerned.