超集网格上波浪方程的高阶精确隐式-显式时间步进方案

IF 3.8 2区 物理与天体物理 Q2 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS
Allison M. Carson , Jeffrey W. Banks, William D. Henshaw , Donald W. Schwendeman
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引用次数: 0

摘要

介绍了二阶波方程的新隐式和隐式-显式时间步进方法,并将其应用于在超集网格上离散的二维和三维问题。隐式方案为单步、三阶时间,基于修正方程方法。此外,还开发了二阶和四阶精确方案,并将上风耗散纳入其中,以实现超集网格上的稳定性。全隐式方案在某些应用中非常有用,例如用于求解亥姆霍兹问题的 WaveHoltz 算法,需要非常大的时间步长。有些波传播问题由于局部区域的网格单元较小而在几何上比较僵硬,例如需要网格来解决精细的几何特征,在这种情况下,隐式时间步进方案与显式方案相结合:隐式方案用于包含小单元的组件网格,而显式方案用于其他网格,如背景笛卡尔网格。由此产生的分区隐式-显式方案比在任何地方使用显式方案都要快很多倍。通过分析和数值计算研究了这些方案的精度和稳定性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
High-order accurate implicit-explicit time-stepping schemes for wave equations on overset grids
New implicit and implicit-explicit time-stepping methods for the wave equation in second-order form are described with application to two and three-dimensional problems discretized on overset grids. The implicit schemes are single step, three levels in time, and based on the modified equation approach. Second and fourth-order accurate schemes are developed and they incorporate upwind dissipation for stability on overset grids. The fully implicit schemes are useful for certain applications such as the WaveHoltz algorithm for solving Helmholtz problems where very large time-steps are desired. Some wave propagation problems are geometrically stiff due to localized regions of small grid cells, such as grids needed to resolve fine geometric features, and for these situations the implicit time-stepping scheme is combined with an explicit scheme: the implicit scheme is used for component grids containing small cells while the explicit scheme is used on the other grids such as background Cartesian grids. The resulting partitioned implicit-explicit scheme can be many times faster than using an explicit scheme everywhere. The accuracy and stability of the schemes are studied through analysis and numerical computations.
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来源期刊
Journal of Computational Physics
Journal of Computational Physics 物理-计算机:跨学科应用
CiteScore
7.60
自引率
14.60%
发文量
763
审稿时长
5.8 months
期刊介绍: Journal of Computational Physics thoroughly treats the computational aspects of physical problems, presenting techniques for the numerical solution of mathematical equations arising in all areas of physics. The journal seeks to emphasize methods that cross disciplinary boundaries. The Journal of Computational Physics also publishes short notes of 4 pages or less (including figures, tables, and references but excluding title pages). Letters to the Editor commenting on articles already published in this Journal will also be considered. Neither notes nor letters should have an abstract.
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