A decoupling method with different subdomain time steps for the nonstationary stokes-darcy model

Li Shan; Haibiao Zheng; William J. Layton

doi:10.1002/num.21720

A decoupling method with different subdomain time steps for the nonstationary stokes-darcy model

Li Shan^*, Haibiao Zheng, William J. Layton

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

125 Scopus citations

Abstract

This report analyzes a multirate, decoupling algorithm, which allows different time steps in the fluid region and the porous region for the nonstationary Stokes-Darcy problem. The method presented requires only one, uncoupled Stokes and Darcy subphysics and subdomain solve per time step. Under a time step restriction of the form â-t ≤ C (physical parameters) we prove stability and convergence of the method. Numerical tests are given to show the convergence result and demonstrate the computational efficiency of the partitioned method. They also show that in the expected case of greater fluid velocities in the free-flow region than in the porous media region, allowing smaller time steps in the subregion with the faster velocities increases both accuracy and efficiency.

Original language	English
Pages (from-to)	549-583
Number of pages	35
Journal	Numerical Methods for Partial Differential Equations
Volume	29
Issue number	2
DOIs	https://doi.org/10.1002/num.21720
State	Published - Mar 2013
Externally published	Yes

Keywords

Stokes-Darcy problem
asynchronous time stepping
decoupling method
multirate method

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title = "A decoupling method with different subdomain time steps for the nonstationary stokes-darcy model",

abstract = "This report analyzes a multirate, decoupling algorithm, which allows different time steps in the fluid region and the porous region for the nonstationary Stokes-Darcy problem. The method presented requires only one, uncoupled Stokes and Darcy subphysics and subdomain solve per time step. Under a time step restriction of the form {\^a}-t ≤ C (physical parameters) we prove stability and convergence of the method. Numerical tests are given to show the convergence result and demonstrate the computational efficiency of the partitioned method. They also show that in the expected case of greater fluid velocities in the free-flow region than in the porous media region, allowing smaller time steps in the subregion with the faster velocities increases both accuracy and efficiency.",

keywords = "Stokes-Darcy problem, asynchronous time stepping, decoupling method, multirate method",

author = "Li Shan and Haibiao Zheng and Layton, \{William J.\}",

year = "2013",

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doi = "10.1002/num.21720",

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pages = "549--583",

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T1 - A decoupling method with different subdomain time steps for the nonstationary stokes-darcy model

AU - Shan, Li

AU - Zheng, Haibiao

AU - Layton, William J.

PY - 2013/3

Y1 - 2013/3

N2 - This report analyzes a multirate, decoupling algorithm, which allows different time steps in the fluid region and the porous region for the nonstationary Stokes-Darcy problem. The method presented requires only one, uncoupled Stokes and Darcy subphysics and subdomain solve per time step. Under a time step restriction of the form â-t ≤ C (physical parameters) we prove stability and convergence of the method. Numerical tests are given to show the convergence result and demonstrate the computational efficiency of the partitioned method. They also show that in the expected case of greater fluid velocities in the free-flow region than in the porous media region, allowing smaller time steps in the subregion with the faster velocities increases both accuracy and efficiency.

AB - This report analyzes a multirate, decoupling algorithm, which allows different time steps in the fluid region and the porous region for the nonstationary Stokes-Darcy problem. The method presented requires only one, uncoupled Stokes and Darcy subphysics and subdomain solve per time step. Under a time step restriction of the form â-t ≤ C (physical parameters) we prove stability and convergence of the method. Numerical tests are given to show the convergence result and demonstrate the computational efficiency of the partitioned method. They also show that in the expected case of greater fluid velocities in the free-flow region than in the porous media region, allowing smaller time steps in the subregion with the faster velocities increases both accuracy and efficiency.

KW - Stokes-Darcy problem

KW - asynchronous time stepping

KW - decoupling method

KW - multirate method

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DO - 10.1002/num.21720

M3 - 文章

AN - SCOPUS:84872929160

SN - 0749-159X

VL - 29

SP - 549

EP - 583

JO - Numerical Methods for Partial Differential Equations

JF - Numerical Methods for Partial Differential Equations

IS - 2

ER -

A decoupling method with different subdomain time steps for the nonstationary stokes-darcy model

Abstract

Keywords

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