Multigrid method for nonlinear poroelasticity equations

Peiyao Luo; C Rodrigo; F. J. Gaspar; C. W. Oosterlee

doi:10.1007/s00791-016-0260-8

Multigrid method for nonlinear poroelasticity equations

Peiyao Luo^*, C Rodrigo, F. J. Gaspar, C. W. Oosterlee

^*Corresponding author for this work

Numerical Analysis

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

12 Citations (Scopus)

44 Downloads (Pure)

Abstract

In this study, a nonlinear multigrid method is applied for solving the system of incompressible poroelasticity equations considering nonlinear hydraulic conductivity. For the unsteady problem, an additional artificial term is utilized to stabilize the solutions when the equations are discretized on collocated grids. We employ two nonlinear multigrid methods, i.e. the “full approximation scheme” and “Newton multigrid” for solving the corresponding system of equations arising after discretization. For the steady case, both homogeneous and heterogeneous cases are solved and two different smoothers are examined to search for an efficient multigrid method. Numerical results show a good convergence performance for all the strategies.

Original language	English
Pages (from-to)	255-265
Number of pages	11
Journal	Computing and Visualization in Science
Volume	17
Issue number	5
DOIs	https://doi.org/10.1007/s00791-016-0260-8
Publication status	Published - 2015

Keywords

Collocated grid
Coupled system
Heterogeneity
Multigrid
Nonlinearity
Poroelasticity
Weibull function

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10.1007/s00791-016-0260-8

10.1007_s00791-016-0260-8Final published version, 1.57 MBLicence: CC BY

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title = "Multigrid method for nonlinear poroelasticity equations",

abstract = "In this study, a nonlinear multigrid method is applied for solving the system of incompressible poroelasticity equations considering nonlinear hydraulic conductivity. For the unsteady problem, an additional artificial term is utilized to stabilize the solutions when the equations are discretized on collocated grids. We employ two nonlinear multigrid methods, i.e. the “full approximation scheme” and “Newton multigrid” for solving the corresponding system of equations arising after discretization. For the steady case, both homogeneous and heterogeneous cases are solved and two different smoothers are examined to search for an efficient multigrid method. Numerical results show a good convergence performance for all the strategies.",

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author = "Peiyao Luo and C Rodrigo and Gaspar, {F. J.} and Oosterlee, {C. W.}",

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T1 - Multigrid method for nonlinear poroelasticity equations

AU - Luo, Peiyao

AU - Rodrigo, C

AU - Gaspar, F. J.

AU - Oosterlee, C. W.

PY - 2015

Y1 - 2015

N2 - In this study, a nonlinear multigrid method is applied for solving the system of incompressible poroelasticity equations considering nonlinear hydraulic conductivity. For the unsteady problem, an additional artificial term is utilized to stabilize the solutions when the equations are discretized on collocated grids. We employ two nonlinear multigrid methods, i.e. the “full approximation scheme” and “Newton multigrid” for solving the corresponding system of equations arising after discretization. For the steady case, both homogeneous and heterogeneous cases are solved and two different smoothers are examined to search for an efficient multigrid method. Numerical results show a good convergence performance for all the strategies.

AB - In this study, a nonlinear multigrid method is applied for solving the system of incompressible poroelasticity equations considering nonlinear hydraulic conductivity. For the unsteady problem, an additional artificial term is utilized to stabilize the solutions when the equations are discretized on collocated grids. We employ two nonlinear multigrid methods, i.e. the “full approximation scheme” and “Newton multigrid” for solving the corresponding system of equations arising after discretization. For the steady case, both homogeneous and heterogeneous cases are solved and two different smoothers are examined to search for an efficient multigrid method. Numerical results show a good convergence performance for all the strategies.

KW - Collocated grid

KW - Coupled system

KW - Heterogeneity

KW - Multigrid

KW - Nonlinearity

KW - Poroelasticity

KW - Weibull function

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JO - Computing and Visualization in Science

JF - Computing and Visualization in Science

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ER -

Multigrid method for nonlinear poroelasticity equations

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