Iterative solvers for 3D linear and nonlinear elasticity problems: Displacement and mixed formulations

Abderrahman El Maliki; Michel Fortin; Nicolas Tardieu; Andŕe Fortin

doi:10.1002/nme.2894

Iterative solvers for 3D linear and nonlinear elasticity problems: Displacement and mixed formulations

Abderrahman El Maliki
, Michel Fortin
, Nicolas Tardieu
, Andŕe Fortin

Rennes et Université Laval (Canada)
LaMSID/CNRS (UMR 2932)

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

We present new iterative solvers for large-scale linear algebraic systems arising from the finite element discretization of the elasticity equations. We focus on the numerical solution of 3D elasticity problems discretized by quadratic tetrahedral finite elements and we show that second-order accuracy can be obtained at very small overcost with respect to first-order (linear) elements. Different Krylov subspace methods are tested on various meshes including elements with small aspect ratio. We first construct a hierarchical preconditioner for the displacement formulation specifically designed for quadratic discretizations. We then develop efficient tools for preconditioning the 2×2 block symmetric indefinite linear system arising from mixed (displacement-pressure) formulations. Finally, we present some numerical results to illustrate the potential of the proposed methods.

langue originale	Anglais
Pages (de - à)	1780-1802
Nombre de pages	23
journal	International Journal for Numerical Methods in Engineering
Volume	83
Numéro de publication	13
Les DOIs	https://doi.org/10.1002/nme.2894
état	Publié - 24 sept. 2010
Modification externe	Oui

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title = "Iterative solvers for 3D linear and nonlinear elasticity problems: Displacement and mixed formulations",

abstract = "We present new iterative solvers for large-scale linear algebraic systems arising from the finite element discretization of the elasticity equations. We focus on the numerical solution of 3D elasticity problems discretized by quadratic tetrahedral finite elements and we show that second-order accuracy can be obtained at very small overcost with respect to first-order (linear) elements. Different Krylov subspace methods are tested on various meshes including elements with small aspect ratio. We first construct a hierarchical preconditioner for the displacement formulation specifically designed for quadratic discretizations. We then develop efficient tools for preconditioning the 2×2 block symmetric indefinite linear system arising from mixed (displacement-pressure) formulations. Finally, we present some numerical results to illustrate the potential of the proposed methods.",

keywords = "Block symmetric indefinite preconditioner, Conjugate gradient-like methods, Hierarchical preconditioner, Hierarchical quadratic basis, Linear and nonlinear elasticity, Mixed formulation",

author = "\{El Maliki\}, Abderrahman and Michel Fortin and Nicolas Tardieu and And{\'r}e Fortin",

year = "2010",

month = sep,

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doi = "10.1002/nme.2894",

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volume = "83",

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journal = "International Journal for Numerical Methods in Engineering",

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TY - JOUR

T1 - Iterative solvers for 3D linear and nonlinear elasticity problems

T2 - Displacement and mixed formulations

AU - El Maliki, Abderrahman

AU - Fortin, Michel

AU - Tardieu, Nicolas

AU - Fortin, Andŕe

PY - 2010/9/24

Y1 - 2010/9/24

N2 - We present new iterative solvers for large-scale linear algebraic systems arising from the finite element discretization of the elasticity equations. We focus on the numerical solution of 3D elasticity problems discretized by quadratic tetrahedral finite elements and we show that second-order accuracy can be obtained at very small overcost with respect to first-order (linear) elements. Different Krylov subspace methods are tested on various meshes including elements with small aspect ratio. We first construct a hierarchical preconditioner for the displacement formulation specifically designed for quadratic discretizations. We then develop efficient tools for preconditioning the 2×2 block symmetric indefinite linear system arising from mixed (displacement-pressure) formulations. Finally, we present some numerical results to illustrate the potential of the proposed methods.

AB - We present new iterative solvers for large-scale linear algebraic systems arising from the finite element discretization of the elasticity equations. We focus on the numerical solution of 3D elasticity problems discretized by quadratic tetrahedral finite elements and we show that second-order accuracy can be obtained at very small overcost with respect to first-order (linear) elements. Different Krylov subspace methods are tested on various meshes including elements with small aspect ratio. We first construct a hierarchical preconditioner for the displacement formulation specifically designed for quadratic discretizations. We then develop efficient tools for preconditioning the 2×2 block symmetric indefinite linear system arising from mixed (displacement-pressure) formulations. Finally, we present some numerical results to illustrate the potential of the proposed methods.

KW - Block symmetric indefinite preconditioner

KW - Conjugate gradient-like methods

KW - Hierarchical preconditioner

KW - Hierarchical quadratic basis

KW - Linear and nonlinear elasticity

KW - Mixed formulation

U2 - 10.1002/nme.2894

DO - 10.1002/nme.2894

M3 - Article

AN - SCOPUS:77956832775

SN - 0029-5981

VL - 83

SP - 1780

EP - 1802

JO - International Journal for Numerical Methods in Engineering

JF - International Journal for Numerical Methods in Engineering

IS - 13

ER -

Iterative solvers for 3D linear and nonlinear elasticity problems: Displacement and mixed formulations

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