Adaptive FE–BE coupling for strongly nonlinear transmission problems with Coulomb friction

Heiko Gimperlein; Matthias Maischak; Elmar Schrohe; Ernst P. Stephan

Adaptive FE–BE coupling for strongly nonlinear transmission problems with Coulomb friction

Heiko Gimperlein, Matthias Maischak, Elmar Schrohe, Ernst P. Stephan

Department of Mathematical Sciences

5 Citations (Scopus)

Abstract

We analyze an adaptive finite element/boundary element procedure for scalar elastoplastic interface problems involving friction, where a nonlinear uniformly monotone operator such as the p-Laplacian is coupled to the linear Laplace equation on the exterior domain. The problem is reduced to a boundary/domain variational inequality, a discretized saddle point formulation of which is then solved using the Uzawa algorithm and adaptive mesh refinements based on a gradient recovery scheme. The Galerkin approximations are shown to converge to the unique solution of the variational problem in a suitable product of L^p- and L²-Sobolev spaces.

Original language	English
Journal	Numerische Mathematik
Volume	117
Issue number	2
Pages (from-to)	307-332
ISSN	0029-599X
Publication status	Published - Feb 2011

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title = "Adaptive FE–BE coupling for strongly nonlinear transmission problems with Coulomb friction",

abstract = "We analyze an adaptive finite element/boundary element procedure for scalar elastoplastic interface problems involving friction, where a nonlinear uniformly monotone operator such as the p-Laplacian is coupled to the linear Laplace equation on the exterior domain. The problem is reduced to a boundary/domain variational inequality, a discretized saddle point formulation of which is then solved using the Uzawa algorithm and adaptive mesh refinements based on a gradient recovery scheme. The Galerkin approximations are shown to converge to the unique solution of the variational problem in a suitable product of Lp- and L2-Sobolev spaces.",

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T1 - Adaptive FE–BE coupling for strongly nonlinear transmission problems with Coulomb friction

AU - Gimperlein, Heiko

AU - Maischak, Matthias

AU - Schrohe, Elmar

AU - Stephan, Ernst P.

PY - 2011/2

Y1 - 2011/2

N2 - We analyze an adaptive finite element/boundary element procedure for scalar elastoplastic interface problems involving friction, where a nonlinear uniformly monotone operator such as the p-Laplacian is coupled to the linear Laplace equation on the exterior domain. The problem is reduced to a boundary/domain variational inequality, a discretized saddle point formulation of which is then solved using the Uzawa algorithm and adaptive mesh refinements based on a gradient recovery scheme. The Galerkin approximations are shown to converge to the unique solution of the variational problem in a suitable product of Lp- and L2-Sobolev spaces.

AB - We analyze an adaptive finite element/boundary element procedure for scalar elastoplastic interface problems involving friction, where a nonlinear uniformly monotone operator such as the p-Laplacian is coupled to the linear Laplace equation on the exterior domain. The problem is reduced to a boundary/domain variational inequality, a discretized saddle point formulation of which is then solved using the Uzawa algorithm and adaptive mesh refinements based on a gradient recovery scheme. The Galerkin approximations are shown to converge to the unique solution of the variational problem in a suitable product of Lp- and L2-Sobolev spaces.

M3 - Journal article

SN - 0029-599X

VL - 117

SP - 307

EP - 332

JO - Numerische Mathematik

JF - Numerische Mathematik

IS - 2

ER -

Adaptive FE–BE coupling for strongly nonlinear transmission problems with Coulomb friction

Abstract

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