A mixed finite element approach for viscoelastic wave propagation

Eliane Bécache; Abdelaâziz Ezziani; Patrick Joly

doi:10.1007/s10596-005-3772-8

A mixed finite element approach for viscoelastic wave propagation

Eliane Bécache
, Abdelaâziz Ezziani
, Patrick Joly

INRIA Rocquencourt

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

Résumé

In this paper, we are interested in the modeling of wave propagation in viscoelastic media. We present a family of models which generalize the Zener's model. We achieve its mathematical analysis: existence and uniqueness of solutions, energy decay and propagation with finite speed. For the numerical resolution, we extend a mixed finite element method proposed in [8]. This method combines mass lumping with a centered explicit scheme for time discretization. For the resulting scheme, we prove a discrete energy decay result and provide a sufficient stability condition. For the numerical simulation in open domains we adapt the perfectly matched layers techniques to viscoelastic waves [23]. Various numerical results are presented.

langue originale	Anglais
Pages (de - à)	255-299
Nombre de pages	45
journal	Computational Geosciences
Volume	8
Numéro de publication	3
Les DOIs	https://doi.org/10.1007/s10596-005-3772-8
état	Publié - 1 janv. 2005
Modification externe	Oui

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10.1007/s10596-005-3772-8

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title = "A mixed finite element approach for viscoelastic wave propagation",

abstract = "In this paper, we are interested in the modeling of wave propagation in viscoelastic media. We present a family of models which generalize the Zener's model. We achieve its mathematical analysis: existence and uniqueness of solutions, energy decay and propagation with finite speed. For the numerical resolution, we extend a mixed finite element method proposed in [8]. This method combines mass lumping with a centered explicit scheme for time discretization. For the resulting scheme, we prove a discrete energy decay result and provide a sufficient stability condition. For the numerical simulation in open domains we adapt the perfectly matched layers techniques to viscoelastic waves [23]. Various numerical results are presented.",

keywords = "Energy dissipation, Finite velocity propagation, Mixed finite element, Stability analysis, Viscoelastic waves, Zener's model",

author = "Eliane B{\'e}cache and Abdela{\^a}ziz Ezziani and Patrick Joly",

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AU - Ezziani, Abdelaâziz

AU - Joly, Patrick

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N2 - In this paper, we are interested in the modeling of wave propagation in viscoelastic media. We present a family of models which generalize the Zener's model. We achieve its mathematical analysis: existence and uniqueness of solutions, energy decay and propagation with finite speed. For the numerical resolution, we extend a mixed finite element method proposed in [8]. This method combines mass lumping with a centered explicit scheme for time discretization. For the resulting scheme, we prove a discrete energy decay result and provide a sufficient stability condition. For the numerical simulation in open domains we adapt the perfectly matched layers techniques to viscoelastic waves [23]. Various numerical results are presented.

AB - In this paper, we are interested in the modeling of wave propagation in viscoelastic media. We present a family of models which generalize the Zener's model. We achieve its mathematical analysis: existence and uniqueness of solutions, energy decay and propagation with finite speed. For the numerical resolution, we extend a mixed finite element method proposed in [8]. This method combines mass lumping with a centered explicit scheme for time discretization. For the resulting scheme, we prove a discrete energy decay result and provide a sufficient stability condition. For the numerical simulation in open domains we adapt the perfectly matched layers techniques to viscoelastic waves [23]. Various numerical results are presented.

KW - Energy dissipation

KW - Finite velocity propagation

KW - Mixed finite element

KW - Stability analysis

KW - Viscoelastic waves

KW - Zener's model

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DO - 10.1007/s10596-005-3772-8

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SN - 1420-0597

VL - 8

SP - 255

EP - 299

JO - Computational Geosciences

JF - Computational Geosciences

IS - 3

ER -

A mixed finite element approach for viscoelastic wave propagation

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