Crack identification by 3D time-domain elastic or acoustic topological sensitivity

Cédric Bellis; Marc Bonnet

doi:10.1016/j.crme.2009.03.015

Crack identification by 3D time-domain elastic or acoustic topological sensitivity

Cédric Bellis, Marc Bonnet

Department of Mechanics École Polytechnique

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

Abstract

The topological sensitivity analysis, based on the asymptotic behavior of a cost functional associated with the creation of a small trial flaw in a defect-free solid, provides a computationally-fast, non-iterative approach for identifying flaws embedded in solids. This concept is here considered for crack identification using time-dependent measurements on the external boundary. The topological derivative of a cost function under the nucleation of a crack of infinitesimal size is established, in the framework of time-domain elasticity or acoustics. The simplicity and efficiency of the proposed formulation is enhanced by the recourse to an adjoint solution. Numerical results obtained on a 3-D elastodynamic example using the conventional FEM demonstrate the usefulness of the topological derivative as a crack indicator function. To cite this article: C. Bellis, M. Bonnet, C. R. Mecanique 337 (2009).

Original language	English
Pages (from-to)	124-130
Number of pages	7
Journal	Comptes Rendus - Mecanique
Volume	337
Issue number	3
DOIs	https://doi.org/10.1016/j.crme.2009.03.015
Publication status	Published - 1 Jan 2009
Externally published	Yes

Keywords

Adjoint solution
Computational solid mechanics
Crack identification
Elastodynamics
Topological sensitivity

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10.1016/j.crme.2009.03.015

Cite this

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abstract = "The topological sensitivity analysis, based on the asymptotic behavior of a cost functional associated with the creation of a small trial flaw in a defect-free solid, provides a computationally-fast, non-iterative approach for identifying flaws embedded in solids. This concept is here considered for crack identification using time-dependent measurements on the external boundary. The topological derivative of a cost function under the nucleation of a crack of infinitesimal size is established, in the framework of time-domain elasticity or acoustics. The simplicity and efficiency of the proposed formulation is enhanced by the recourse to an adjoint solution. Numerical results obtained on a 3-D elastodynamic example using the conventional FEM demonstrate the usefulness of the topological derivative as a crack indicator function. To cite this article: C. Bellis, M. Bonnet, C. R. Mecanique 337 (2009).",

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AU - Bonnet, Marc

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AB - The topological sensitivity analysis, based on the asymptotic behavior of a cost functional associated with the creation of a small trial flaw in a defect-free solid, provides a computationally-fast, non-iterative approach for identifying flaws embedded in solids. This concept is here considered for crack identification using time-dependent measurements on the external boundary. The topological derivative of a cost function under the nucleation of a crack of infinitesimal size is established, in the framework of time-domain elasticity or acoustics. The simplicity and efficiency of the proposed formulation is enhanced by the recourse to an adjoint solution. Numerical results obtained on a 3-D elastodynamic example using the conventional FEM demonstrate the usefulness of the topological derivative as a crack indicator function. To cite this article: C. Bellis, M. Bonnet, C. R. Mecanique 337 (2009).

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KW - Elastodynamics

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Crack identification by 3D time-domain elastic or acoustic topological sensitivity

Abstract

Keywords

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