On the use of perfectly matched layers in the presence of long or backward propagating guided elastic waves

Anne Sophie Bonnet-Ben Dhia; Colin Chambeyron; Guillaume Legendre

doi:10.1016/j.wavemoti.2013.08.001

On the use of perfectly matched layers in the presence of long or backward propagating guided elastic waves

Anne Sophie Bonnet-Ben Dhia, Colin Chambeyron, Guillaume Legendre

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

Abstract

An efficient method to compute the scattering of a guided wave by a localized defect, in an elastic waveguide of infinite extent and bounded cross section, is considered. It relies on the use of perfectly matched layers (PML) to reduce the problem to a bounded portion of the guide, allowing for a classical finite element discretization. The difficulty here comes from the existence of backward propagating modes, which are not correctly handled by the PML. We propose a simple strategy, based on finite-dimensional linear algebra arguments and using the knowledge of the modes, to recover a correct approximation to the solution with a low additional cost compared to the standard PML approach. Numerical experiments are presented in the two-dimensional case involving Rayleigh-Lamb modes.

Original language	English
Pages (from-to)	266-283
Number of pages	18
Journal	Wave Motion
Volume	51
Issue number	2
DOIs	https://doi.org/10.1016/j.wavemoti.2013.08.001
Publication status	Published - 1 Jan 2014

Keywords

Backward propagating mode
Elastic waveguide
Perfectly matched layer
Scattering problem

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10.1016/j.wavemoti.2013.08.001

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title = "On the use of perfectly matched layers in the presence of long or backward propagating guided elastic waves",

abstract = "An efficient method to compute the scattering of a guided wave by a localized defect, in an elastic waveguide of infinite extent and bounded cross section, is considered. It relies on the use of perfectly matched layers (PML) to reduce the problem to a bounded portion of the guide, allowing for a classical finite element discretization. The difficulty here comes from the existence of backward propagating modes, which are not correctly handled by the PML. We propose a simple strategy, based on finite-dimensional linear algebra arguments and using the knowledge of the modes, to recover a correct approximation to the solution with a low additional cost compared to the standard PML approach. Numerical experiments are presented in the two-dimensional case involving Rayleigh-Lamb modes.",

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AU - Bonnet-Ben Dhia, Anne Sophie

AU - Chambeyron, Colin

AU - Legendre, Guillaume

PY - 2014/1/1

Y1 - 2014/1/1

N2 - An efficient method to compute the scattering of a guided wave by a localized defect, in an elastic waveguide of infinite extent and bounded cross section, is considered. It relies on the use of perfectly matched layers (PML) to reduce the problem to a bounded portion of the guide, allowing for a classical finite element discretization. The difficulty here comes from the existence of backward propagating modes, which are not correctly handled by the PML. We propose a simple strategy, based on finite-dimensional linear algebra arguments and using the knowledge of the modes, to recover a correct approximation to the solution with a low additional cost compared to the standard PML approach. Numerical experiments are presented in the two-dimensional case involving Rayleigh-Lamb modes.

AB - An efficient method to compute the scattering of a guided wave by a localized defect, in an elastic waveguide of infinite extent and bounded cross section, is considered. It relies on the use of perfectly matched layers (PML) to reduce the problem to a bounded portion of the guide, allowing for a classical finite element discretization. The difficulty here comes from the existence of backward propagating modes, which are not correctly handled by the PML. We propose a simple strategy, based on finite-dimensional linear algebra arguments and using the knowledge of the modes, to recover a correct approximation to the solution with a low additional cost compared to the standard PML approach. Numerical experiments are presented in the two-dimensional case involving Rayleigh-Lamb modes.

KW - Backward propagating mode

KW - Elastic waveguide

KW - Perfectly matched layer

KW - Scattering problem

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SP - 266

EP - 283

JO - Wave Motion

JF - Wave Motion

IS - 2

ER -

On the use of perfectly matched layers in the presence of long or backward propagating guided elastic waves

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Keywords

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