Robust method for identifying material parameters based on virtual fields in elastodynamics

Clément Touzeau; Benoît Magnain; Gilles Lubineau; Eric Florentin

doi:10.1016/j.camwa.2018.08.005

Robust method for identifying material parameters based on virtual fields in elastodynamics

Clément Touzeau, Benoît Magnain, Gilles Lubineau, Eric Florentin

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

Abstract

We develop an inverse method with the purpose of extracting elastic properties of materials in the framework of transient dynamics. To this end, we create a small linear system based on a set of well-chosen time-dependent virtual fields (VF) and measurement data. The parameters are the solutions of this system and can be quickly extracted. We compare this new method with the classical finite element model updating (FEMU) method for different case studies. In our study, the measurements are synthetic, i.e, they are calculated using a fine finite element (FE) model. Uniform white noise is added to model measurement uncertainties. Results, based on Monte Carlo simulations, show that our method is more robust and accurate than the FEMU method for an acceptable noise level. Our new method appears well-adapted to linear elasticity in transient dynamics.

Original language	English (US)
Pages (from-to)	3021-3042
Number of pages	22
Journal	Computers & Mathematics with Applications
Volume	77
Issue number	11
DOIs	https://doi.org/10.1016/j.camwa.2018.08.005
State	Published - Aug 22 2018

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KAUST Repository Item: Exported on 2020-10-01

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10.1016/j.camwa.2018.08.005

Cite this

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title = "Robust method for identifying material parameters based on virtual fields in elastodynamics",

abstract = "We develop an inverse method with the purpose of extracting elastic properties of materials in the framework of transient dynamics. To this end, we create a small linear system based on a set of well-chosen time-dependent virtual fields (VF) and measurement data. The parameters are the solutions of this system and can be quickly extracted. We compare this new method with the classical finite element model updating (FEMU) method for different case studies. In our study, the measurements are synthetic, i.e, they are calculated using a fine finite element (FE) model. Uniform white noise is added to model measurement uncertainties. Results, based on Monte Carlo simulations, show that our method is more robust and accurate than the FEMU method for an acceptable noise level. Our new method appears well-adapted to linear elasticity in transient dynamics.",

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T1 - Robust method for identifying material parameters based on virtual fields in elastodynamics

AU - Touzeau, Clément

AU - Magnain, Benoît

AU - Lubineau, Gilles

AU - Florentin, Eric

N1 - KAUST Repository Item: Exported on 2020-10-01

PY - 2018/8/22

Y1 - 2018/8/22

N2 - We develop an inverse method with the purpose of extracting elastic properties of materials in the framework of transient dynamics. To this end, we create a small linear system based on a set of well-chosen time-dependent virtual fields (VF) and measurement data. The parameters are the solutions of this system and can be quickly extracted. We compare this new method with the classical finite element model updating (FEMU) method for different case studies. In our study, the measurements are synthetic, i.e, they are calculated using a fine finite element (FE) model. Uniform white noise is added to model measurement uncertainties. Results, based on Monte Carlo simulations, show that our method is more robust and accurate than the FEMU method for an acceptable noise level. Our new method appears well-adapted to linear elasticity in transient dynamics.

AB - We develop an inverse method with the purpose of extracting elastic properties of materials in the framework of transient dynamics. To this end, we create a small linear system based on a set of well-chosen time-dependent virtual fields (VF) and measurement data. The parameters are the solutions of this system and can be quickly extracted. We compare this new method with the classical finite element model updating (FEMU) method for different case studies. In our study, the measurements are synthetic, i.e, they are calculated using a fine finite element (FE) model. Uniform white noise is added to model measurement uncertainties. Results, based on Monte Carlo simulations, show that our method is more robust and accurate than the FEMU method for an acceptable noise level. Our new method appears well-adapted to linear elasticity in transient dynamics.

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UR - https://www.sciencedirect.com/science/article/pii/S0898122118304231

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DO - 10.1016/j.camwa.2018.08.005

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SP - 3021

EP - 3042

JO - Computers & Mathematics with Applications

JF - Computers & Mathematics with Applications

IS - 11

ER -

Robust method for identifying material parameters based on virtual fields in elastodynamics

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