Multiscale finite element analysis of uncertain-but-bounded heterogeneous materials at finite deformation

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

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  • Xidian University
  • University of New South Wales (UNSW)
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OriginalspracheEnglisch
Seiten (von - bis)15-31
Seitenumfang17
FachzeitschriftFinite Elements in Analysis and Design
Jahrgang149
Frühes Online-Datum5 Juli 2018
PublikationsstatusVeröffentlicht - 15 Sept. 2018

Abstract

A new computationally interval homogenization modelling for heterogeneous materials with uncertain-but-bounded parameters is presented in a deformation controlled setting, and the homogenization analysis in the context of elasticity at finite deformation is then addressed by an integrative approach of finite element method with the optimization algorithms where the interval uncertainty in the microstructure of the material is fully considered. Different deformation-controlled boundary conditions are imposed on the representative volume element, and the interval effective quantities involving the tangent tensor and the first Piola–Kirchhoff stress tensor as well as the strain energy together with the effective moduli are obtained. The influences of different uncertain cases on the interval effective quantities are also analyzed. For the purpose of verification, the results from particle swarm optimization (PSO) algorithm are compared with those obtained from genetic algorithm (GA) and Monte-carlo simulation. The feasibility and validity of the proposed modelling method are evidenced by the well-agreed consequences among the above algorithms.

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Multiscale finite element analysis of uncertain-but-bounded heterogeneous materials at finite deformation. / Ma, Juan; Du, Wenyi; Gao, Wei et al.
in: Finite Elements in Analysis and Design, Jahrgang 149, 15.09.2018, S. 15-31.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Ma J, Du W, Gao W, Wriggers P, Xue X. Multiscale finite element analysis of uncertain-but-bounded heterogeneous materials at finite deformation. Finite Elements in Analysis and Design. 2018 Sep 15;149:15-31. Epub 2018 Jul 5. doi: 10.1016/j.finel.2018.06.001
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abstract = "A new computationally interval homogenization modelling for heterogeneous materials with uncertain-but-bounded parameters is presented in a deformation controlled setting, and the homogenization analysis in the context of elasticity at finite deformation is then addressed by an integrative approach of finite element method with the optimization algorithms where the interval uncertainty in the microstructure of the material is fully considered. Different deformation-controlled boundary conditions are imposed on the representative volume element, and the interval effective quantities involving the tangent tensor and the first Piola–Kirchhoff stress tensor as well as the strain energy together with the effective moduli are obtained. The influences of different uncertain cases on the interval effective quantities are also analyzed. For the purpose of verification, the results from particle swarm optimization (PSO) algorithm are compared with those obtained from genetic algorithm (GA) and Monte-carlo simulation. The feasibility and validity of the proposed modelling method are evidenced by the well-agreed consequences among the above algorithms.",
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T1 - Multiscale finite element analysis of uncertain-but-bounded heterogeneous materials at finite deformation

AU - Ma, Juan

AU - Du, Wenyi

AU - Gao, Wei

AU - Wriggers, Peter

AU - Xue, Xiangdong

PY - 2018/9/15

Y1 - 2018/9/15

N2 - A new computationally interval homogenization modelling for heterogeneous materials with uncertain-but-bounded parameters is presented in a deformation controlled setting, and the homogenization analysis in the context of elasticity at finite deformation is then addressed by an integrative approach of finite element method with the optimization algorithms where the interval uncertainty in the microstructure of the material is fully considered. Different deformation-controlled boundary conditions are imposed on the representative volume element, and the interval effective quantities involving the tangent tensor and the first Piola–Kirchhoff stress tensor as well as the strain energy together with the effective moduli are obtained. The influences of different uncertain cases on the interval effective quantities are also analyzed. For the purpose of verification, the results from particle swarm optimization (PSO) algorithm are compared with those obtained from genetic algorithm (GA) and Monte-carlo simulation. The feasibility and validity of the proposed modelling method are evidenced by the well-agreed consequences among the above algorithms.

AB - A new computationally interval homogenization modelling for heterogeneous materials with uncertain-but-bounded parameters is presented in a deformation controlled setting, and the homogenization analysis in the context of elasticity at finite deformation is then addressed by an integrative approach of finite element method with the optimization algorithms where the interval uncertainty in the microstructure of the material is fully considered. Different deformation-controlled boundary conditions are imposed on the representative volume element, and the interval effective quantities involving the tangent tensor and the first Piola–Kirchhoff stress tensor as well as the strain energy together with the effective moduli are obtained. The influences of different uncertain cases on the interval effective quantities are also analyzed. For the purpose of verification, the results from particle swarm optimization (PSO) algorithm are compared with those obtained from genetic algorithm (GA) and Monte-carlo simulation. The feasibility and validity of the proposed modelling method are evidenced by the well-agreed consequences among the above algorithms.

KW - Finite deformation

KW - Finite element method

KW - GA

KW - Interval homogenization

KW - PSO algorithm

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VL - 149

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JO - Finite Elements in Analysis and Design

JF - Finite Elements in Analysis and Design

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