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Main Authors: Sato, Yuki, Terashima, Yuto Lewis, Kondo, Ruho
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2407.18870
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author Sato, Yuki
Terashima, Yuto Lewis
Kondo, Ruho
author_facet Sato, Yuki
Terashima, Yuto Lewis
Kondo, Ruho
contents Real-world physical systems, like composite materials and porous media, exhibit complex heterogeneities and multiscale nature, posing significant computational challenges. Computational homogenization is useful for predicting macroscopic properties from the microscopic material constitution. It involves defining a representative volume element (RVE), solving governing equations, and evaluating its properties such as conductivity and elasticity. Despite its effectiveness, the approach can be computationally expensive. This study proposes a tensor-train (TT)-based asymptotic homogenization method to address these challenges. By deriving boundary value problems at the microscale and expressing them in the TT format, the proposed method estimates material properties efficiently. We demonstrate its validity and effectiveness through numerical experiments applying the proposed method for homogenization of thermal conductivity and elasticity in two- and three-dimensional materials, offering a promising solution for handling the multiscale nature of heterogeneous systems.
format Preprint
id arxiv_https___arxiv_org_abs_2407_18870
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Efficient computational homogenization via tensor train format
Sato, Yuki
Terashima, Yuto Lewis
Kondo, Ruho
Computational Engineering, Finance, and Science
Real-world physical systems, like composite materials and porous media, exhibit complex heterogeneities and multiscale nature, posing significant computational challenges. Computational homogenization is useful for predicting macroscopic properties from the microscopic material constitution. It involves defining a representative volume element (RVE), solving governing equations, and evaluating its properties such as conductivity and elasticity. Despite its effectiveness, the approach can be computationally expensive. This study proposes a tensor-train (TT)-based asymptotic homogenization method to address these challenges. By deriving boundary value problems at the microscale and expressing them in the TT format, the proposed method estimates material properties efficiently. We demonstrate its validity and effectiveness through numerical experiments applying the proposed method for homogenization of thermal conductivity and elasticity in two- and three-dimensional materials, offering a promising solution for handling the multiscale nature of heterogeneous systems.
title Efficient computational homogenization via tensor train format
topic Computational Engineering, Finance, and Science
url https://arxiv.org/abs/2407.18870