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Autores principales: Mirramezani, Mehran, Meeussen, Anne S., Bertoldi, Katia, Orbanz, Peter, Adams, Ryan P.
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2410.02385
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author Mirramezani, Mehran
Meeussen, Anne S.
Bertoldi, Katia
Orbanz, Peter
Adams, Ryan P.
author_facet Mirramezani, Mehran
Meeussen, Anne S.
Bertoldi, Katia
Orbanz, Peter
Adams, Ryan P.
contents Mechanical meta-materials are solids whose geometric structure results in exotic nonlinear behaviors that are not typically achievable via homogeneous materials. We show how to drastically expand the design space of a class of mechanical meta-materials known as cellular solids, by generalizing beyond translational symmetry. This is made possible by transforming a reference geometry according to a divergence free flow that is parameterized by a neural network and equivariant under the relevant symmetry group. We show how to construct flows equivariant to the space groups, despite the fact that these groups are not compact. Coupling this flow with a differentiable nonlinear mechanics simulator allows us to represent a much richer set of cellular solids than was previously possible. These materials can be optimized to exhibit desirable mechanical properties such as negative Poisson's ratios or to match target stress-strain curves. We validate these new designs in simulation and by fabricating real-world prototypes. We find that designs with higher-order symmetries can exhibit a wider range of behaviors.
format Preprint
id arxiv_https___arxiv_org_abs_2410_02385
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Designing Mechanical Meta-Materials by Learning Equivariant Flows
Mirramezani, Mehran
Meeussen, Anne S.
Bertoldi, Katia
Orbanz, Peter
Adams, Ryan P.
Computational Engineering, Finance, and Science
Mechanical meta-materials are solids whose geometric structure results in exotic nonlinear behaviors that are not typically achievable via homogeneous materials. We show how to drastically expand the design space of a class of mechanical meta-materials known as cellular solids, by generalizing beyond translational symmetry. This is made possible by transforming a reference geometry according to a divergence free flow that is parameterized by a neural network and equivariant under the relevant symmetry group. We show how to construct flows equivariant to the space groups, despite the fact that these groups are not compact. Coupling this flow with a differentiable nonlinear mechanics simulator allows us to represent a much richer set of cellular solids than was previously possible. These materials can be optimized to exhibit desirable mechanical properties such as negative Poisson's ratios or to match target stress-strain curves. We validate these new designs in simulation and by fabricating real-world prototypes. We find that designs with higher-order symmetries can exhibit a wider range of behaviors.
title Designing Mechanical Meta-Materials by Learning Equivariant Flows
topic Computational Engineering, Finance, and Science
url https://arxiv.org/abs/2410.02385