Related papers: Equivariant graph convolutional neural networks for the representation of homogenized anisotropic microstructural mechanical response

Equivariant graph convolutional neural networks for the representation of homogenized anisotropic microstructural mechanical response

URL: http://arxiv.org/abs/2404.17584v1
Date: Fri, 5 Apr 2024 14:49:01 GMT
Title: Equivariant graph convolutional neural networks for the representation of homogenized anisotropic microstructural mechanical response
Authors: Ravi Patel, Cosmin Safta, Reese E. Jones,
Abstract summary: Composite materials with different microstructural material symmetries are common in engineering applications. We provide neural network architectures that provide effective homogenization models of materials with anisotropic components.
Score: 1.283555556182245
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Composite materials with different microstructural material symmetries are common in engineering applications where grain structure, alloying and particle/fiber packing are optimized via controlled manufacturing. In fact these microstructural tunings can be done throughout a part to achieve functional gradation and optimization at a structural level. To predict the performance of particular microstructural configuration and thereby overall performance, constitutive models of materials with microstructure are needed. In this work we provide neural network architectures that provide effective homogenization models of materials with anisotropic components. These models satisfy equivariance and material symmetry principles inherently through a combination of equivariant and tensor basis operations. We demonstrate them on datasets of stochastic volume elements with different textures and phases where the material undergoes elastic and plastic deformation, and show that the these network architectures provide significant performance improvements.

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