A simple machine learning-based framework for faster multi-scale simulations of path-independent materials at large strains

A simple machine learning-based framework for faster multi-scale simulations of path-independent materials at large strains

Coupled multi-scale finite element analyses have gained traction over the last years due to the increasing available computational resources. Nevertheless, in the pursuit of accurate results within a reasonable time frame, replacing these high-fidelity micromechanical simulations with reduced-order...

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Bibliographic Details
Main Authors: Andrade Pires, F.M (Author), Cardoso Coelho, R.P (Author), Cardoso, J.S (Author), Carvalho Alves, A.F (Author), Couto Carneiro, A.M (Author)
Format: Article
Language:English
Published: Elsevier B.V. 2023
Subjects:
Elasticity
Equilibrium problem
Finite element analyse
Large strains
Linear regression
Machine learning
Machine-learning
Multiscale modeling
Multi-scale modelling
Multi-scale simulation
Multi-scales
Neural networks
Neural-networks
Regression analysis
RVE
Simple++
Strain
Online Access:View Fulltext in Publisher
View in Scopus
Description
Summary:Coupled multi-scale finite element analyses have gained traction over the last years due to the increasing available computational resources. Nevertheless, in the pursuit of accurate results within a reasonable time frame, replacing these high-fidelity micromechanical simulations with reduced-order data-driven models has been explored recently by the modelling community. In this work, two classes of machine learning models are trained for a porous hyperelastic microstructure to predict (i) whether the microscopic equilibrium problem is likely to fail and (ii) the stress–strain response. The former may be used to identify critical macroscopic points where one may fall back to the high-fidelity analysis and possibly apply convergence bowl-widening techniques. For the latter, both a linear regression with polynomial features and artificial Neural Networks have been used, and the required stress–strain derivatives for solving the equilibrium problem have been derived analytically. A weight regularisation is introduced to stabilise the tangent operator and several strategies are discussed for imposing null stresses in undeformed configurations for both regression models. The regression techniques, here analysed exclusively in the context of porous hyperelastic materials, evidence very promising prospects to accelerate multi-scale analyses of solids under large deformation. © 2023 The Author(s)
ISBN:0168874X (ISSN)
DOI:10.1016/j.finel.2023.103956

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