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Main Authors: Fuhg, Jan N., Jadoon, Asghar, Weeger, Oliver, Seidl, D. Thomas, Jones, Reese E.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2404.15562
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author Fuhg, Jan N.
Jadoon, Asghar
Weeger, Oliver
Seidl, D. Thomas
Jones, Reese E.
author_facet Fuhg, Jan N.
Jadoon, Asghar
Weeger, Oliver
Seidl, D. Thomas
Jones, Reese E.
contents Machine-learning function representations such as neural networks have proven to be excellent constructs for constitutive modeling due to their flexibility to represent highly nonlinear data and their ability to incorporate constitutive constraints, which also allows them to generalize well to unseen data. In this work, we extend a polyconvex hyperelastic neural network framework to thermo-hyperelasticity by specifying the thermodynamic and material theoretic requirements for an expansion of the Helmholtz free energy expressed in terms of deformation invariants and temperature. Different formulations which a priori ensure polyconvexity with respect to deformation and concavity with respect to temperature are proposed and discussed. The physics-augmented neural networks are furthermore calibrated with a recently proposed sparsification algorithm that not only aims to fit the training data but also penalizes the number of active parameters, which prevents overfitting in the low data regime and promotes generalization. The performance of the proposed framework is demonstrated on synthetic data, which illustrate the expected thermomechanical phenomena, and existing temperature-dependent uniaxial tension and tension-torsion experimental datasets.
format Preprint
id arxiv_https___arxiv_org_abs_2404_15562
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Polyconvex neural network models of thermoelasticity
Fuhg, Jan N.
Jadoon, Asghar
Weeger, Oliver
Seidl, D. Thomas
Jones, Reese E.
Soft Condensed Matter
Computational Physics
Machine-learning function representations such as neural networks have proven to be excellent constructs for constitutive modeling due to their flexibility to represent highly nonlinear data and their ability to incorporate constitutive constraints, which also allows them to generalize well to unseen data. In this work, we extend a polyconvex hyperelastic neural network framework to thermo-hyperelasticity by specifying the thermodynamic and material theoretic requirements for an expansion of the Helmholtz free energy expressed in terms of deformation invariants and temperature. Different formulations which a priori ensure polyconvexity with respect to deformation and concavity with respect to temperature are proposed and discussed. The physics-augmented neural networks are furthermore calibrated with a recently proposed sparsification algorithm that not only aims to fit the training data but also penalizes the number of active parameters, which prevents overfitting in the low data regime and promotes generalization. The performance of the proposed framework is demonstrated on synthetic data, which illustrate the expected thermomechanical phenomena, and existing temperature-dependent uniaxial tension and tension-torsion experimental datasets.
title Polyconvex neural network models of thermoelasticity
topic Soft Condensed Matter
Computational Physics
url https://arxiv.org/abs/2404.15562