Physically recurrent neural network for rate and path-dependent heterogeneous materials in a finite strain framework

M.A. Maia*, I.B.C.M. Rocha, D. Kovačević, F. P. van der Meer

*Corresponding author for this work

Research output: Contribution to journalArticleScientificpeer-review

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Abstract

In this work, a hybrid physics-based data-driven surrogate model for the microscale analysis of heterogeneous material is investigated. The proposed model benefits from the physics-based knowledge contained in the constitutive models used in the full-order micromodel by embedding the material models in a neural network. Following previous developments, this paper extends the applicability of the physically recurrent neural network (PRNN) by introducing an architecture suitable for rate-dependent materials in a finite strain framework. In this model, the homogenized deformation gradient of the micromodel is encoded into a set of deformation gradients serving as input to the embedded constitutive models. These constitutive models compute stresses, which are combined in a decoder to predict the homogenized stress, such that the internal variables of the history-dependent constitutive models naturally provide physics-based memory for the network. To demonstrate the capabilities of the surrogate model, we consider a unidirectional composite micromodel with transversely isotropic elastic fibers and elasto-viscoplastic matrix material. The extrapolation properties of the surrogate model trained to replace such micromodel are tested on loading scenarios unseen during training, ranging from different strain-rates to cyclic loading and relaxation. Speed-ups of three orders of magnitude with respect to the runtime of the original micromodel are obtained.

Original languageEnglish
Article number105145
Number of pages20
JournalMechanics of Materials
Volume198
DOIs
Publication statusPublished - 2024

Keywords

  • Constitutive model
  • Heterogeneous materials
  • Neural networks
  • Path-dependency
  • Rate-dependency

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