Accelerating multiscale finite element simulations of history-dependent materials using a recurrent neural network

F. Ghavamian; A. Simone

doi:10.1016/j.cma.2019.112594

Accelerating multiscale finite element simulations of history-dependent materials using a recurrent neural network

F. Ghavamian^*, A. Simone

^*Corresponding author for this work

Applied Mechanics

Research output: Contribution to journal › Article › Scientific › peer-review

131 Citations (Scopus)

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Abstract

FE² multiscale simulations of history-dependent materials are accelerated by means of a recurrent neural network (RNN) surrogate for the history-dependent micro level response. We propose a simple strategy to efficiently collect stress–strain data from the micro model, and we modify the RNN model such that it resembles a nonlinear finite element analysis procedure during training. We then implement the trained RNN model in the FE² scheme and employ automatic differentiation to compute the consistent tangent. The exceptional performance of the proposed model is demonstrated through a number of academic examples using strain-softening Perzyna viscoplasticity as the nonlinear material model at the micro level.

Original language	English
Article number	112594
Number of pages	23
Journal	Computer Methods in Applied Mechanics and Engineering
Volume	357
DOIs	https://doi.org/10.1016/j.cma.2019.112594
Publication status	Published - 2019

Bibliographical note

Accepted author manuscript

Keywords

Deep learning
Machine learning
Multiscale modeling
Recurrent neural network
Strain softening
Viscoplasticity

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10.1016/j.cma.2019.112594

paperAccepted author manuscript, 1.85 MBLicence: CC BY-NC-ND

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title = "Accelerating multiscale finite element simulations of history-dependent materials using a recurrent neural network",

abstract = "FE2 multiscale simulations of history-dependent materials are accelerated by means of a recurrent neural network (RNN) surrogate for the history-dependent micro level response. We propose a simple strategy to efficiently collect stress–strain data from the micro model, and we modify the RNN model such that it resembles a nonlinear finite element analysis procedure during training. We then implement the trained RNN model in the FE2 scheme and employ automatic differentiation to compute the consistent tangent. The exceptional performance of the proposed model is demonstrated through a number of academic examples using strain-softening Perzyna viscoplasticity as the nonlinear material model at the micro level.",

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N2 - FE2 multiscale simulations of history-dependent materials are accelerated by means of a recurrent neural network (RNN) surrogate for the history-dependent micro level response. We propose a simple strategy to efficiently collect stress–strain data from the micro model, and we modify the RNN model such that it resembles a nonlinear finite element analysis procedure during training. We then implement the trained RNN model in the FE2 scheme and employ automatic differentiation to compute the consistent tangent. The exceptional performance of the proposed model is demonstrated through a number of academic examples using strain-softening Perzyna viscoplasticity as the nonlinear material model at the micro level.

AB - FE2 multiscale simulations of history-dependent materials are accelerated by means of a recurrent neural network (RNN) surrogate for the history-dependent micro level response. We propose a simple strategy to efficiently collect stress–strain data from the micro model, and we modify the RNN model such that it resembles a nonlinear finite element analysis procedure during training. We then implement the trained RNN model in the FE2 scheme and employ automatic differentiation to compute the consistent tangent. The exceptional performance of the proposed model is demonstrated through a number of academic examples using strain-softening Perzyna viscoplasticity as the nonlinear material model at the micro level.

KW - Deep learning

KW - Machine learning

KW - Multiscale modeling

KW - Recurrent neural network

KW - Strain softening

KW - Viscoplasticity

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M3 - Article

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JO - Computer Methods in Applied Mechanics and Engineering

JF - Computer Methods in Applied Mechanics and Engineering

M1 - 112594

ER -

Accelerating multiscale finite element simulations of history-dependent materials using a recurrent neural network

Abstract

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Keywords

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