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A micromechanics‐based recurrent neural networks model for path‐dependent cyclic deformation of short fiber composites

J. Friemann, Behdad Dashtbozorg, Martin Fagerström, Mohsen Mirkhalaf

2023International Journal for Numerical Methods in Engineering40 citationsDOIOpen Access PDF

Abstract

Abstract The macroscopic response of short fiber reinforced composites (SFRCs) is dependent on an extensive range of microstructural parameters. Thus, micromechanical modeling of these materials is challenging and in some cases, computationally expensive. This is particularly important when path‐dependent plastic behavior is needed to be predicted. A solution to this challenge is to enhance micromechanical solutions with machine learning techniques such as artificial neural networks. In this work, a recurrent deep neural network model is trained to predict the path‐dependent elasto‐plastic stress response of SFRCs, given the microstructural parameters and the strain path. Micromechanical mean‐field simulations are conducted to create a database for training the validating the model. The model gives very accurate predictions in a computationally efficient manner when compared with independent micromechanical simulations.

Topics & Concepts

MicromechanicsMaterials scienceArtificial neural networkFiberPath (computing)Deformation (meteorology)Composite materialFiber-reinforced compositeWork (physics)Stress pathComputer scienceBiological systemArtificial intelligenceMechanical engineeringPlasticityEngineeringComposite numberProgramming languageBiologyComposite Material MechanicsMechanical Behavior of CompositesNumerical methods in engineering
A micromechanics‐based recurrent neural networks model for path‐dependent cyclic deformation of short fiber composites | Litcius