A deep material network for multiscale topology learning and accelerated nonlinear modeling of heterogeneous materials

TL;DR

This paper introduces a deep material network that combines mechanistic homogenization with machine learning to efficiently model heterogeneous materials across multiple scales, enabling accurate predictions without extensive calibration.

Contribution

It develops a novel data-driven multiscale modeling approach using connected mechanistic building blocks, avoiding loss of physics and allowing broad applicability.

Findings

Effective training on RVE data using stochastic gradient descent.

Valid for various material laws without additional calibration.

Accurate extrapolation to unknown material and loading conditions.

Abstract

In this paper, a new data-driven multiscale material modeling method, which we refer to as deep material network, is developed based on mechanistic homogenization theory of representative volume element (RVE) and advanced machine learning techniques. We propose to use a collection of connected mechanistic building blocks with analytical homogenization solutions which avoids the loss of essential physics in generic neural networks, and this concept is demonstrated for 2-dimensional RVE problems and network depth up to 7. Based on linear elastic RVE data from offline direct numerical simulations, the material network can be effectively trained using stochastic gradient descent with backpropagation algorithm, enhanced by model compression methods. Importantly, the trained network is valid for any local material laws without the need for additional calibration or micromechanics assumption. Its extrapolations to unknown material and loading spaces for a wide range of problems are validated through numerical experiments, including linear elasticity with high contrast of phase properties, nonlinear history-dependent plasticity and finite-strain hyperelasticity under large deformations. By discovering a proper topological representation of RVE with fewer degrees of freedom, this intelligent material model is believed to open new possibilities of high-fidelity efficient concurrent simulations for a large-scale heterogeneous structure. It also provides a mechanistic understanding of structure-property relations across material length scales and enables the development of parameterized microstructural database for material design and manufacturing.