Direct numerical simulation of hierarchical materials via homogenization-based concurrent multiscale models poses critical challenges for 3D large scale engineering applications, as the computation of highly nonlinear and path-dependent material constitutive responses at the lower scale causes prohibitively high computational costs. In this work, we propose a physics-informed data-driven deep learning model as an efficient surrogate to emulate the effective responses of heterogeneous microstructures under irreversible elasto-plastic hardening and softening deformation. Our contribution contains several major innovations. First, we propose a novel training scheme to generate arbitrary loading sequences in the sampling space confined by defor...
Abstract We propose a deep neural network (DNN) as a fast surrogate model for local stress calculati...
The deep energy method (DEM) has been used to solve the elastic deformation of structures with linea...
In mechanics and engineering, the Finite Element Method (FEM) represents the predominant numerical s...
Recent advances in machine learning have unlocked new potential for innovation in engineering scienc...
Driven by the need to accelerate numerical simulations, the use of machine learning techniques is ra...
Deep material networks (DMN) are a promising piece of technology for accelerating concurrent multisc...
In a concurrent (FE2) multiscale modeling is an increasingly popular approach for modeling complex m...
Deep material networks (DMNs) are a recent multiscale technology which enable running concurrent mul...
An artificial Neural Network (NNW) is designed to serve as a surrogate model of micro-scale simulati...
Modern material systems with properly designed microstructures offer new avenues for engineering mat...
The analytical description of path-dependent elastic-plastic responses of a granular system is highl...
FE2 multiscale simulations of history-dependent materials are accelerated by means of a recurrent ne...
We propose and implement a computational procedure to establish data-driven surrogate constitutive m...
We propose a surrogate model for two-scale computational homogenization of elastostatics at finite s...
In this communication, a multi-task deep learning-driven homogenization scheme is proposed for predi...
Abstract We propose a deep neural network (DNN) as a fast surrogate model for local stress calculati...
The deep energy method (DEM) has been used to solve the elastic deformation of structures with linea...
In mechanics and engineering, the Finite Element Method (FEM) represents the predominant numerical s...
Recent advances in machine learning have unlocked new potential for innovation in engineering scienc...
Driven by the need to accelerate numerical simulations, the use of machine learning techniques is ra...
Deep material networks (DMN) are a promising piece of technology for accelerating concurrent multisc...
In a concurrent (FE2) multiscale modeling is an increasingly popular approach for modeling complex m...
Deep material networks (DMNs) are a recent multiscale technology which enable running concurrent mul...
An artificial Neural Network (NNW) is designed to serve as a surrogate model of micro-scale simulati...
Modern material systems with properly designed microstructures offer new avenues for engineering mat...
The analytical description of path-dependent elastic-plastic responses of a granular system is highl...
FE2 multiscale simulations of history-dependent materials are accelerated by means of a recurrent ne...
We propose and implement a computational procedure to establish data-driven surrogate constitutive m...
We propose a surrogate model for two-scale computational homogenization of elastostatics at finite s...
In this communication, a multi-task deep learning-driven homogenization scheme is proposed for predi...
Abstract We propose a deep neural network (DNN) as a fast surrogate model for local stress calculati...
The deep energy method (DEM) has been used to solve the elastic deformation of structures with linea...
In mechanics and engineering, the Finite Element Method (FEM) represents the predominant numerical s...