Driven by the need to accelerate numerical simulations, the use of machine learning techniques is rapidly growing in the field of computational solid mechanics. Their application is especially advantageous in concurrent multiscale finite element analysis (FE2) due to the exceedingly high computational costs often associated with it and the high number of similar micromechanical analyses involved. To tackle the issue, using surrogate models to approximate the microscopic behavior and accelerate the simulations is a promising and increasingly popular strategy. However, several challenges related to their data-driven nature compromise the reliability of surrogate models in material modeling. The alternative explored in this work is to reintrod...
Computational models describing the mechanical behavior of materials are indispensable when optimizi...
Constitutive modeling of nonlinear materials is a computationally complex and time-intensive process...
Data related to the publication (we would be grateful if you could cite the paper in the case in whi...
In a concurrent (FE2) multiscale modeling is an increasingly popular approach for modeling complex m...
An artificial Neural Network (NNW) is designed to serve as a surrogate model of micro-scale simulati...
FE2 multiscale simulations of history-dependent materials are accelerated by means of a recurrent ne...
Modern material systems with properly designed microstructures offer new avenues for engineering mat...
We applied physics-informed neural networks to solve the constitutive relations for nonlinear, path-...
Recurrent Neural Network (RNN) based surrogate models constitute an emerging class of reduced order ...
We propose and implement a computational procedure to establish data-driven surrogate constitutive m...
peer reviewedArtificial Neural Networks (NNWs) are appealing functions to substitute high dimensiona...
Direct numerical simulation of hierarchical materials via homogenization-based concurrent multiscale...
In mechanics and engineering, the Finite Element Method (FEM) represents the predominant numerical s...
The present work aims at proposing a hybrid physics-AI based model to predict non-linear mechanical ...
Data for: On the Importance of Self-consistency in Recurrent Neural Network Models Representing Elas...
Computational models describing the mechanical behavior of materials are indispensable when optimizi...
Constitutive modeling of nonlinear materials is a computationally complex and time-intensive process...
Data related to the publication (we would be grateful if you could cite the paper in the case in whi...
In a concurrent (FE2) multiscale modeling is an increasingly popular approach for modeling complex m...
An artificial Neural Network (NNW) is designed to serve as a surrogate model of micro-scale simulati...
FE2 multiscale simulations of history-dependent materials are accelerated by means of a recurrent ne...
Modern material systems with properly designed microstructures offer new avenues for engineering mat...
We applied physics-informed neural networks to solve the constitutive relations for nonlinear, path-...
Recurrent Neural Network (RNN) based surrogate models constitute an emerging class of reduced order ...
We propose and implement a computational procedure to establish data-driven surrogate constitutive m...
peer reviewedArtificial Neural Networks (NNWs) are appealing functions to substitute high dimensiona...
Direct numerical simulation of hierarchical materials via homogenization-based concurrent multiscale...
In mechanics and engineering, the Finite Element Method (FEM) represents the predominant numerical s...
The present work aims at proposing a hybrid physics-AI based model to predict non-linear mechanical ...
Data for: On the Importance of Self-consistency in Recurrent Neural Network Models Representing Elas...
Computational models describing the mechanical behavior of materials are indispensable when optimizi...
Constitutive modeling of nonlinear materials is a computationally complex and time-intensive process...
Data related to the publication (we would be grateful if you could cite the paper in the case in whi...