Materials-by-design is a paradigm to develop previously unknown high-performance materials. However, finding materials with superior properties is often computationally or experimentally intractable because of the astronomical number of combinations in design space. Here we report an AI-based approach, implemented in a game theory–based conditional generative adversarial neural network (cGAN), to bridge the gap between a material’s microstructure—the design space—and physical performance. Our end-to-end deep learning model predicts physical fields like stress or strain directly from the material microstructure geometry, and reaches an astonishing accuracy not only for predicted field data but also for derivative material property prediction...
Abstract Neural network-based generative models have been actively investigated as an inverse design...
Emerging multi-material 3D printing techniques enables the rational design of metamaterials with not...
Increased demands for high-performance materials have led to advanced composite materials with compl...
Abstract Developing accurate yet fast computational tools to simulate complex physical phenomena is ...
Recent advances in machine learning have unlocked new potential for innovation in engineering scienc...
Computational solid mechanics has been widely conducted using Finite Element Analysis (FEA). Howeve...
This study presents an AI-based constitutive modelling framework wherein the prediction model direct...
Generative adversarial networks (GANs) are deep generative models (GMs) that have recently attracted...
A novel method to predict the mechanical responses of arbitrary microstructures from the deep learni...
In this paper we show some different concepts for the use of Artificial Neural Networks [1-4] in mod...
Modern material systems with properly designed microstructures offer new avenues for engineering mat...
The distribution of material phases is crucial to determine the composite's mechanical property. Whi...
Abstract We propose a deep neural network (DNN) as a fast surrogate model for local stress calculati...
International audiencePredicting the performance of mechanical properties is an important and curren...
Abstract High‐throughput screening has become one of the major strategies for the discovery of novel...
Abstract Neural network-based generative models have been actively investigated as an inverse design...
Emerging multi-material 3D printing techniques enables the rational design of metamaterials with not...
Increased demands for high-performance materials have led to advanced composite materials with compl...
Abstract Developing accurate yet fast computational tools to simulate complex physical phenomena is ...
Recent advances in machine learning have unlocked new potential for innovation in engineering scienc...
Computational solid mechanics has been widely conducted using Finite Element Analysis (FEA). Howeve...
This study presents an AI-based constitutive modelling framework wherein the prediction model direct...
Generative adversarial networks (GANs) are deep generative models (GMs) that have recently attracted...
A novel method to predict the mechanical responses of arbitrary microstructures from the deep learni...
In this paper we show some different concepts for the use of Artificial Neural Networks [1-4] in mod...
Modern material systems with properly designed microstructures offer new avenues for engineering mat...
The distribution of material phases is crucial to determine the composite's mechanical property. Whi...
Abstract We propose a deep neural network (DNN) as a fast surrogate model for local stress calculati...
International audiencePredicting the performance of mechanical properties is an important and curren...
Abstract High‐throughput screening has become one of the major strategies for the discovery of novel...
Abstract Neural network-based generative models have been actively investigated as an inverse design...
Emerging multi-material 3D printing techniques enables the rational design of metamaterials with not...
Increased demands for high-performance materials have led to advanced composite materials with compl...