Despite their recent success, machine learning (ML) models such as graph neural networks (GNNs), suffer from drawbacks such as the need for large training datasets and poor performance for unseen cases. In this work, we use transfer learning (TL) approaches to circumvent the need for retraining with large datasets. We apply TL to an existing ML framework, trained to predict multiple crack propagation and stress evolution in brittle materials under Mode-I loading. The new framework, ACCelerated Universal fRAcTure Emulator (ACCURATE), is generalized to a variety of crack problems by using a sequence of TL update steps including (i) arbitrary crack lengths, (ii) arbitrary crack orientations, (iii) square domains, (iv) horizontal domains, and (...
Understanding fracture is critical to the design of resilient nanomaterials. Molecular dynamics offe...
We present deep learning phase-field models for brittle fracture. A variety of Physics-Informed Neur...
Recent advances in machine learning have unlocked new potential for innovation in engineering scienc...
High-fidelity fracture mechanics simulations of multiple microcracks interaction via physics-based m...
Access to the material response in mechanical experiments can be provided by modern optical methods ...
We present deep learning phase-field models for brittle fracture. A variety of physics-informed neur...
Architected materials typically rely on regular periodic patterns to achieve improved mechanical pro...
The relationships between the fatigue crack growth rate ( d a / d N ) and stress intens...
Machine learning (ML) models enable exploration of vast structural space faster than the traditional...
Computer vision techniques can be applied to detect structural defects of different concrete structu...
International audienceThe propagation of small cracks contributes to the majority of the fatigue lif...
Fracture is a catastrophic and complex process that involves various time and length scales. Scienti...
thesisPredicting the growth behavior of microstructurally small fatigue cracks is a practically rele...
International audienceSmall crack propagation accounts for most of the fatigue life of engineering s...
The paper “Predicting Mechanically Driven Full-Field Quantities of Interest with Deep Learning-Based...
Understanding fracture is critical to the design of resilient nanomaterials. Molecular dynamics offe...
We present deep learning phase-field models for brittle fracture. A variety of Physics-Informed Neur...
Recent advances in machine learning have unlocked new potential for innovation in engineering scienc...
High-fidelity fracture mechanics simulations of multiple microcracks interaction via physics-based m...
Access to the material response in mechanical experiments can be provided by modern optical methods ...
We present deep learning phase-field models for brittle fracture. A variety of physics-informed neur...
Architected materials typically rely on regular periodic patterns to achieve improved mechanical pro...
The relationships between the fatigue crack growth rate ( d a / d N ) and stress intens...
Machine learning (ML) models enable exploration of vast structural space faster than the traditional...
Computer vision techniques can be applied to detect structural defects of different concrete structu...
International audienceThe propagation of small cracks contributes to the majority of the fatigue lif...
Fracture is a catastrophic and complex process that involves various time and length scales. Scienti...
thesisPredicting the growth behavior of microstructurally small fatigue cracks is a practically rele...
International audienceSmall crack propagation accounts for most of the fatigue life of engineering s...
The paper “Predicting Mechanically Driven Full-Field Quantities of Interest with Deep Learning-Based...
Understanding fracture is critical to the design of resilient nanomaterials. Molecular dynamics offe...
We present deep learning phase-field models for brittle fracture. A variety of Physics-Informed Neur...
Recent advances in machine learning have unlocked new potential for innovation in engineering scienc...