The analytical description of path-dependent elastic-plastic responses of a granular system is highly complicated because of continuously evolving microstructures and strain localisation within the system undergoing deformation. This study offers an alternative to the current analytical paradigm by developing micromechanics-informed machine-learning based constitutive modelling approaches for granular materials. A set of critical variables associated with the constitutive behaviour of granular materials are identified through an incremental stress-strain relationship analysis. Depending on the strategy to exploit the priori micromechanical knowledge, three different training strategies are explored. The first model uses only the measurable ...
This work presents a constitutive modeling approach for the behavior of granular materials. In the g...
Constitutive models for plastic deformation of metals are typically based on flow rules determining ...
This work focuses on integrating crystal plasticity based deformation models and machine learning te...
This study presents an AI-based constitutive modelling framework wherein the prediction model direct...
Recent advances in machine learning have unlocked new potential for innovation in engineering scienc...
Machine learning offers a new approach to predicting the path-dependent stress–strain response of gr...
Granular materials are ubiquitous in engineering activities of our human beings. Constitutive modell...
Plasticity theory aims at describing the yield loci and work hardening of a material under general d...
Direct numerical simulation of hierarchical materials via homogenization-based concurrent multiscale...
Granular materials are complex systems whose macroscopic mechanics are governed by particles at the ...
Driven by the need to accelerate numerical simulations, the use of machine learning techniques is ra...
In this paper the application of machine learning techniques for the development of constitutive mat...
Constitutive modeling of nonlinear materials is a computationally complex and time-intensive process...
Classically, the mechanical response of materials is described through constitutive models, often in...
Here you can find the results and code corresponding to the article "Modeling the relationship betwe...
This work presents a constitutive modeling approach for the behavior of granular materials. In the g...
Constitutive models for plastic deformation of metals are typically based on flow rules determining ...
This work focuses on integrating crystal plasticity based deformation models and machine learning te...
This study presents an AI-based constitutive modelling framework wherein the prediction model direct...
Recent advances in machine learning have unlocked new potential for innovation in engineering scienc...
Machine learning offers a new approach to predicting the path-dependent stress–strain response of gr...
Granular materials are ubiquitous in engineering activities of our human beings. Constitutive modell...
Plasticity theory aims at describing the yield loci and work hardening of a material under general d...
Direct numerical simulation of hierarchical materials via homogenization-based concurrent multiscale...
Granular materials are complex systems whose macroscopic mechanics are governed by particles at the ...
Driven by the need to accelerate numerical simulations, the use of machine learning techniques is ra...
In this paper the application of machine learning techniques for the development of constitutive mat...
Constitutive modeling of nonlinear materials is a computationally complex and time-intensive process...
Classically, the mechanical response of materials is described through constitutive models, often in...
Here you can find the results and code corresponding to the article "Modeling the relationship betwe...
This work presents a constitutive modeling approach for the behavior of granular materials. In the g...
Constitutive models for plastic deformation of metals are typically based on flow rules determining ...
This work focuses on integrating crystal plasticity based deformation models and machine learning te...