Nonlinear materials are often difficult to model with classical state model theory because they have a complex and sometimes inaccurate physical and mathematical description or we simply do not know how to describe such materials in terms of relations between external and internal variables. In many disciplines, Neural Network methods have arisen as powerful tools to identify very complex and non-linear correlations. In this work, we use the very recently developed concept of Physically Guided Neural Networks with Internal Variables (PGNNIV) to discover constitutive laws using a model-free approach and training solely with measured force-displacement data. PGNNIVs make a particular use of the physics of the problem to enforce constraints on...
Constitutive modeling of nonlinear materials is a computationally complex and time-intensive process...
The mathematical formulation of constitutive models to describe the path-dependent, i.e., inelastic,...
Machine learning for materials science envisions the acceleration of basic science research through ...
(Artificial) neural networks have become increasingly popular in mechanics and materials sciences to...
We applied physics-informed neural networks to solve the constitutive relations for nonlinear, path-...
Standard neural networks can approximate general nonlinear operators, represented either explicitly ...
Nonlinear materials are often difficult to model with classical methods like the FiniteElement Metho...
We propose a new approach for unsupervised learning of hyperelastic constitutive laws with physics-c...
Classically, the mechanical response of materials is described through constitutive models, often in...
Substitution of well-grounded theoretical models by data-driven predictions is not as simple in engi...
Classical physical modelling with associated numerical simulation (model-based), and prognostic meth...
Material identification is critical for understanding the relationship between mechanical properties...
Nature has always been our inspiration in the research, design and development of materials and has ...
Recent advances in machine learning have unlocked new potential for innovation in engineering scienc...
Anisotropy in the mechanical response of materials with microstructure is common and yet is difficul...
Constitutive modeling of nonlinear materials is a computationally complex and time-intensive process...
The mathematical formulation of constitutive models to describe the path-dependent, i.e., inelastic,...
Machine learning for materials science envisions the acceleration of basic science research through ...
(Artificial) neural networks have become increasingly popular in mechanics and materials sciences to...
We applied physics-informed neural networks to solve the constitutive relations for nonlinear, path-...
Standard neural networks can approximate general nonlinear operators, represented either explicitly ...
Nonlinear materials are often difficult to model with classical methods like the FiniteElement Metho...
We propose a new approach for unsupervised learning of hyperelastic constitutive laws with physics-c...
Classically, the mechanical response of materials is described through constitutive models, often in...
Substitution of well-grounded theoretical models by data-driven predictions is not as simple in engi...
Classical physical modelling with associated numerical simulation (model-based), and prognostic meth...
Material identification is critical for understanding the relationship between mechanical properties...
Nature has always been our inspiration in the research, design and development of materials and has ...
Recent advances in machine learning have unlocked new potential for innovation in engineering scienc...
Anisotropy in the mechanical response of materials with microstructure is common and yet is difficul...
Constitutive modeling of nonlinear materials is a computationally complex and time-intensive process...
The mathematical formulation of constitutive models to describe the path-dependent, i.e., inelastic,...
Machine learning for materials science envisions the acceleration of basic science research through ...