Exploring Elastoplastic Constitutive Law of Microstructured Materials Through Artificial Neural Network—A Mechanistic-Based Data-Driven Approach
Hang Yang, Hai Qiu, Xiang Qian, Shan Tang, Xu Guo
Abstract
Abstract In this paper, a data-driven approach for constructing elastoplastic constitutive law of microstructured materials is proposed by combining the insights from plasticity theory and the tools of artificial intelligence (i.e., constructing yielding function through ANN) to reduce the required amount of data for machine learning. Illustrative examples show that the constitutive laws constructed by the present approach can be used to solve the boundary value problems (BVPs) involving elastoplastic materials with microstructures under complex loading paths (e.g., cyclic/reverse loading) effectively. The limitation of the proposed approach is also discussed.
Topics & Concepts
Constitutive equationArtificial neural networkBoundary value problemFunction (biology)PlasticityComputer scienceMaterials scienceArtificial intelligenceStructural engineeringMathematicsEngineeringMathematical analysisFinite element methodComposite materialBiologyEvolutionary biologyElasticity and Material ModelingModel Reduction and Neural NetworksComposite Material Mechanics