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Multi-level physics informed deep learning for solving partial differential equations in computational structural mechanics

Weiwei He, Jinzhao Li, Xuan Kong, Lu Deng

2024Communications Engineering58 citationsDOIOpen Access PDF

Abstract

Physics-informed neural network has emerged as a promising approach for solving partial differential equations. However, it is still a challenge for the computation of structural mechanics problems since it involves solving higher-order partial differential equations as the governing equations are fourth-order nonlinear equations. Here we develop a multi-level physics-informed neural network framework where an aggregation model is developed by combining multiple neural networks, with each one involving only first-order or second-order partial differential equations representing different physics information such as geometrical, constitutive, and equilibrium relations of the structure. The proposed framework demonstrates a remarkable advancement over the classical neural networks in terms of the accuracy and computation time. The proposed method holds the potential to become a promising paradigm for structural mechanics computation and facilitate the intelligent computation of digital twin systems. Weiwei He and colleagues implement a multi-level physicsinformed neural network to solve partial differential equations, a key problem for efficient structure analysis. Their results improve the accuracy and computation time for solving these problems.

Topics & Concepts

Partial differential equationComputational mechanicsApplied mathematicsComputer sciencePhysicsMathematicsMathematics educationCalculus (dental)Classical mechanicsMathematical analysisFinite element methodThermodynamicsDentistryMedicineModel Reduction and Neural NetworksStructural Health Monitoring TechniquesDam Engineering and Safety
Multi-level physics informed deep learning for solving partial differential equations in computational structural mechanics | Litcius