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Chien-physics-informed neural networks for solving singularly perturbed boundary-layer problems

Long Wang, Lei Zhang, Guowei He

2024Applied Mathematics and Mechanics12 citationsDOIOpen Access PDF

Abstract

Abstract A physics-informed neural network (PINN) is a powerful tool for solving differential equations in solid and fluid mechanics. However, it suffers from singularly perturbed boundary-layer problems in which there exist sharp changes caused by a small perturbation parameter multiplying the highest-order derivatives. In this paper, we introduce Chien’s composite expansion method into PINNs, and propose a novel architecture for the PINNs, namely, the Chien-PINN (C-PINN) method. This novel PINN method is validated by singularly perturbed differential equations, and successfully solves the well-known thin plate bending problems. In particular, no cumbersome matching conditions are needed for the C-PINN method, compared with the previous studies based on matched asymptotic expansions.

Topics & Concepts

Method of matched asymptotic expansionsSingular perturbationBoundary layerBoundary value problemPerturbation (astronomy)Artificial neural networkMatching (statistics)Asymptotic expansionBoundary (topology)Differential equationApplied mathematicsMathematical analysisMathematicsComputer sciencePhysicsMechanicsArtificial intelligenceStatisticsQuantum mechanicsModel Reduction and Neural NetworksMagnetic Properties and ApplicationsFluid Dynamics and Vibration Analysis
Chien-physics-informed neural networks for solving singularly perturbed boundary-layer problems | Litcius