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Stiff-PDEs and Physics-Informed Neural Networks

Prakhar Sharma, Llion Marc Evans, Michelle Tindall, Perumal Nithiarasu

2023Archives of Computational Methods in Engineering38 citationsDOIOpen Access PDF

Abstract

Abstract In recent years, physics-informed neural networks (PINN) have been used to solve stiff-PDEs mostly in the 1D and 2D spatial domain. PINNs still experience issues solving 3D problems, especially, problems with conflicting boundary conditions at adjacent edges and corners. These problems have discontinuous solutions at edges and corners that are difficult to learn for neural networks with a continuous activation function. In this review paper, we have investigated various PINN frameworks that are designed to solve stiff-PDEs. We took two heat conduction problems (2D and 3D) with a discontinuous solution at corners as test cases. We investigated these problems with a number of PINN frameworks, discussed and analysed the results against the FEM solution. It appears that PINNs provide a more general platform for parameterisation compared to conventional solvers. Thus, we have investigated the 2D heat conduction problem with parametric conductivity and geometry separately. We also discuss the challenges associated with PINNs and identify areas for further investigation.

Topics & Concepts

Thermal conductionArtificial neural networkParametric statisticsBoundary (topology)Boundary value problemFinite element methodDomain (mathematical analysis)Function (biology)Heat equationComputer scienceApplied mathematicsMathematical optimizationMathematicsMathematical analysisArtificial intelligencePhysicsStatisticsEvolutionary biologyBiologyThermodynamicsModel Reduction and Neural NetworksHeat Transfer and OptimizationThermal properties of materials
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