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Finite element interpolated neural networks for solving forward and inverse problems

Santiago Badia, Wei Li, Alberto F. Martı́n

2023Computer Methods in Applied Mechanics and Engineering44 citationsDOIOpen Access PDF

Abstract

We propose a general framework for solving forward and inverse problems constrained by partial differential equations, where we interpolate neural networks onto finite element spaces to represent the (partial) unknowns. The framework overcomes the challenges related to the imposition of boundary conditions, the choice of collocation points in physics-informed neural networks, and the integration of variational physics-informed neural networks. A numerical experiment set confirms the framework’s capability of handling various forward and inverse problems. In particular, the trained neural network generalises well for smooth problems, beating finite element solutions by some orders of magnitude. We finally propose an effective one-loop solver with an initial data fitting step (to obtain a cheap initialisation) to solve inverse problems.

Topics & Concepts

Finite element methodArtificial neural networkCollocation (remote sensing)Inverse problemSolverPartial differential equationInverseApplied mathematicsBoundary (topology)Computer scienceSet (abstract data type)Mathematical optimizationBoundary value problemMathematicsAlgorithmMathematical analysisArtificial intelligenceGeometryPhysicsMachine learningThermodynamicsProgramming languageModel Reduction and Neural NetworksNumerical methods in engineeringAdvanced Numerical Methods in Computational Mathematics
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