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Variational Physics Informed Neural Networks: the Role of Quadratures and Test Functions

Stefano Berrone, Claudio Canuto, Moreno Pintore

2022Journal of Scientific Computing64 citationsDOIOpen Access PDF

Abstract

Abstract In this work we analyze how quadrature rules of different precisions and piecewise polynomial test functions of different degrees affect the convergence rate of Variational Physics Informed Neural Networks (VPINN) with respect to mesh refinement, while solving elliptic boundary-value problems. Using a Petrov-Galerkin framework relying on an inf-sup condition, we derive an a priori error estimate in the energy norm between the exact solution and a suitable high-order piecewise interpolant of a computed neural network. Numerical experiments confirm the theoretical predictions and highlight the importance of the inf-sup condition. Our results suggest, somehow counterintuitively, that for smooth solutions the best strategy to achieve a high decay rate of the error consists in choosing test functions of the lowest polynomial degree, while using quadrature formulas of suitably high precision.

Topics & Concepts

MathematicsTest (biology)Artificial neural networkApplied mathematicsCalculus (dental)Mathematical analysisStatistical physicsArtificial intelligencePhysicsComputer scienceGeologyMedicineDentistryPaleontologyModel Reduction and Neural NetworksNeural Networks and ApplicationsComputational Physics and Python Applications