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On quadrature rules for solving Partial Differential Equations using Neural Networks

Jon Ander Rivera, Jamie M. Taylor, Ángel J. Omella, David Pardo

2022Computer Methods in Applied Mechanics and Engineering39 citationsDOIOpen Access PDF

Abstract

Neural Networks have been widely used to solve Partial Differential Equations. These methods require to approximate definite integrals using quadrature rules. Here, we illustrate via 1D numerical examples the quadrature problems that may arise in these applications and propose several alternatives to overcome them, namely: Monte Carlo methods, adaptive integration, polynomial approximations of the Neural Network output, and the inclusion of regularization terms in the loss. We also discuss the advantages and limitations of each proposed numerical integration scheme. We advocate the use of Monte Carlo methods for high dimensions (above 3 or 4), and adaptive integration or polynomial approximations for low dimensions (3 or below). The use of regularization terms is a mathematically elegant alternative that is valid for any spatial dimension; however, it requires certain regularity assumptions on the solution and complex mathematical analysis when dealing with sophisticated Neural Networks.

Topics & Concepts

Numerical integrationArtificial neural networkApplied mathematicsQuadrature (astronomy)Regularization (linguistics)Monte Carlo methodPartial differential equationAdaptive quadratureMathematicsQuasi-Monte Carlo methodMathematical optimizationPartial derivativeComputer sciencePolynomialDimension (graph theory)Hybrid Monte CarloMathematical analysisArtificial intelligenceControl theory (sociology)StatisticsElectrical engineeringControl (management)Pure mathematicsEngineeringMarkov chain Monte CarloModel Reduction and Neural NetworksProbabilistic and Robust Engineering DesignNumerical Methods and Algorithms