Litcius/Paper detail

A Rate of Convergence of Physics Informed Neural Networks for the Linear Second Order Elliptic PDEs

Yuling Jiao, Yanming Lai, Dingwei Li, Xiaoguang Lu, Fengru Wang Fengru Wang, Yang Wang, Jerry Zhijian Yang Jerry Zhijian Yang

2022Communications in Computational Physics32 citationsDOIOpen Access PDF

Abstract

In recent years, physical informed neural networks (PINNs) have been shown to be a powerful tool for solving PDEs empirically. However, numerical analysis of PINNs is still missing. In this paper, we prove the convergence rate to PINNs for the second order elliptic equations with Dirichlet boundary condition, by establishing the upper bounds on the number of training samples, depth and width of the deep neural networks to achieve desired accuracy. The error of PINNs is decomposed into approximation error and statistical error, where the approximation error is given in C2 norm with ReLU3 networks (deep network with activation function max{0,x3}) and the statistical error is estimated by Rademacher complexity. We derive the bound on the Rademacher complexity of the non-Lipschitz composition of gradient norm with ReLU3 network, which is of immense independent interest. ©2022 Global-Science Press

Topics & Concepts

Lipschitz continuityArtificial neural networkRate of convergenceNorm (philosophy)Uniform normActivation functionApplied mathematicsConvergence (economics)Function (biology)Approximation errorOrder (exchange)Dirichlet distributionUpper and lower boundsComputer scienceBoundary (topology)AlgorithmMathematicsDiscrete mathematicsBoundary value problemPure mathematicsArtificial intelligenceMathematical analysisEconomicsComputer networkLawChannel (broadcasting)Evolutionary biologyEconomic growthBiologyFinancePolitical scienceModel Reduction and Neural NetworksAdvanced Numerical Methods in Computational MathematicsProbabilistic and Robust Engineering Design