Litcius/Paper detail

A proof that rectified deep neural networks overcome the curse of dimensionality in the numerical approximation of semilinear heat equations

Martin Hutzenthaler, Arnulf Jentzen, Thomas Kruse, Tuan Anh Nguyen

2020Partial Differential Equations and Applications80 citationsDOIOpen Access PDF

Abstract

Abstract Deep neural networks and other deep learning methods have very successfully been applied to the numerical approximation of high-dimensional nonlinear parabolic partial differential equations (PDEs), which are widely used in finance, engineering, and natural sciences. In particular, simulations indicate that algorithms based on deep learning overcome the curse of dimensionality in the numerical approximation of solutions of semilinear PDEs. For certain linear PDEs it has also been proved mathematically that deep neural networks overcome the curse of dimensionality in the numerical approximation of solutions of such linear PDEs. The key contribution of this article is to rigorously prove this for the first time for a class of nonlinear PDEs. More precisely, we prove in the case of semilinear heat equations with gradient-independent nonlinearities that the numbers of parameters of the employed deep neural networks grow at most polynomially in both the PDE dimension and the reciprocal of the prescribed approximation accuracy. Our proof relies on recently introduced full history recursive multilevel Picard approximations for semilinear PDEs.

Topics & Concepts

Curse of dimensionalityArtificial neural networkNonlinear systemMathematicsApplied mathematicsDimension (graph theory)Partial differential equationHeat equationDeep learningReciprocalNumerical analysisLinear approximationMathematical analysisMathematical optimizationApproximation theoryClass (philosophy)Feature (linguistics)High dimensionalDifferential equationKey (lock)Numerical approximationDynamical systems theoryApproximation algorithmFunction approximationDimensionality reductionFeedforward neural networkModel Reduction and Neural NetworksNumerical methods in inverse problemsGenerative Adversarial Networks and Image Synthesis