Space-time deep neural network approximations for high-dimensional partial differential equations
Metadata only
Date
2020-06Type
- Report
ETH Bibliography
yes
Altmetrics
Abstract
It is one of the most challenging issues in applied mathematics to approximately solve high-dimensional partial differential equations (PDEs) and most of the numerical approximation methods for PDEs in the scientific literature suffer from the so-called curse of dimensionality in the sense that the number of computational operations employed in the corresponding approximation scheme to obtain an approximation precision ε>0 grows exponentially in the PDE dimension and/or the reciprocal of ε. Recently, certain deep learning based approximation methods for PDEs have been proposed and various numerical simulations for such methods suggest that deep neural network (DNN) approximations might have the capacity to indeed overcome the curse of dimensionality in the sense that the number of real parameters used to describe the approximating DNNs grows at most polynomially in both the PDE dimension d∈N and the reciprocal of the prescribed approximation accuracy ε>0. There are now also a few rigorous mathematical results in the scientific literature which substantiate this conjecture by proving that DNNs overcome the curse of dimensionality in approximating solutions of PDEs. Each of these results establishes that DNNs overcome the curse of dimensionality in approximating suitable PDE solutions at a fixed time point T>0 and on a compact cube [a,b]d in space but none of these results provides an answer to the question whether the entire PDE solution on [0,T]×[a,b]d can be approximated by DNNs without the curse of dimensionality. It is precisely the subject of this article to overcome this issue. More specifically, the main result of this work in particular proves for every a∈R, b∈(a,∞) that solutions of certain Kolmogorov PDEs can be approximated by DNNs on the space-time region [0,T]×[a,b]d without the curse of dimensionality. Show more
Publication status
publishedExternal links
Journal / series
SAM Research ReportVolume
Publisher
Seminar for Applied Mathematics, ETH ZurichSubject
deep neural network; DNN; artificial neural network; ANN; curse of dimensionality; approximation; partial differential equation; PDE; stochastic differential equation; SDE; Monte Carlo Euler; Feynman-Kac formulaOrganisational unit
02501 - Seminar für Angewandte Mathematik / Seminar for Applied Mathematics
Funding
175699 - Higher order numerical approximation methods for stochastic partial differential equations (SNF)
Related publications and datasets
Is previous version of: http://hdl.handle.net/20.500.11850/708379
More
Show all metadata
ETH Bibliography
yes
Altmetrics