On Universal Approximation and Error Bounds for Fourier Neural Operators

Nikola Kovachki; Samuel Lanthaler; Siddhartha Mishra

2021 JMLR JMLR 2021

On Universal Approximation and Error Bounds for Fourier Neural Operators

Abstract

Fourier neural operators (FNOs) have recently been proposed as an effective framework for learning operators that map between infinite-dimensional spaces. We prove that FNOs are universal, in the sense that they can approximate any continuous operator to desired accuracy. Moreover, we suggest a mechanism by which FNOs can approximate operators associated with PDEs efficiently. Explicit error bounds are derived to show that the size of the FNO, approximating operators associated with a Darcy type elliptic PDE and with the incompressible Navier-Stokes equations of fluid dynamics, only increases sub (log)-linearly in terms of the reciprocal of the error. Thus, FNOs are shown to efficiently approximate operators arising in a large class of PDEs. [abs] [ pdf ][ bib ] © JMLR 2021. (edit, beta)

🌉 Interdisciplinary Bridge — Machine Learning and Mathematics & Optimization

🧭 Keyword Pioneer — operator learning

🐝 Cross-Pollinator — Artificial Intelligence, Deep Learning, Machine Learning, Mathematics & Optimization, Reinforcement Learning

Authors

Nikola Kovachki , Samuel Lanthaler , Siddhartha Mishra

Topics

Machine Learning > Core Methods > Regression Machine Learning > Core Methods > Representation Learning Mathematics & Optimization > Optimization > Continuous Optimization Mathematics & Optimization > Mathematics > Functional Analysis Deep Learning > Models > Neural Networks

Keywords

universal approximation partial differential equation operator learning error bound fourier neural operator

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