Understanding the Expressivity and Trainability of Fourier Neural Operator: A Mean-Field Perspective

Takeshi Koshizuka; Masahiro Fujisawa; Yusuke Tanaka; Issei Sato

Understanding the Expressivity and Trainability of Fourier Neural Operator: A Mean-Field Perspective

Takeshi Koshizuka, Masahiro Fujisawa, Yusuke Tanaka, Issei Sato

Published: 25 Sept 2024, Last Modified: 06 Nov 2024NeurIPS 2024 posterEveryoneRevisionsBibTeXCC BY 4.0

Keywords: Fourier Neural Operator, PDE, Mean-Field Theory

Abstract: In this paper, we explores the expressivity and trainability of the Fourier Neural Operator (FNO). We establish a mean-field theory for the FNO, analyzing the behavior of the random FNO from an \emph{edge of chaos} perspective. Our investigation into the expressivity of a random FNO involves examining the ordered-chaos phase transition of the network based on the weight distribution. This phase transition demonstrates characteristics unique to the FNO, induced by mode truncation, while also showcasing similarities to those of densely connected networks. Furthermore, we identify a connection between expressivity and trainability: the ordered and chaotic phases correspond to regions of vanishing and exploding gradients, respectively. This finding provides a practical prerequisite for the stable training of the FNO. Our experimental results corroborate our theoretical findings.

Primary Area: Machine learning for physical sciences (for example: climate, physics)

Submission Number: 8310

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