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Embeddings between Barron spaces with higher order activation functions

Machine Learning 2024-06-19 v2 Machine Learning Functional Analysis

Abstract

The approximation properties of infinitely wide shallow neural networks heavily depend on the choice of the activation function. To understand this influence, we study embeddings between Barron spaces with different activation functions. These embeddings are proven by providing push-forward maps on the measures μ\mu used to represent functions ff. An activation function of particular interest is the rectified power unit (RePU\operatorname{RePU}) given by RePUs(x)=max(0,x)s\operatorname{RePU}_s(x)=\max(0,x)^s. For many commonly used activation functions, the well-known Taylor remainder theorem can be used to construct a push-forward map, which allows us to prove the embedding of the associated Barron space into a Barron space with a RePU\operatorname{RePU} as activation function. Moreover, the Barron spaces associated with the RePUs\operatorname{RePU}_s have a hierarchical structure similar to the Sobolev spaces HmH^m.

Keywords

Cite

@article{arxiv.2305.15839,
  title  = {Embeddings between Barron spaces with higher order activation functions},
  author = {Tjeerd Jan Heeringa and Len Spek and Felix Schwenninger and Christoph Brune},
  journal= {arXiv preprint arXiv:2305.15839},
  year   = {2024}
}

Comments

21 pages, 1 figure; revision adds extension to fractional RePU and fractional Taylor expansion

R2 v1 2026-06-28T10:45:41.616Z