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Universal Function Approximation by Deep Neural Nets with Bounded Width and ReLU Activations

Machine Learning 2019-10-22 v3 Computational Geometry Machine Learning Functional Analysis Statistics Theory Statistics Theory

Abstract

This article concerns the expressive power of depth in neural nets with ReLU activations and bounded width. We are particularly interested in the following questions: what is the minimal width wmin(d)w_{\text{min}}(d) so that ReLU nets of width wmin(d)w_{\text{min}}(d) (and arbitrary depth) can approximate any continuous function on the unit cube [0,1]d[0,1]^d aribitrarily well? For ReLU nets near this minimal width, what can one say about the depth necessary to approximate a given function? Our approach to this paper is based on the observation that, due to the convexity of the ReLU activation, ReLU nets are particularly well-suited for representing convex functions. In particular, we prove that ReLU nets with width d+1d+1 can approximate any continuous convex function of dd variables arbitrarily well. These results then give quantitative depth estimates for the rate of approximation of any continuous scalar function on the dd-dimensional cube [0,1]d[0,1]^d by ReLU nets with width d+3.d+3.

Keywords

Cite

@article{arxiv.1708.02691,
  title  = {Universal Function Approximation by Deep Neural Nets with Bounded Width and ReLU Activations},
  author = {Boris Hanin},
  journal= {arXiv preprint arXiv:1708.02691},
  year   = {2019}
}

Comments

v3. Theorem 3 removed. Comments Welcome. 9p

R2 v1 2026-06-22T21:10:05.457Z