On the optimal approximation of Sobolev and Besov functions using deep ReLU neural networks

Abstract

This paper studies the problem of how efficiently functions in the Sobolev spaces Ws,q([0,1]d) and Besov spaces Bsq,r([0,1]d) can be approximated by deep ReLU neural networks with width W and depth L, when the error is measured in the Lp([0,1]d) norm. This problem has been studied by several recent works, which obtained the approximation rate O((WL)-2s/d) up to logarithmic factors when p=q=∞, and the rate O(L-2s/d) for networks with fixed width when the Sobolev embedding condition 1/q -1/p<s/d holds. We generalize these results by showing that the rate O((WL)-2s/d) indeed holds under the Sobolev embedding condition. It is known that this rate is optimal up to logarithmic factors. The key tool in our proof is a novel encoding of sparse vectors by using deep ReLU neural networks with varied width and depth, which may be of independent interest.