Computation complexity of deep ReLU neural networks in high-dimensional approximation

Abstract

The purpose of the present paper is to study the computation complexity of deep ReLU neural networks to approximate functions in H\"older-Nikol'skii spaces of mixed smoothness H∞α(Id) on the unit cube Id:=[0,1]d. In this context, for any function f∈ H∞α(Id), we explicitly construct nonadaptive and adaptive deep ReLU neural networks having an output that approximates f with a prescribed accuracy , and prove dimension-dependent bounds for the computation complexity of this approximation, characterized by the size and the depth of this deep ReLU neural network, explicitly in d and . Our results show the advantage of the adaptive method of approximation by deep ReLU neural networks over nonadaptive one.