A Depth Hierarchy for Computing the Maximum in ReLU Networks via Extremal Graph Theory

Abstract

We consider the problem of exact computation of the maximum function over d real inputs using ReLU neural networks. We prove a depth hierarchy, wherein width (d1+12k-2-1) is necessary to represent the maximum for any depth 3 k 2(2(d)). This is the first unconditional super-linear lower bound for this fundamental operator at depths k3, and it holds even if the depth scales with d. Our proof technique is based on a combinatorial argument and associates the non-differentiable ridges of the maximum with cliques in a graph induced by the first hidden layer of the computing network, utilizing Tur\'an's theorem from extremal graph theory to show that a sufficiently narrow network cannot capture the non-linearities of the maximum. This suggests that despite its simple nature, the maximum function possesses an inherent complexity that stems from the geometric structure of its non-differentiable hyperplanes, and provides a novel approach for proving lower bounds for deep neural networks.