Achieve the Minimum Width of Neural Networks for Universal Approximation

Abstract

The universal approximation property (UAP) of neural networks is fundamental for deep learning, and it is well known that wide neural networks are universal approximators of continuous functions within both the Lp norm and the continuous/uniform norm. However, the exact minimum width, w, for the UAP has not been studied thoroughly. Recently, using a decoder-memorizer-encoder scheme, Park2021Minimum found that w = (dx+1,dy) for both the Lp-UAP of ReLU networks and the C-UAP of ReLU+STEP networks, where dx,dy are the input and output dimensions, respectively. In this paper, we consider neural networks with an arbitrary set of activation functions. We prove that both C-UAP and Lp-UAP for functions on compact domains share a universal lower bound of the minimal width; that is, w* = (dx,dy). In particular, the critical width, w*, for Lp-UAP can be achieved by leaky-ReLU networks, provided that the input or output dimension is larger than one. Our construction is based on the approximation power of neural ordinary differential equations and the ability to approximate flow maps by neural networks. The nonmonotone or discontinuous activation functions case and the one-dimensional case are also discussed.