Sharp Sobolev Sandwich and Approximation Rates of Radon-Domain Lp Ridge Integral Spaces for ReLUk Networks

Abstract

We develop the Lp space and approximation theory for shallow neural networks with ReLUk activations. The central object is the Radon-domain Lp space RLpk(Ω) containing all functions on a bounded domain Ω that admit a ridge integral representation whose coefficient density belongs to Lp in the Radon domain. In the Hilbert case p=2, we prove by elementary Fourier analysis that this space recovers the critical Sobolev space Hk+(d+1)/2(Ω). For general 1<p<∞, the identity becomes a Sobolev sandwich. The sharp gap of each side is exactly the Seeger--Sogge--Stein loss for the Radon transform as a Fourier integral operator. This also clarifies how the activation regularity and Radon back-projection jointly produce the regularity. As an application, we discretize the integral representation using a deterministic interpolation skeleton plus uniform sampling. This yields high-probability Lp approximation rates and the optimal Hilbert rate O\!(n-12-2k+12d) at p=2 for linearized neural networks.