Toward L∞-recovery of Nonlinear Functions: A Polynomial Sample Complexity Bound for Gaussian Random Fields

Abstract

Many machine learning applications require learning a function with a small worst-case error over the entire input domain, that is, the L∞-error, whereas most existing theoretical works only guarantee recovery in average errors such as the L2-error. L∞-recovery from polynomial samples is even impossible for seemingly simple function classes such as constant-norm infinite-width two-layer neural nets. This paper makes some initial steps beyond the impossibility results by leveraging the randomness in the ground-truth functions. We prove a polynomial sample complexity bound for random ground-truth functions drawn from Gaussian random fields. Our key technical novelty is to prove that the degree-k spherical harmonics components of a function from Gaussian random field cannot be spiky in that their L∞/L2 ratios are upperbounded by O(d k) with high probability. In contrast, the worst-case L∞/L2 ratio for degree-k spherical harmonics is on the order of (\dk/2,kd/2\).