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Statistical Learning Theory for Neural Operators

Statistics Theory 2024-12-24 v1 Numerical Analysis Numerical Analysis Statistics Theory

Abstract

We present statistical convergence results for the learning of (possibly) non-linear mappings in infinite-dimensional spaces. Specifically, given a map G0:XYG_0:\mathcal X\to\mathcal Y between two separable Hilbert spaces, we analyze the problem of recovering G0G_0 from nNn\in\mathbb N noisy input-output pairs (xi,yi)i=1n(x_i, y_i)_{i=1}^n with yi=G0(xi)+εiy_i = G_0 (x_i)+\varepsilon_i; here the xiXx_i\in\mathcal X represent randomly drawn 'design' points, and the εi\varepsilon_i are assumed to be either i.i.d. white noise processes or subgaussian random variables in Y\mathcal{Y}. We provide general convergence results for least-squares-type empirical risk minimizers over compact regression classes GL(X,Y)\mathbf G\subseteq L^\infty(X,Y), in terms of their approximation properties and metric entropy bounds, which are derived using empirical process techniques. This generalizes classical results from finite-dimensional nonparametric regression to an infinite-dimensional setting. As a concrete application, we study an encoder-decoder based neural operator architecture termed FrameNet. Assuming G0G_0 to be holomorphic, we prove algebraic (in the sample size nn) convergence rates in this setting, thereby overcoming the curse of dimensionality. To illustrate the wide applicability, as a prototypical example we discuss the learning of the non-linear solution operator to a parametric elliptic partial differential equation.

Keywords

Cite

@article{arxiv.2412.17582,
  title  = {Statistical Learning Theory for Neural Operators},
  author = {Niklas Reinhardt and Sven Wang and Jakob Zech},
  journal= {arXiv preprint arXiv:2412.17582},
  year   = {2024}
}
R2 v1 2026-06-28T20:46:40.430Z