Statistical Learning Theory for Neural Operators

Abstract

We present statistical convergence results for the learning of (possibly) non-linear mappings in infinite-dimensional spaces. Specifically, given a map G0: X Y between two separable Hilbert spaces, we analyze the problem of recovering G0 from n∈ N noisy input-output pairs (xi, yi)i=1n with yi = G0 (xi)+i; here the xi∈ X represent randomly drawn 'design' points, and the i are assumed to be either i.i.d. white noise processes or subgaussian random variables in Y. We provide general convergence results for least-squares-type empirical risk minimizers over compact regression classes G⊂eq L∞(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 G0 to be holomorphic, we prove algebraic (in the sample size n) 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.

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