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Learning linear operators: Infinite-dimensional regression as a well-behaved non-compact inverse problem

Statistics Theory 2024-07-11 v3 Functional Analysis Probability Machine Learning Statistics Theory

Abstract

We consider the problem of learning a linear operator θ\theta between two Hilbert spaces from empirical observations, which we interpret as least squares regression in infinite dimensions. We show that this goal can be reformulated as an inverse problem for θ\theta with the feature that its forward operator is generally non-compact (even if θ\theta is assumed to be compact or of pp-Schatten class). However, we prove that, in terms of spectral properties and regularisation theory, this inverse problem is equivalent to the known compact inverse problem associated with scalar response regression. Our framework allows for the elegant derivation of dimension-free rates for generic learning algorithms under H\"older-type source conditions. The proofs rely on the combination of techniques from kernel regression with recent results on concentration of measure for sub-exponential Hilbertian random variables. The obtained rates hold for a variety of practically-relevant scenarios in functional regression as well as nonlinear regression with operator-valued kernels and match those of classical kernel regression with scalar response.

Keywords

Cite

@article{arxiv.2211.08875,
  title  = {Learning linear operators: Infinite-dimensional regression as a well-behaved non-compact inverse problem},
  author = {Mattes Mollenhauer and Nicole Mücke and T. J. Sullivan},
  journal= {arXiv preprint arXiv:2211.08875},
  year   = {2024}
}

Comments

40 pages, 1 figure

R2 v1 2026-06-28T06:02:08.230Z