English

Sample complexity and effective dimension for regression on manifolds

Machine Learning 2020-10-19 v3 Machine Learning Statistics Theory Statistics Theory

Abstract

We consider the theory of regression on a manifold using reproducing kernel Hilbert space methods. Manifold models arise in a wide variety of modern machine learning problems, and our goal is to help understand the effectiveness of various implicit and explicit dimensionality-reduction methods that exploit manifold structure. Our first key contribution is to establish a novel nonasymptotic version of the Weyl law from differential geometry. From this we are able to show that certain spaces of smooth functions on a manifold are effectively finite-dimensional, with a complexity that scales according to the manifold dimension rather than any ambient data dimension. Finally, we show that given (potentially noisy) function values taken uniformly at random over a manifold, a kernel regression estimator (derived from the spectral decomposition of the manifold) yields minimax-optimal error bounds that are controlled by the effective dimension.

Keywords

Cite

@article{arxiv.2006.07642,
  title  = {Sample complexity and effective dimension for regression on manifolds},
  author = {Andrew McRae and Justin Romberg and Mark Davenport},
  journal= {arXiv preprint arXiv:2006.07642},
  year   = {2020}
}
R2 v1 2026-06-23T16:17:57.904Z