English

Density estimation on an unknown submanifold

Statistics Theory 2020-11-02 v2 Statistics Theory

Abstract

We investigate density estimation from a nn-sample in the Euclidean space RD\mathbb R^D, when the data is supported by an unknown submanifold MM of possibly unknown dimension d<Dd < D under a reach condition. We study nonparametric kernel methods for pointwise loss, with data-driven bandwidths that incorporate some learning of the geometry via a local dimension estimator. When ff has H\"older smoothness β\beta and MM has regularity α\alpha, our estimator achieves the rate nαβ/(2αβ+d)n^{-\alpha \wedge \beta/(2\alpha \wedge \beta+d)} and does not depend on the ambient dimension DD and is asymptotically minimax for αβ\alpha \geq \beta. Following Lepski's principle, a bandwidth selection rule is shown to achieve smoothness adaptation. We also investigate the case αβ\alpha \leq \beta: by estimating in some sense the underlying geometry of MM, we establish in dimension d=1d=1 that the minimax rate is nβ/(2β+1)n^{-\beta/(2\beta+1)} proving in particular that it does not depend on the regularity of MM. Finally, a numerical implementation is conducted on some case studies in order to confirm the practical feasibility of our estimators.

Keywords

Cite

@article{arxiv.1910.08477,
  title  = {Density estimation on an unknown submanifold},
  author = {Clément Berenfeld and Marc Hoffmann},
  journal= {arXiv preprint arXiv:1910.08477},
  year   = {2020}
}

Comments

36 pages, 21 figures. v2 : important structural modifications and several minor corrections have been done, following comments from anonymous peer reviewers. We also added a new result (Thm 2.6) that underlines the necessity of the reach constraint

R2 v1 2026-06-23T11:47:57.153Z