English

Half-space depth of log-concave probability measures

Probability 2023-09-18 v2 Functional Analysis

Abstract

Given a probability measure μ\mu on Rn{\mathbb R}^n, Tukey's half-space depth is defined for any xRnx\in {\mathbb R}^n by φμ(x)=inf{μ(H):HH(x)}\varphi_{\mu }(x)=\inf\{\mu (H):H\in {\cal H}(x)\}, where H(x){\cal H}(x) is the set of all half-spaces HH of Rn{\mathbb R}^n containing xx. We show that if μ\mu is log-concave then ec1nRnφμ(x)dμ(x)ec2n/Lμ2e^{-c_1n}\leq \int_{\mathbb{R}^n}\varphi_{\mu }(x)\,d\mu(x) \leq e^{-c_2n/L_{\mu}^2} where LμL_{\mu } is the isotropic constant of μ\mu and c1,c2>0c_1,c_2>0 are absolute constants. The proofs combine large deviations techniques with a number of facts from the theory of LqL_q-centroid bodies of log-concave probability measures. The same ideas lead to general estimates for the expected measure of random polytopes whose vertices have a log-concave distribution.

Keywords

Cite

@article{arxiv.2201.11992,
  title  = {Half-space depth of log-concave probability measures},
  author = {Silouanos Brazitikos and Apostolos Giannopoulos and Minas Pafis},
  journal= {arXiv preprint arXiv:2201.11992},
  year   = {2023}
}

Comments

Final version, to appear in Probability Theory and Related Fields

R2 v1 2026-06-24T09:06:56.633Z