English

Optimal Mean Estimation without a Variance

Statistics Theory 2020-12-10 v2 Data Structures and Algorithms Machine Learning Machine Learning Statistics Theory

Abstract

We study the problem of heavy-tailed mean estimation in settings where the variance of the data-generating distribution does not exist. Concretely, given a sample X={Xi}i=1n\mathbf{X} = \{X_i\}_{i = 1}^n from a distribution D\mathcal{D} over Rd\mathbb{R}^d with mean μ\mu which satisfies the following \emph{weak-moment} assumption for some α[0,1]{\alpha \in [0, 1]}: \begin{equation*} \forall \|v\| = 1: \mathbb{E}_{X \thicksim \mathcal{D}}[\lvert \langle X - \mu, v\rangle \rvert^{1 + \alpha}] \leq 1, \end{equation*} and given a target failure probability, δ\delta, our goal is to design an estimator which attains the smallest possible confidence interval as a function of n,d,δn,d,\delta. For the specific case of α=1\alpha = 1, foundational work of Lugosi and Mendelson exhibits an estimator achieving subgaussian confidence intervals, and subsequent work has led to computationally efficient versions of this estimator. Here, we study the case of general α\alpha, and establish the following information-theoretic lower bound on the optimal attainable confidence interval: \begin{equation*} \Omega \left(\sqrt{\frac{d}{n}} + \left(\frac{d}{n}\right)^{\frac{\alpha}{(1 + \alpha)}} + \left(\frac{\log 1 / \delta}{n}\right)^{\frac{\alpha}{(1 + \alpha)}}\right). \end{equation*} Moreover, we devise a computationally-efficient estimator which achieves this lower bound.

Keywords

Cite

@article{arxiv.2011.12433,
  title  = {Optimal Mean Estimation without a Variance},
  author = {Yeshwanth Cherapanamjeri and Nilesh Tripuraneni and Peter L. Bartlett and Michael I. Jordan},
  journal= {arXiv preprint arXiv:2011.12433},
  year   = {2020}
}

Comments

Fixed typographical errors in Theorem 1.2, Lemmas 4.3 and C.8

R2 v1 2026-06-23T20:29:25.145Z