English

High-dimensional CLT: Improvements, Non-uniform Extensions and Large Deviations

Statistics Theory 2019-06-26 v3 Statistics Theory

Abstract

Central limit theorems (CLTs) for high-dimensional random vectors with dimension possibly growing with the sample size have received a lot of attention in the recent times. Chernozhukov et al. (2017) proved a Berry--Esseen type result for high-dimensional averages for the class of hyperrectangles and they proved that the rate of convergence can be upper bounded by n1/6n^{-1/6} upto a polynomial factor of logp\log p (where nn represents the sample size and pp denotes the dimension). Convergence to zero of the bound requires log7p=o(n)\log^7p = o(n). We improve upon their result which only requires log4p=o(n)\log^4p = o(n) (in the best case). This improvement is made possible by a sharper dimension-free anti-concentration inequality for Gaussian process on a compact metric space. In addition, we prove two non-uniform variants of the high-dimensional CLT based on the large deviation and non-uniform CLT results for random variables in a Banach space by Bentkus, Ra{\v c}kauskas, and Paulauskas. We apply our results in the context of post-selection inference in linear regression and of empirical processes.

Keywords

Cite

@article{arxiv.1806.06153,
  title  = {High-dimensional CLT: Improvements, Non-uniform Extensions and Large Deviations},
  author = {Arun Kumar Kuchibhotla and Somabha Mukherjee and Debapratim Banerjee},
  journal= {arXiv preprint arXiv:1806.06153},
  year   = {2019}
}

Comments

76 pages

R2 v1 2026-06-23T02:31:48.046Z