Uniform Concentration for $\alpha$-subexponential Random Operators
Abstract
Random matrices acting on structured sets play a fundamental role in high-dimensional geometry, compressed sensing, and randomized algorithms. Existing results primarily focus on subgaussian models, when random matrices act as near-isometries on sets with optimal tail behavior. Nevertheless, very often in applications we deal with distributions with heavy tails that are not subgaussian but have at least exponential-type tails. In this work, we study random matrices A whose rows (or columns) have -subexponential tail distributions with . So subgaussian and sub-exponential models are included in as special cases. We establish concentration type inequality for , where x belongs to the bounded subsets of , showing that their geometric distortion is governed by Talagrand's functional of the set and depends on the tail parameter . Our results extend the known optimal inequalities in the subgaussian regime (), and provide new guarantees for heavier-tailed, yet exponentially integrable, random matrices. These findings extend the theory of random matrices beyond the subgaussian framework. Moreover, they yield near-isometric embedding results applicable to dimension reduction and allow us to make robust high-dimensional inference under non-Gaussian measurements.
Cite
@article{arxiv.2603.09487,
title = {Uniform Concentration for $\alpha$-subexponential Random Operators},
author = {Tiankun Diao and Xuanang Hu and Vladimir V. Ulyanov and Hanchao Wang},
journal= {arXiv preprint arXiv:2603.09487},
year = {2026}
}