Uniform Concentration for α-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 α-subexponential tail distributions with α ∈ (0,2]. So subgaussian and sub-exponential models are included in as special cases. We establish concentration type inequality for Ax, where x belongs to the bounded subsets of Rn, showing that their geometric distortion is governed by Talagrand's functional of the set and depends on the tail parameter α. Our results extend the known optimal inequalities in the subgaussian regime (α=2), 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.
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