Covariance Representations, Lp-Poincar\'e Inequalities, Stein's Kernels and High Dimensional CLTs

Abstract

We explore connections between covariance representations, Bismut-type formulas and Stein's method. First, using the theory of closed symmetric forms, we derive covariance representations for several well-known probability measures on Rd, d ≥ 1. When strong gradient bounds are available, these covariance representations immediately lead to Lp-Lq covariance estimates, for all p ∈ (1, +∞) and q = p/(p-1). Then, we revisit the well-known Lp-Poincar\'e inequalities (p ≥ 2) for the standard Gaussian probability measure on Rd based on a covariance representation. Moreover, for the nondegenerate symmetric α-stable case, α ∈ (1,2), we obtain Lp-Poincar\'e and pseudo-Poincar\'e inequalities, for p ∈ (1, α), via a detailed analysis of the various Bismut-type formulas at our disposal. Finally, using the construction of Stein's kernels by closed forms techniques, we obtain quantitative high-dimensional CLTs in 1-Wasserstein distance when the limiting Gaussian probability measure is anisotropic. The dependence on the parameters is completely explicit and the rates of convergence are sharp.