Sharp High-dimensional Central Limit Theorems for Log-concave Distributions

Abstract

Let X1,…,Xn be i.i.d. log-concave random vectors in Rd with mean 0 and covariance matrix . We study the problem of quantifying the normal approximation error for W=n-1/2Σi=1nXi with explicit dependence on the dimension d. Specifically, without any restriction on , we show that the approximation error over rectangles in Rd is bounded by C(13(dn)/n)1/2 for some universal constant C. Moreover, if the Kannan-Lov\'asz-Simonovits (KLS) spectral gap conjecture is true, this bound can be improved to C(3(dn)/n)1/2. This improved bound is optimal in terms of both n and d in the regime n=O( d). We also give p-Wasserstein bounds with all p≥2 and a Cram\'er type moderate deviation result for this normal approximation error, and they are all optimal under the KLS conjecture. To prove these bounds, we develop a new Gaussian coupling inequality that gives almost dimension-free bounds for projected versions of p-Wasserstein distance for every p≥2. We prove this coupling inequality by combining Stein's method and Eldan's stochastic localization procedure.

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