Multidimensional Stein method and quantitative asymptotic independence

Abstract

If Y is a random vector in Rd, we denote by PY its probability distribution. Consider a random variable X and a d-dimensional random vector Y. Inspired by Pi, we develop a multidimensional Stein-Malliavin calculus which allows to measure the Wasserstein distance between the law P (X, Y) and the probability distribution PZ PY, where Z is a Gaussian random variable. That is, we give estimates, in terms of the Malliavin operators, for the distance between the law of the random vector (X, Y) and the law of the vector (Z, Y), where Z is Gaussian and independent of Y. Then we focus on the particular case of random vectors in Wiener chaos and we give an asymptotic version of this result. In this situation, this variant of the Stein-Malliavin calculus has strong and unexpected consequences. Let (Xk, k≥ 1) be a sequence of random variables in the pth Wiener chaos (p≥ 2), which converges in law, as k ∞, to the Gaussian distribution N(0, σ2). Also consider (Yk, k≥ 1) a d-dimensional random sequence converging in L2(), as k ∞, to an arbitrary random vector U in Rd and assume that the two sequences are asymptotically uncorrelated. We prove that, under very light assumptions on Yk, we have the joint convergence of (Xk, Yk), k≥ 1) to (Z, U) where Z N(0, σ 2) is indeendent of U. These assumptions are automatically satisfied when the components of the vector Yk belong to a finite sum of Wiener chaoses or when Yk=Y for every k≥ 1, where Y belongs to the Sobolev-Malliavin space D1,2.