Fractional smoothness of distributions of polynomials and a fractional analog of the Hardy--Landau--Littlewood inequality

Abstract

We prove that the distribution density of any non-constant polynomial f(1,2,…) of degree d in independent standard Gaussian random variables (possibly, in infinitely many variables) always belongs to the Nikol'skii--Besov space B1/d(R1) of fractional order 1/d (and this order is best possible), and an analogous result holds for polynomial mappings with values in Rk. Our second main result is an upper bound on the total variation distance between two probability measures on Rk via the Kantorovich distance between them and a suitable Nikol'skii--Besov norm of their difference. As an application we consider the total variation distance between the distributions of two random k-dimensional vectors composed of polynomials of degree d in Gaussian random variables and show that this distance is estimated by a fractional power of the Kantorovich distance with an exponent depending only on d and k, but not on the number of variables of the considered polynomials.