Optimal Variance--Gamma approximation on the second Wiener chaos
Abstract
In this paper, we consider a target random variable Y distributed according to a centered Variance--Gamma distribution. For a generic random element F=I2(f) in the second Wiener chaos with [F2]= [Y2] we establish a non-asymptotic optimal bound on the distance between F and Y in terms of the maximum of difference of the first six cumulants. This six moment theorem extends the celebrated optimal fourth moment theorem of I.\ Nourdin \& G.\ Peccati for normal approximation. The main body of our analysis constitutes a splitting technique for test functions in the Banach space of Lipschitz functions relying on the compactness of the Stein operator. The recent developments around Stein method for Variance--Gamma approximation by R.\ Gaunt play a significant role in our study. As an application we consider the generalized Rosenblatt process at the extreme critical exponent, first studied by S.\ Bai \& M.\ Taqqu.
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