Wasserstein-p Bounds via Cumulant-Based Edgeworth Expansion for α-Mixing Random Fields

Abstract

Recent progress has been made in establishing normal approximation bounds in terms of the Wasserstein-p distance for i.i.d. and locally dependent random variables. However, for p > 1, no such results have been demonstrated for dependent variables under α-mixing conditions. In this paper, we extend the Wasserstein-p bounds to α-mixing random fields. We show that, under appropriate conditions, the rescaled average of random fields converges to the standard normal distribution in the Wasserstein-p distance at a rate of O(|T|-β), where |T| is the size of the index set, and β ∈ (0, 1/2] depends on p, the dimension d of the random fields, and the decay rate of the α-mixing coefficients. Notably, β = 1/2 is achievable if the mixing coefficients decay at a sufficiently fast polynomial rate. Our results are derived through a carefully constructed cumulant-based Edgeworth expansion and an adaptation of recent developments in Stein's method. Additionally, we introduce a novel constructive graph approach that leverages combinatorial techniques to establish the desired expansion for general dependent variables.