Normal approximation for the polynomial functionals of correlated random field sampling along random walk path in dimension 1+1

Abstract

Let be the stationary occupation field generated by a Poisson system of independent simple symmetric random walks on Z in space--time dimension 1+1. For a finite set A⊂ Z, we consider the classical fixed-region observables WN(A), the cumulative occupation of A up to time N, and DN(A), the number of distinct particles visiting A up to time N. We prove quantitative central limit theorems for both observables, with Wasserstein rate of order N-1/4. In addition, we introduce an independent nearest-neighbour random walk S=(Sn,\,n 0) on Z with non-zero drift and sample the field along this ballistic path. For a fixed polynomial observable (x)=Σj=0k βj xj, βk≠ 0, of degree k∈ N, we consider the partial sums YN,=Σn=1N ((n,Sn)). We prove a Wasserstein bound of order N-1/2 for the normal approximation of the standardized YN,. To the best of our knowledge, this is the first quantitative normal approximation result for polynomial functionals of the Poisson occupation field sampled along a random walk path. The drift induces an effective decorrelation of the sampled environment, leading to a substantial improvement over fixed-region sampling. The proofs rely on a representation of as a Poisson functional on path space and on the Malliavin--Stein method for Poisson functionals.

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