Gaussian fluctuations for hyperbolic Anderson model with L\'evy colored noise

Abstract

In this article, we study the asymptotic behaviour of the spatial integral FR(t) of the solution to the hyperbolic Anderson model in dimension d=1, driven by the L\'evy colored noise introduced in Balan and Jim\'enez (2026). We assume that the spatial coloration kernel of the noise is either integrable on R, or is the Riesz kernel of order α ∈ (0,1), and the L\'evy measure of the noise has finite moments of order p and 2p for some p ∈ (1,2]. By applying a recent result of Trauthwein (2025), we prove that FR(t)/ Var(FR(t)) converges to the standard normal distribution as R ∞, and we give an estimate for the rate of this convergence in the Fortet-Mourier distance, the 1-Wasserstein distance, or the Kolmogorov distance. We also provide the corresponding functional limit result.