Compound Poisson statistics for dynamical systems via spectral perturbation

Abstract

We consider random transformations Tωn:=Tσn-1ω·s Tσω Tω, where each map Tω acts on a complete metrizable space M. The randomness comes from an invertible ergodic driving map σ: acting on a probability space (,F,m). For a family of random target sets Hω, n⊂ M that shrink as n∞, we consider quenched compound Poisson statistics of returns of random orbits to these random targets. We develop a spectral approach to such statistics: associated with the random map cocycle is a transfer operator cocycle Lnω,0:=Lσn-1ω,0·sσω,0ω,0, where Lω,0 is the transfer operator for the map Tω. We construct a perturbed cocycle with generator Lω,n,s(·):=Lω,0(· eis1Hω,n) and an associated random variable Sω,n,k(x):=Σj=0k-11Hσjω,n(Tωjx), which counts the number of visits to random targets in an orbit of length k. Under suitable assumptions, we show that in the n∞ limit, the random variables Sω,n,n converge in distribution to a compound Poisson distributed random variable. We provide several explicit examples for piecewise monotone interval maps in both the deterministic and random settings.