Persistence of AR(1) sequences with Rademacher innovations and linear mod 1 transforms

Abstract

We study the probability that an AR(1) Markov chain Xn+1=aXn+n+1, where a∈(0,1) is a constant, stays non-negative for a long time. We find the exact asymptotics of this probability and the weak limit of Xn conditioned to stay non-negative, assuming that the i.i.d.\ innovations n take only two values 1 and a 23. This limiting distribution is quasi-stationary. It has no atoms and is singular with respect to the Lebesgue measure when 12< a 23, except for the case a=23 and P(n=1)=12, where this distribution is uniform on the interval [0,3]. This is similar to the properties of Bernoulli convolutions. For 0 < a 12, the situation is much simpler, and the limiting distribution is a δ-measure. To prove these results, we uncover a close connection between Xn killed at exiting [0, ∞) and the classical dynamical system defined by the piecewise linear mapping x 1a x + 12 1. Namely, the trajectory of this system started at Xn deterministically recovers the values of the killed chain in reversed time. We use this fact to construct a suitable Banach space, where the transition operator of the killed chain has the compactness properties that allow us to apply a conventional argument of the Perron--Frobenius type.