The complete Lq-spectrum and large deviations for return times for equilibrium states with summable potentials

Abstract

Let (Xk)k≥ 0 be a stationary and ergodic process with joint distribution μ where the random variables Xk take values in a finite set A. Let Rn be the first time this process repeats its first n symbols of output. It is well-known that 1n Rn converges almost surely to the entropy of the process. Refined properties of Rn (large deviations, multifractality, etc) are encoded in the return-time Lq-spectrum defined as \[ R(q)=n1n∫ Rnq \,dμ (q∈R) \] provided the limit exists. We consider the case where (Xk)k≥ 0 is distributed according to the equilibrium state of a potential :AN with summable variation, and we prove that \[ R(q) = cases P((1-q)) & for\;\; q≥ q*\\ η ∫ \, dη & for\;\; q<q* cases \] where P((1-q)) is the topological pressure of (1-q), the supremum is taken over all shift-invariant measures, and q* is the unique solution of P((1-q)) =η ∫ \, dη. Unexpectedly, this spectrum does not coincide with the Lq-spectrum of μ, which is P((1-q)), and does not coincide with the waiting-time Lq-spectrum in general. In fact, the return-time Lq-spectrum coincides with the waiting-time Lq-spectrum if and only if the equilibrium state of is the measure of maximal entropy. As a by-product, we also improve the large deviation asymptotics of 1n Rn.