English

The pressure function for infinite equilibrium measures

Dynamical Systems 2018-10-10 v3

Abstract

Assume that (X,f)(X,f) is a dynamical system and ϕ:X[,)\phi:X \to [-\infty, \infty) is a potential such that the ff-invariant measure μϕ\mu_\phi equivalent to ϕ\phi-conformal measure is infinite, but that there is an inducing scheme F=fτF = f^\tau with a finite measure μϕˉ\mu_{\bar\phi} and polynomial tails μϕˉ(τn)=O(nβ)\mu_{\bar\phi}(\tau \geq n) = O(n^{-\beta}), β(0,1)\beta \in (0,1). We give conditions under which the pressure of ff for a perturbed potential ϕ+sψ\phi+s\psi relates to the pressure of the induced system as P(ϕ+sψ)=(CP(ϕ+sψ))1/β(1+o(1))P(\phi+s\psi) = (C P(\overline{\phi+s\psi}))^{1/\beta} (1+o(1)), together with estimates for the o(1)o(1)-error term. This extends results from Sarig to the setting of infinite equilibrium states. We give several examples of such systems, thus improving on the results of Lopes for the Pomeau-Manneville map with potential ϕt=tlogf\phi_t = - t\log f', as well as on the results by Bruin & Todd on countably piecewise linear unimodal Fibonacci maps. In addition, limit properties of the family of measures μϕ+sψ\mu_{\phi+s\psi} as s0s\to 0 are studied and statistical properties (correlation coefficients and arcsine laws) under the limit measure are derived.

Keywords

Cite

@article{arxiv.1711.05069,
  title  = {The pressure function for infinite equilibrium measures},
  author = {Henk Bruin and Dalia Terhesiu and Mike Todd},
  journal= {arXiv preprint arXiv:1711.05069},
  year   = {2018}
}

Comments

Corrections in Section 8.2. Other minor modifications in the presentation

R2 v1 2026-06-22T22:45:28.274Z