Equality of H\"older exponents for distribution functions of Gibbs measures

Abstract

Pointwise H\"older exponents describe the degree of regularity of a function near a point. For a function f:R, a number α>0 and a point t0∈R, write f∈ Cα(t0) if there is a constant C and a polynomial P of degree less than α such that \[ |f(t)-P(t-t0)|≤ C|t-t0|α for all t∈R. \] The pointwise H\"older exponent of f at t0 is the number \[ αf(t0):=\α>0: f∈ Cα(t0)\. \] A simpler quantity, also frequently called pointwise H\"older exponent in the mathematical literature, is the number \[ αf(t0):=\α>0: f∈ Cα(t0)\, \] where f∈ Cα(t0) means that there is a constant C>0 such that |f(t)-f(t0)|≤ C|t-t0|α for all t∈R. Clearly αf(t)≥ αf(t), but strict inequality is possible and in fact common. In this paper we consider the case when f=Fμ is the distribution function of a Gibbs measure μ associated with an arbitrary H\"older continuous potential on a self-conformal set, and show that, under a very mild condition on , αf(t)=αf(t) for all t. As a consequence, we deduce that the pointwise H\"older spectrum of f satisfies the multifractal formalism. As an application, we derive the pointwise H\"older spectrum of conjugacy maps between expanding piecewise C1+ε maps of an interval.