Bifurcation sets arising from non-integer base expansions

Abstract

Given a positive integer M and q∈(1,M+1], let Uq be the set of x∈[0, M/(q-1)] having a unique q-expansion: there exists a unique sequence (xi)=x1x2… with each xi∈\0,1,…, M\ such that \[ x=x1q+x2q2+x3q3+·s. \] Denote by Uq the set of corresponding sequences of all points in Uq. It is well-known that the function H: q h( Uq) is a Devil's staircase, where h( Uq) denotes the topological entropy of Uq. In this paper we give several characterizations of the bifurcation set \[ B:=\q∈(1,M+1]: H(p) H(q) for any p q\. \] Note that B is contained in the set UR of bases q∈(1,M+1] such that 1∈ Uq. By using a transversality technique we also calculate the Hausdorff dimension of the difference BR. Interestingly this quantity is always strictly between 0 and 1. When M=1 the Hausdorff dimension of BR is 23 λ*≈ 0.368699, where λ* is the unique root in (1, 2) of the equation x5-x4-x3-2x2+x+1=0.