Periodicity and pure periodicity in alternate base systems

Abstract We study the Cantor real base numeration system which is a common generalization of two positional systems, namely the Cantor system with a sequence of integer bases and the Rényi system with one real base. We focus on the case of an alternate base B B given by a purely periodic sequence (ₙ) ₍ ₁ (β n) n ≥ 1 of real numbers greater than 1. We answer an open question of Charlier et al. (J Number Theory 254: 184–198, 2024, https: //doi. org/10. 1016/j. jnt. 2023. 07. 008) on the set of numbers with eventually periodic B B -expansions. We also investigate for which bases all sufficiently small rationals have a purely periodic B B -expansion. We show that a necessary condition for this phenomenon is that = ₍=₁^p ₙ δ = ∏ n = 1 p β n (where p is the period-length of B B) is a Pisot or a Salem unit. We also provide a sufficient condition. We thus generalize the results known for the Rényi numeration system, i. e. for the case when p=1 p = 1. We provide a class of alternate bases in which all rational numbers in the interval [0, 1) have a purely periodic B B -expansion.