Explicit entropy bounds for symmetric nearest-neighbor subshifts

Abstract

We provide another approach to Friedland's result that the topological entropy h of a symmetric nearest-neighbor subshift is computable. Instead of the previous algebraic technique, our approach is mostly combinatorial and involves only counts of locally admissible patterns Cn of a cube [1,n]d in Zd. The main idea is a reflection-gluing construction: we flip admissible patterns and merge them along their boundaries. In addition to a short and elementary proof, another advantage is that our approach yields an explicit convergence rate in arbitrary dimensions, whereas obtaining such a rate is already complicated for Z3 in Friedland's approach. In particular, we show that for every n 1, \[ 1nd( Cn+1 - qd(n)|Σ|) h 1nd Cn, \] where Σ is the alphabet and \[ qd(n)=(2d-1)Σk=0d-1 dk2d-2k\, nk. \]