Central Limit Theorems for Gaps of Generalized Zeckendorf Decompositions

Abstract

Zeckendorf proved that every integer can be written uniquely as a sum of non-adjacent Fibonacci numbers \1,2,3,5,…\. This has been extended to many other recurrence relations \Gn\ (with their own notion of a legal decomposition) and to proving that the distribution of the number of summands of an M ∈ [Gn, Gn+1) converges to a Gaussian as n∞. We prove that for any non-negative integer g the average number of gaps of size g in many generalized Zeckendorf decompositions is Cμ n+dμ+o(1) for constants Cμ > 0 and dμ depending on g and the recurrence, the variance of the number of gaps of size g is similarly Cσ n + dσ + o(1) with Cσ > 0, and the number of gaps of size g of an M∈[Gn,Gn+1) converges to a Gaussian as n∞. The proof is by analysis of an associated two-dimensional recurrence; we prove a general result on when such behavior converges to a Gaussian, and additionally re-derive other results in the literature.