Gaussian Behavior of the Number of Summands in Zeckendorf Decompositions in Small Intervals

Abstract

Zeckendorf's theorem states that every positive integer can be written uniquely as a sum of non-consecutive Fibonacci numbers Fn, with initial terms F1 = 1, F2 = 2. We consider the distribution of the number of summands involved in such decompositions. Previous work proved that as n ∞ the distribution of the number of summands in the Zeckendorf decompositions of m ∈ [Fn, Fn+1), appropriately normalized, converges to the standard normal. The proofs crucially used the fact that all integers in [Fn, Fn+1) share the same potential summands. We generalize these results to subintervals of [Fn, Fn+1) as n ∞; the analysis is significantly more involved here as different integers have different sets of potential summands. Explicitly, fix an integer sequence α(n) ∞. As n ∞, for almost all m ∈ [Fn, Fn+1) the distribution of the number of summands in the Zeckendorf decompositions of integers in the subintervals [m, m + Fα(n)), appropriately normalized, converges to the standard normal. The proof follows by showing that, with probability tending to 1, m has at least one appropriately located large gap between indices in its decomposition. We then use a correspondence between this interval and [0, Fα(n)) to obtain the result, since the summands are known to have Gaussian behavior in the latter interval. % We also prove the same result for more general linear recurrences.