From Fibonacci Numbers to Central Limit Type Theorems

Abstract

A beautiful theorem of Zeckendorf states that every integer can be written uniquely as a sum of non-consecutive Fibonacci numbers \Fn\n=1∞. Lekkerkerker proved that the average number of summands for integers in [Fn, Fn+1) is n/(φ2 + 1), with φ the golden mean. This has been generalized to the following: given nonnegative integers c1,c2,...,cL with c1,cL>0 and recursive sequence \Hn\n=1∞ with H1=1, Hn+1 =c1Hn+c2Hn-1+...+cnH1+1 (1 n< L) and Hn+1=c1Hn+c2Hn-1+...+cLHn+1-L (n≥ L), every positive integer can be written uniquely as Σ aiHi under natural constraints on the ai's, the mean and the variance of the numbers of summands for integers in [Hn, Hn+1) are of size n, and the distribution of the numbers of summands converges to a Gaussian as n goes to the infinity. Previous approaches used number theory or ergodic theory. We convert the problem to a combinatorial one. In addition to re-deriving these results, our method generalizes to a multitude of other problems (in the sequel paper BM we show how this perspective allows us to determine the distribution of gaps between summands in decompositions). For example, it is known that every integer can be written uniquely as a sum of the Fn's, such that every two terms of the same (opposite) sign differ in index by at least 4 (3). The presence of negative summands introduces complications and features not seen in previous problems. We prove that the distribution of the numbers of positive and negative summands converges to a bivariate normal with computable, negative correlation, namely -(21-2φ)/(29+2φ) ≈ -0.551058.