Generalizing Zeckendorf's Theorem to f-decompositions

Abstract

A beautiful theorem of Zeckendorf states that every positive integer can be uniquely decomposed as a sum of non-consecutive Fibonacci numbers \Fn\, where F1 = 1, F2 = 2 and Fn+1 = Fn + Fn-1. For general recurrences \Gn\ with non-negative coefficients, there is a notion of a legal decomposition which again leads to a unique representation, and the number of summands in the representations of uniformly randomly chosen m ∈ [Gn, Gn+1) converges to a normal distribution as n ∞. We consider the converse question: given a notion of legal decomposition, is it possible to construct a sequence \an\ such that every positive integer can be decomposed as a sum of terms from the sequence? We encode a notion of legal decomposition as a function f:00 and say that if an is in an "f-decomposition", then the decomposition cannot contain the f(n) terms immediately before an in the sequence; special choices of f yield many well known decompositions (including base-b, Zeckendorf and factorial). We prove that for any f:00, there exists a sequence \an\n=0∞ such that every positive integer has a unique f-decomposition using \an\. Further, if f is periodic, then the unique increasing sequence \an\ that corresponds to f satisfies a linear recurrence relation. Previous research only handled recurrence relations with no negative coefficients. We find a function f that yields a sequence that cannot be described by such a recurrence relation. Finally, for a class of functions f, we prove that the number of summands in the f-decomposition of integers between two consecutive terms of the sequence converges to a normal distribution.