Integer complexity: Stability and self-similarity

Abstract

Define ||n|| to be the complexity of n, the smallest number of ones needed to write n using an arbitrary combination of addition and multiplication. The set D of defects, differences δ(n):=||n||-33 n, is known to be a well-ordered subset of [0,∞), with order type ωω. This is proved by showing that, for any r, there is a finite set Ss of certain multilinear polynomials, called low-defect polynomials, such that δ(n) s if and only if one can write n = f(3k1,…,3kr)3kr+1. In this paper we show that, in addition to it being true that D (and thus D) has order type ωω, this set satisifies a sort of self-similarity property with D' = D + 1. This is proven by restricting attention to substantial low-defect polynomials, ones that can be themselves written efficiently in a certain sense, and showing that in a certain sense the values of these polynomials at powers of 3 have complexity equal to the na\"ive upper bound most of the time. As a result, we also prove that, under appropriate conditions on a and b, numbers of the form b(a3k+1)3 will, for all sufficiently large k, have complexity equal to the na\"ive upper bound. These results resolve various earlier conjectures of the second author.