English

On Small Sets of Integers

Number Theory 2022-01-26 v4 Classical Analysis and ODEs Functional Analysis

Abstract

An upper quasi-density on H\bf H (the integers or the non-negative integers) is a real-valued subadditive function μ\mu^\ast defined on the whole power set of H\mathbf H such that μ(X)μ(H)=1\mu^\ast(X) \le \mu^\ast({\bf H}) = 1 and μ(kX+h)=1kμ(X)\mu^\ast(k \cdot X + h) = \frac{1}{k}\, \mu^\ast(X) for all XHX \subseteq \bf H, kN+k \in {\bf N}^+, and hNh \in \bf N, where kX:={kx:xX}k \cdot X := \{kx: x \in X\}; and an upper density on H\bf H is an upper quasi-density on H\bf H that is non-decreasing with respect to inclusion. We say that a set XHX \subseteq \bf H is small if μ(X)=0\mu^\ast(X) = 0 for every upper quasi-density μ\mu^\ast on H\bf H. Main examples of upper densities are given by the upper analytic, upper Banach, upper Buck, and upper P\'olya densities, along with the uncountable family of upper α\alpha-densities, where α\alpha is a real parameter 1\ge -1 (most notably, α=1\alpha = -1 corresponds to the upper logarithmic density, and α=0\alpha = 0 to the upper asymptotic density). It turns out that a subset of H\bf H is small if and only if it belongs to the zero set of the upper Buck density on Z\bf Z. This allows us to show that many interesting sets are small, including the integers with less than a fixed number of prime factors, counted with multiplicity; the numbers represented by a binary quadratic form with integer coefficients whose discriminant is not a perfect square; and the image of Z\bf Z through a non-linear integral polynomial in one variable.

Keywords

Cite

@article{arxiv.1905.08075,
  title  = {On Small Sets of Integers},
  author = {Paolo Leonetti and Salvatore Tringali},
  journal= {arXiv preprint arXiv:1905.08075},
  year   = {2022}
}

Comments

15 pp, no figures. The paper is a sequel of arXiv:1506.04664. Fixed minor details. To appear in The Ramanujan Journal

R2 v1 2026-06-23T09:13:14.833Z