Locality in Sumsets

Abstract

Motivated by the Polynomial Freiman-Ruzsa (PFR) Conjecture, we develop a theory of locality in sumsets, with applications to John-type approximation and sets with small doubling. First we show that if A ⊂ Z with |A+A| (1-ε) 2d |A| is non-degenerate then A is covered by O(2d) translates of a d-dimensional generalised arithmetic progression (d-GAP) P with |P| Od,ε(|A|); thus we obtain one of the polynomial bounds required by PFR, under the non-degeneracy assumption that A is not efficiently covered by Od,ε(1) translates of a (d-1)-GAP. We also prove a stability result showing for any ε,α>0 that if A ⊂ Z with |A+A| (2-ε)2d|A| is non-degenerate then some A' ⊂ A with |A'|>(1-α)|A| is efficiently covered by either a (d+1)-GAP or Oα(1) translates of a d-GAP. This `dimension-free' bound for approximate covering makes for a stark contrast with exact covering, where the required number of translates grows exponentially with d. We further show that if A ⊂ Z is non-degenerate with |A+A| (2d + )|A| and 0.1 · 2d then A is covered by +1 translates of a d-GAP P with |P| Od(|A|); this is tight, in that +1 cannot be replaced by any smaller number. The above results also hold for A ⊂ Rd, replacing GAPs by a suitable common generalisation of GAPs and convex bodies. In this setting the non-degeneracy condition holds automatically, so we obtain essentially optimal bounds with no additional assumption on A. These results are all deduced from a unifying theory, in which we introduce a new intrinsic structural approximation of any set, which we call the `additive hull', and develop its theory via a refinement of Freiman's theorem with additional separation properties.