On sets of integers which contain no three terms in geometric progression

Abstract: Abstract. The problem of looking for subsets of the natural numbers which contain no 3-term arithmetic progressions has a rich history. Roth's theorem famously shows that any such subset cannot have positive upper density. In contrast, Rankin in 1960 suggested looking at subsets without three-term geometric progressions, and constructed such a subset with density about 0.719. More recently, several authors have found upper bounds for the upper density of such sets. We significantly improve upon these bounds, a… Show more

“…In the case where the smallest non-unit element has norm 3, we have that the proportion of excluded elements is bounded above by (4.4) and in the case where the smallest non-unit element has norm 4, we have that the proportion of excluded elements is bounded above by We can conceivably improve these bounds by taking into account more possible ratios. We do so, generalizing an argument made over the integers in [4]. For a quadratic number field K = Q √ d , and an integer n ∈ Z, we define an element (or ideal) of the ring of integers O K to be n-smooth if its factorization into irreducible elements consists entirely of elements with norm at most n.…”

“…The results of this computation are summarized in Table 4. [4], also discussed more recently by Nathanson and O'Bryant [7]. For illustration, we first consider the Gaussian integers and construct a subset S ⊂ Z[i] that has a large upper density and that avoids geometric progressions.…”

“…Rankin constructed a larger set, with asymptotic density approximately 0.71974. Modifying the construction of this set slightly, (see [4]) one can get a small improvement, producing a set with density about 0.72195. It is not known what the greatest possible asymptotic density of such a set is, however several authors have considered sets with greater upper asymptotic density.…”

Geometric-progression-free sets over quadratic number fields

“…In the case where the smallest non-unit element has norm 3, we have that the proportion of excluded elements is bounded above by (4.4) and in the case where the smallest non-unit element has norm 4, we have that the proportion of excluded elements is bounded above by We can conceivably improve these bounds by taking into account more possible ratios. We do so, generalizing an argument made over the integers in [4]. For a quadratic number field K = Q √ d , and an integer n ∈ Z, we define an element (or ideal) of the ring of integers O K to be n-smooth if its factorization into irreducible elements consists entirely of elements with norm at most n.…”

“…The results of this computation are summarized in Table 4. [4], also discussed more recently by Nathanson and O'Bryant [7]. For illustration, we first consider the Gaussian integers and construct a subset S ⊂ Z[i] that has a large upper density and that avoids geometric progressions.…”

“…Rankin constructed a larger set, with asymptotic density approximately 0.71974. Modifying the construction of this set slightly, (see [4]) one can get a small improvement, producing a set with density about 0.72195. It is not known what the greatest possible asymptotic density of such a set is, however several authors have considered sets with greater upper asymptotic density.…”

Geometric-progression-free sets over quadratic number fields

“…It seems possible that a similar construction might yield a set with higher asymptotic density in F q [x]. In previous work, [Mc,Section 4], [BHMMPTW,Section 4.2] in different rings, improved upper bounds for the upper density were obtained by considering progressions among the smooth integers. Thus far this technique has not proven to be as useful in this ring, however it may just be that more work and computation are required.…”

Subsets of Fq[x] free of 3-term geometric progressions

“…Let A be a k-GP-free sequence. The question of finding the maximal possible asymptotic density d(A), or else the upper density d U (A), of A has been a subject of recent study [2,3,12,15,15]. For an exposition of progress on this problem and the tightest known bounds on d U (A), along with constructions of A with nearly optimal upper density, see the paper of McNew [12].…”

Geometric progression-free sequences with small gaps