Abstract
We consider two problems regarding arithmetic progressions in symmetric sets in the finite field (product space) model. First, we show that a symmetric set $S \subseteq \mathbb{Z}_q^n$ containing $|S| = \mu \cdot q^n$ elements must contain at least $\delta(q, \mu) \cdot q^n \cdot 2^n$ arithmetic progressions $x, x+d, \ldots, x+(q-1)\cdot d$ such that the difference $d$ is restricted to lie in $\{0,1\}^n$. Second, we show that for prime $p$ a symmetric set $S\subseteq\mathbb{F}_p^n$ with $|S|=\mu\cdot p^n$ elements contains at least $\mu^{C(p)}\cdot p^{2n}$ arithmetic progressions of length $p$. This establishes that the qualitative behavior of longer arithmetic progressions in symmetric sets is the same as for progressions of length three.
Highlights
In this paper we consider problems in the finite field model in additive combinatorics
The most well-known problem in this setting concerns arithmetic progressions: Given a subset S ⊆ Znq with density μ(S) := |S|/qn, what are the bounds on the number of arithmetic progressions of length k contained in S? The case q = k = 3 is called the
It is well known that this last statement is equivalent to the following: There exists a constant C > 0 such that every set S ⊆ Fn3 with density μ contains at least μC · 9n arithmetic progressions of length three
Summary
In this paper we consider problems in the finite field model in additive combinatorics. There, it has long been known [Rot[53], Mes95] that any subset of Fn3 of constant density must contain an arithmetic progression of length three for large enough n. An application of the density Hales-Jewett theorem establishes that a dense set S ⊆ Znq contains a non-trivial restricted progression of length q for large enough n. Our second result is a removal lemma for symmetric sets with respect to restricted progressions: Theorem 2. Similar as in the case of Theorem 1, it follows that a symmetric set S of density μ contains a dense fraction of all restricted progressions
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