On Monochromatic Ascending Waves
Abstract
A sequence of positive integers w1,w2,...,wn is called an ascending wave if wi+1-wi ≥ wi - wi-1 for 2 ≤ i ≤ n-1. For integers k,r≥1, let AW(k;r) be the least positive integer such that under any r-coloring of [1,AW(k;r)] there exists a k-term monochromatic ascending wave. The existence of AW(k;r) is guaranteed by van der Waerden's theorem on arithmetic progressions since an arithmetic progression is, itself, an ascending wave. Originally, Brown, Erdos, and Freedman defined such sequences and proved that k2-k+1≤ AW(k;2) ≤ 1/3(k3-4k+9). Alon and Spencer then showed that AW(k;2) = O(k3). In this article, we show that AW(k;3) = O(k5) as well as offer a proof of the existence of AW(k;r) independent of van der Waerden's theorem. Furthermore, we prove that for any ε > 0, k2r-1-ε2r-1(40r)r2-1(1+o(1)) ≤ AW(k;r) ≤ k2r-1(2r-1)!(1+o(1)) holds for all r ≥ 1, which, in particular, improves upon the best known upper bound for AW(k;2). Additionally, we show that for fixed k ≥ 3, AW(k;r)≤2k-2(k-1)! rk-1(1+o(1)).
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