Strictly monotonic multidimensional sequences and stable sets in pillage games
Abstract: Let $S \subset \mathbb{R}n$ have size $|S| > \ell{2n-1}$. We show that there are distinct points ${x1,..., x{\ell+1}} \subset S$ such that for each $i \in [n]$, the coordinate sequence $(xj_i)_{j=1}{\ell+1}$ is strictly increasing, strictly decreasing, or constant, and that this bound on $|S|$ is best possible. This is analogous to the \erdos-Szekeres theorem on monotonic sequences in $\real$. We apply these results to bound the size of a stable set in a pillage game. We also prove a theorem of independent combinatorial interest. Suppose ${a1,b1,...,at,bt}$ is a set of $2t$ points in $\realn$ such that the set of pairs of points not sharing a coordinate is precisely ${{a1,b1},...,{at,bt}}$. We show that $t \leq 2{n-1}$, and that this bound is best possible.
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