Arithmetic subsequences in a random ordering of an additive set

For a finite set $A$ of size $n$, an ordering is an injection from $\{1,2,\ldots,n\}$ to $A$. We present results concerning the asymptotic properties of the length $L_n$ of the longest arithmetic subsequence in a random ordering of an additive set $A$. In the torsion-free case where $A = [1,n]^d\subseteq {\bf Z}^d$, we prove that there exists a function $\psi(n,d)$ such that $L_n\in \{\lfloor\psi(n,d)\rfloor, \lceil\psi(n,d)\rceil\}$ with probability tending to $1$ as $n\to\infty$, where $\psi(n,d)\sim 2d\log n/\log \log n$. We show that the case $A = {\bf Z}/n{\bf Z}$ behaves asymptotically like the torsion-free case with $d=1$, and then use this fact to compute the expected length of the longest arithmetic subsequence in a random ordering of an arbitrary finite abelian group. We also prove that the number of orderings of ${\bf Z}/n{\bf Z}$ without any arithmetic subsequence of length $3$ is $2^{n-1}$ when $n\geq 2$ is a power of $2$, and zero otherwise. We conclude with a concrete application to elementary $p$-groups and a discussion of possible noncommutative generalisations.