Permutations that separate close elements (2207.09806v3)

Abstract: Let $n$ be a fixed integer with $n\geq 2$. For $i,j\in\mathbb{Z}_n$, define $||i,j||_n$ to be the distance between $i$ and $j$ when the elements of $\mathbb{Z}_n$ are written in a cycle. So $||i,j||_n=\min{(i-j)\bmod n,(j-i)\bmod n}$. For positive integers $s$ and $k$, the permutation $\pi:\mathbb{Z}_n\rightarrow\mathbb{Z}_n$ is \emph{$(s,k)$-clash-free} if $||\pi(i),\pi(j)||_n\geq k$ whenever $||i,j||_n<s$ with $i\not=j$. So an $(s,k)$-clash-free permutation $\pi$ can be thought of as moving every close pair of elements of $\mathbb{Z}_n$ to a pair at large distance. More geometrically, the existence of an $(s,k)$-clash-free permutation is equivalent to the existence of a set of $n$ non-overlapping $s\times k$ rectangles on an $n\times n$ torus, whose centres have distinct integer $x$-coordinates and distinct integer $y$-coordinates. For positive integers $n$ and $k$ with $k<n$, let $\sigma(n,k)$ be the largest value of $s$ such that an $(s,k)$-clash-free permutation on $\mathbb{Z}_n$ exists. In a paper, Mammoliti and Simpson conjectured that [ \lfloor (n-1)/k\rfloor-1\leq \sigma(n,k)\leq \lfloor (n-1)/k\rfloor ] for all integers $n$ and $k$ with $k<n$. The paper establishes this conjecture, by explicitly constructing an $(s,k)$-clash-free permutation on $\mathbb{Z}_n$ with $s=\lfloor (n-1)/k\rfloor-1$. Indeed, this construction is used to establish a more general conjecture of Mammoliti and Simpson, where for some fixed integer $r$ we require every point on the torus to be contained in the interior of at most $r$ rectangles.