Covering Complete Geometric Graphs by Monotone Paths

Given a set $A$ of $n$ points (vertices) in general position in the plane, the \emph{complete geometric graph} $K_n[A]$ consists of all ${n\choose 2}$ segments (edges) between the elements of $A$. It is known that the edge set of every complete geometric graph on $n$ vertices can be partitioned into $O(n^{3/2})$ noncrossing paths (or matchings). We strengthen this result under various additional assumptions on the point set. In particular, we prove that for a set $A$ of $n$ \emph{randomly} selected points, uniformly distributed in $[0,1]^2$, with probability tending to $1$ as $n\rightarrow\infty$, the edge set of $K_n[A]$ can be covered by $O(n^{4/3} t(n))$ noncrossing paths (or matchings), where $t(n)$ is any function tending to $\infty$. On the other hand, we construct $n$-element point sets such that covering the edge set of $K_n(A)$ requires a quadratic number of monotone paths.