The Covering Threshold of a Directed Acyclic Graph by Directed Acyclic Subgraphs

Abstract

Let $H$ be a directed acyclic graph (dag) that is not a rooted star. It is known that there are constants $c=c(H)$ and $C=C(H)$ such that the following holds for $D_n$, the complete directed graph on $n$ vertices. There is a set of at most $C\log n$ directed acyclic subgraphs of $D_n$ that covers every $H$-copy of $D_n$, while every set of at most $c\log n$ directed acyclic subgraphs of $D_n$ does not cover all $H$-copies. Here this dichotomy is considerably strengthened.
 Let ${\vec G}(n,p)$ denote the probability space of all directed graphs with $n$ vertices and with edge probability $p$. The fractional arboricity of $H$ is $a(H) = max \{\frac{|E(H')|}{|V(H')|-1}\}$, where the maximum is over all non-singleton subgraphs of $H$. If $a(H) = \frac{|E(H)|}{|V(H)|-1}$ then $H$ is totally balanced. Complete graphs, complete multipartite graphs, cycles, trees, and, in fact, almost all graphs, are totally balanced. It is proven that:
 
 Let $H$ be a dag with $h$ vertices and $m$ edges which is not a rooted star. For every $a^* > a(H)$ there exists $c^* = c^*(a^*,H) > 0$ such a.a.s. $G \sim {\vec G}(n,n^{-1/a^*})$ has the property that every set $X$ of at most $c^*\log n$ directed acyclic subgraphs of $G$ does not cover all $H$-copies of $G$. Moreover, there exists $s(H) = m/2 + O(m^{4/5}h^{1/5})$ such that the following stronger assertion holds for any such $X$: there is an $H$-copy in $G$ that has no more than $s(H)$ of its edges covered by each element of $X$.
 If $H$ is totally balanced then for every $0 < a^* < a(H)$, a.a.s. $G \sim {\vec G}(n,n^{-1/a^*})$ has a single directed acyclic subgraph that covers all its $H$-copies.
 
 As for the first result, note that if $h=o(m)$ then $s(H)=(1+o_m(1))m/2$ is about half of the edges of $H$. In fact, for infinitely many $H$ it holds that $s(H)=m/2$, optimally. As for the second result, the requirement that $H$ is totally balanced cannot, generally, be relaxed.