Path Extendable Tournaments

Abstract: A digraph $D$ is called \emph{path extendable} if for every nonhamiltonian (directed) path $P$ in $D$, there exists another path $P^\prime$ with the same initial and terminal vertices as $P$, and $V(P^\prime) = V (P)\cup {w}$ for a vertex $w \in V(D)\setminus V(P)$. Hence, path extendability implies paths of continuous lengths between every vertex pair. In earlier works of C. Thomassen and K. Zhang, it was shown that the condition of small $i(T)$ or positive $\pi_2(T)$ implies paths of continuous lengths between every vertex pair in a tournament $T$, where $i(T)$ is the irregularity of $T$ and $\pi_2(T)$ denotes for the minimum number of paths of length $2$ from $u$ to $v$ among all vertex pairs ${u,v}$. Motivated by these results, we study sufficient conditions in terms of $i(T)$ and $\pi_2(T)$ that guarantee a tournament $T$ is path extendable. We prove that (1) a tournament $T$ is path extendable if $i(T)< 2\pi_2(T)-(|T|+8)/6$, and (2) a tournament $T$ is path extendable if $\pi_2(T) > (7|T|-10)/36$. As an application, we deduce that almost all random tournaments are path extendable.