A King in every two consecutive tournaments

Abstract: We think of a tournament $T=([n], E)$ as a communication network where in each round of communication processor $P_i$ sends its information to $P_j$, for every directed edge $ij \in E(T)$. By Landau's theorem (1953) there is a King in $T$, i.e., a processor whose initial input reaches every other processor in two rounds or less. Namely, a processor $P_{\nu}$ such that after two rounds of communication along $T$'s edges, the initial information of $P_{\nu}$ reaches all other processors. Here we consider a more general scenario where an adversary selects an arbitrary series of tournaments $T_1, T_2,\ldots$, so that in each round $s=1, 2, \ldots$, communication is governed by the corresponding tournament $T_s$. We prove that for every series of tournaments that the adversary selects, it is still true that after two rounds of communication, the initial input of at least one processor reaches everyone. Concretely, we show that for every two tournaments $T_1, T_2$ there is a vertex in $[n]$ that can reach all vertices via (i) A step in $T_1$, or (ii) A step in $T_2$ or (iii) A step in $T_1$ followed by a step in $T_2$. }