On representable graphs, semi-transitive orientations, and the representation numbers

A graph $G=(V,E)$ is representable if there exists a word $W$ over the alphabet $V$ such that letters $x$ and $y$ alternate in $W$ if and only if $(x,y)\in E$ for each $x\neq y$. If $W$ is $k$-uniform (each letter of $W$ occurs exactly $k$ times in it) then $G$ is called $k$-representable. It was shown that a graph is representable if and only if it is $k$-representable for some $k$. Minimum $k$ for which a representable graph $G$ is $k$-representable is called its representation number. In this paper we give a characterization of representable graphs in terms of orientations. Namely, we show that a graph is representable if and only if it admits an orientation into a so-called \emph{semi-transitive digraph}. This allows us to prove a number of results about representable graphs, not the least that 3-colorable graphs are representable. We also prove that the representation number of a graph on $n$ nodes is at most $n$, from which one concludes that the recognition problem for representable graphs is in NP. This bound is tight up to a constant factor, as we present a graph whose representation number is $n/2$. We also answer several questions, in particular, on representability of the Petersen graph and local permutation representability.