On the oriented chromatic index of oriented graphs

We introduce in this paper the notion of the chromatic number of an oriented graph G (that is of an antisymmetric directed graph) defined as the minimum order of an oriented graph H such that G admits a homomorphism to H. We study the chromatic number of oriented k-trees and of oriented graphs with

The oriented chromatic number χ o ( G) of an oriented graph G = (V, A) is the minimum number of vertices in an oriented graph H for which there exists a homomorphism of G to H. The oriented chromatic number χ o (G) of an undirected graph G is the maximum of the oriented chromatic numbers of all the

For every positive integer k, we present an oriented graph G k such that deleting any vertex of G k decreases its oriented chromatic number by at least k and deleting any arc decreases the oriented chromatic number of G k by two.

## Abstract A kernel of a directed graph is a set of vertices __K__ that is both absorbant and independent (i.e., every vertex not in __K__ is the origin of an arc whose extremity is in __K__, and no arc of the graph has both endpoints in __K__). In 1983, Meyniel conjectured that any perfect graph,

A 2-assignment on a graph G (V,E) is a collection of pairs Lv of allowed colors speci®ed for all vertices v PV. The graph G (with at least one edge) is said to have oriented choice number 2 if it admits an orientation which satis®es the following property: For every 2-assignment there exists a choic

## Abstract We extend Landau's concept of the score structure of a tournament to that of the score sequence of an oriented graph, and give a condition for an arbitrary integer sequence to be a score sequence. The proof is by construction of a specific oriented graph Δ(__S__) with given score sequen