More results on the z-chromatic number of graphs

Abstract

By a z-coloring of a graph G we mean any proper vertex coloring consisting of the color classes C1, …, Ck such that (i) for any two colors i and j with 1 ≤ i < j ≤ k, any vertex of color j is adjacent to a vertex of color i, (ii) there exists a set \u1, …, uk\ of vertices of G such that uj ∈ Cj for any j ∈ \1, …, k\ and uk is adjacent to uj for each 1 ≤ j ≤ k with j =k, and (iii) for each i and j with i = j, the vertex uj has a neighbor in Ci. Denote by z(G) the maximum number of colors used in any z-coloring of G. Denote the Grundy and b-chromatic number of G by (G) and b(G), respectively. The z-coloring is an improvement over both the Grundy and b-coloring of graphs. We prove that z(G) is much better than \(G), b(G)\ for infinitely many graphs G by obtaining an infinite sequence \Gn\n=3∞ of graphs such that z(Gn)=n but (Gn)= b(Gn)=2n-1 for each n≥ 3. We show that acyclic graphs are z-monotonic and z-continuous. Then it is proved that to decide whether z(G)=(G)+1 is NP-complete even for bipartite graphs G. We finally prove that to recognize graphs G satisfying z(G)=(G) is coNP-complete, improving a previous result for the Grundy number.