Complete coloring

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In graph theory, a complete coloring is a (proper) vertex coloring in which every pair of colors appears on at least one pair of adjacent vertices. Equivalently, a complete coloring is minimal in the sense that it cannot be transformed into a proper coloring with fewer colors by merging pairs of color classes. The achromatic number Template:Math of a graph Template:Mvar is the maximum number of colors possible in any complete coloring of Template:Mvar.

A complete coloring is the opposite of a harmonious coloring, which requires every pair of colors to appear on at most one pair of adjacent vertices.

Finding Template:Math is an optimization problem. The decision problem for complete coloring can be phrased as:

INSTANCE: a graph Template:Math and positive integer Template:Mvar

QUESTION: does there exist a partition of Template:Mvar into Template:Mvar or more disjoint sets Template:Math such that each Template:Mvar is an independent set for Template:Mvar and such that for each pair of distinct sets Template:Math is not an independent set.

Determining the achromatic number is NP-hard; determining if it is greater than a given number is NP-complete, as shown by Yannakakis and Gavril in 1978 by transformation from the minimum maximal matching problem.^[1]

Note that any coloring of a graph with the minimum number of colors must be a complete coloring, so minimizing the number of colors in a complete coloring is just a restatement of the standard graph coloring problem.

For any fixed k, it is possible to determine whether the achromatic number of a given graph is at least k, in linear time.^[2]

The optimization problem permits approximation and is approximable within a ${\displaystyle O(|V|/\sqrt{\log |V|})}$ approximation ratio.^[3]

The NP-completeness of the achromatic number problem holds also for some special classes of graphs: bipartite graphs,^[2] complements of bipartite graphs (that is, graphs having no independent set of more than two vertices),^[1] cographs and interval graphs,^[4] and even for trees.^[5]

For complements of trees, the achromatic number can be computed in polynomial time.^[6] For trees, it can be approximated to within a constant factor.^[3]

The achromatic number of an n-dimensional hypercube graph is known to be proportional to ${\displaystyle \sqrt{n{2}^n}}$, but the constant of proportionality is not known precisely.^[7]

Template:Reflist

• A compendium of NP optimization problems
• A Bibliography of Harmonious Colourings and Achromatic Number by Keith Edwards