Generalising the achromatic number to Zaslavsky's colourings of signed graphs

TL;DR

This paper extends the concept of the achromatic number to Zaslavsky's signed graph colourings, analyzing its properties, bounds, and computational complexity within this new framework.

Contribution

It introduces a novel generalisation of the achromatic number for signed graphs based on Zaslavsky's colourings and investigates its fundamental properties and computational aspects.

Findings

Established bounds for the signed achromatic number

Analyzed behaviour under standard graph operations

Explored complexity of computing the signed achromatic number

Abstract

The chromatic number, which refers to the minimum number of colours required to colour the vertices of graphs properly, is one of the most central notions of the graph chromatic theory. Several of its aspects of interest have been investigated in the literature, including variants for modifications of proper colourings. These variants include, notably, the achromatic number of graphs, which is the maximum number of colours required to colour the vertices of graphs properly so that each possible combination of distinct colours is assigned along some edge. The behaviours of this parameter have led to many investigations of interest, bringing to light both similarities and discrepancies with the chromatic number. This work takes place in a recent trend aiming at extending the chromatic theory of graphs to the realm of signed graphs, and, in particular, at investigating how classic results adapt to the signed context. Most of the works done in that line to date are with respect to two main generalisations of proper colourings of signed graphs, attributed to Zaslavsky and Guenin. Generalising the achromatic number to signed graphs was initiated recently by Lajou, his investigations being related to Guenin's colourings. We here pursue this line of research, but with taking Zaslavsky's colourings as our notion of proper colourings. We study the general behaviour of our resulting variant of the achromatic number, mainly by investigating how known results on the classic achromatic number generalise to our context. Our results cover, notably, bounds, standard operations on graphs, and complexity aspects.