On k-11-representable graphs
Abstract
Distinct letters and alternate in a word if after deleting in all letters but the copies of and we either obtain a word of the form (of even or odd length) or a word of the form (of even or odd length). A simple graph is word-representable if there exists a word over the alphabet such that letters and alternate in if and only if is an edge in . Thus, edges of are defined by avoiding the consecutive pattern 11 in a word representing , that is, by avoiding and . In 2017, Jeff Remmel has introduced the notion of a --representable graph for a non-negative integer , which generalizes the notion of a word-representable graph. Under this representation, edges of are defined by containing at most occurrences of the consecutive pattern in a word representing . Thus, word-representable graphs are precisely --representable graphs. Our key result in this paper is showing that any graph is --representable by a concatenation of permutations, which is rather surprising taking into account that concatenation of permutations has limited power in the case of --representation. Also, we show that the class of word-representable graphs, studied intensively in the literature, is contained strictly in the class of --representable graphs. Another result that we prove is the fact that the class of interval graphs is precisely the class of --representable graphs that can be represented by uniform words containing two copies of each letter. This result can be compared with the known fact that the class of circle graphs is precisely the class of --representable graphs that can be represented by uniform words containing two copies of each letter.
Cite
@article{arxiv.1803.01055,
title = {On k-11-representable graphs},
author = {Gi-Sang Cheon and Jinha Kim and Minki Kim and Sergey Kitaev and Artem Pyatkin},
journal= {arXiv preprint arXiv:1803.01055},
year = {2018}
}
Comments
A key result on 2-11-representability of any graph was added