Rotational circulant graphs
Abstract
A Frobenius group is a transitive permutation group which is not regular but only the identity element can fix two points. Such a group can be expressed as the semi-direct product of a nilpotent normal subgroup and another group fixing a point. A first-kind -Frobenius graph is a connected Cayley graph on with connection set an -orbit on that generates , where has an even order or is an involution. It is known that the first-kind Frobenius graphs admit attractive routing and gossiping algorithms. A complete rotation in a Cayley graph on a group with connection set is an automorphism of fixing setwise and permuting the elements of cyclically. It is known that if the fixed-point set of such a complete rotation is an independent set and not a vertex-cut, then the gossiping time of the Cayley graph (under a certain model) attains the smallest possible value. In this paper we classify all first-kind Frobenius circulant graphs that admit complete rotations, and describe a means to construct them. This result can be stated as a necessary and sufficient condition for a first-kind Frobenius circulant to be 2-cell embeddable on a closed orientable surface as a balanced regular Cayley map. We construct a family of non-Frobenius circulants admitting complete rotations such that the corresponding fixed-point sets are independent and not vertex-cuts. We also give an infinite family of counterexamples to the conjecture that the fixed-point set of every complete rotation of a Cayley graph is not a vertex-cut.
Cite
@article{arxiv.1302.6652,
title = {Rotational circulant graphs},
author = {Alison Thomson and Sanming Zhou},
journal= {arXiv preprint arXiv:1302.6652},
year = {2018}
}
Comments
Final version