Abstract
An automorphism of a graph is a mapping of the vertices onto themselves such that connections between respective edges are preserved. A vertex v in a graph G is fixed if it is mapped to itself under every automorphism of G. The fixing number of a graph G is the minimum number of vertices, when fixed, fixes all of the vertices in G. The determination of fixing numbers is important as it can be useful in determining the group of automorphisms of a graph-a famous and difficult problem. Fixing numbers were introduced and initially studied by Gibbons and Laison, Erwin and Harary and Boutin. In this paper, we investigate fixing numbers for graphs with an underlying cyclic structure, which provides an inherent presence of symmetry. We first determine fixing numbers for circulant graphs, showing in many cases the fixing number is 2. However, we also show that circulant graphs with twins, which are pairs of vertices with the same neighbourhoods, have considerably higher fixing numbers. This is the first paper that investigates fixing numbers of point-block incidence graphs, which lie at the intersection of graph theory and combinatorial design theory. We also present a surprising result-identifying infinite families of graphs in which fixing any vertex fixes every vertex, thus removing all symmetries from the graph.
Highlights
If you look closely at a QR-code you will see that three of the corners are marked with small nested squares
We investigate circulant graphs and point-block incidence graphs which arise from combinatorial designs
We present a connection between circulant graphs and point-block incidence graphs
Summary
If you look closely at a QR-code you will see that three of the corners are marked with small nested squares. We consider the problem of removing symmetry from a graph by fixing vertices. This leads us to an investigation of fixing numbers of circulant graphs. This includes presentation of infinite families of graphs where fixing any vertex fixes every vertex, removing all symmetries from the graph. For the third case we note the graph has only one non-trivial automorphism, where vi is swapped with vn−i+1 for all 1 ≤ i ≤. When n is even we can fix any vertex and remove this automorphism, when n is odd we can fix any vertex other than the centre vertex and remove this automorphism
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