Holt graph

Holt graph
	In the Holt graph, all vertices are equivalent, and all edges are equivalent, but edges are not equivalent to their inverses.
Named after	Derek F. Holt
Vertices	27
Edges	54
Radius	3
Diameter	3
Girth	5
Automorphisms	54
Chromatic number	3
Chromatic index	5
Book thickness	3
Queue number	3
Properties	Vertex-transitive; Edge-transitive; Half-transitive; Hamiltonian; Eulerian; Cayley graph
	Table of graphs and parameters

In the mathematical field of graph theory, the Holt graph or Doyle graph is the smallest half-transitive graph, that is, the smallest example of a vertex-transitive and edge-transitive graph which is not also symmetric.[1][2] Such graphs are not common.[3] It is named after Peter G. Doyle and Derek F. Holt, who discovered the same graph independently in 1976[4] and 1981[5] respectively.

The Holt Graph has diameter 3, radius 3 and girth 5, chromatic number 3, chromatic index 5 and is Hamiltonian with 98,472 distinct Hamiltonian cycles.[6] It is also a 4-vertex-connected and a 4-edge-connected graph. It has book thickness 3 and queue number 3.[7]

It has an automorphism group of order 54 automorphisms.[6] This is a smaller group than a symmetric graph with the same number of vertices and edges would have. The graph drawing on the right highlights this, in that it lacks reflectional symmetry.

The characteristic polynomial of the Holt graph is

(x^{3}-6x+2)^{6}(x+2)^{4}(x-1)^{4}(x-4).\

Gallery

The chromatic number of the Holt graph is 3.
The chromatic index of the Holt graph is 5.
The Holt graph is Hamiltonian.

References

Doyle, P. "A 27-Vertex Graph That Is Vertex-Transitive and Edge-Transitive But Not L-Transitive." October 1998.
Alspach, Brian; Marušič, Dragan; Nowitz, Lewis (1994), "Constructing Graphs which are ½-Transitive", Journal of the Australian Mathematical Society Series A, 56 (3): 391–402, doi:10.1017/S1446788700035564, archived from the original on 2003-11-27.
Jonathan L. Gross, Jay Yellen, Handbook of Graph Theory, CRC Press, 2004, ISBN 1-58488-090-2, p. 491.
Doyle, P. G. (1976), On Transitive Graphs, Senior Thesis, Harvard College. As cited by MathWorld.
Holt, Derek F. (1981), "A graph which is edge transitive but not arc transitive", Journal of Graph Theory, 5 (2): 201–204, doi:10.1002/jgt.3190050210.
Weisstein, Eric W. "Doyle Graph". MathWorld.
Jessica Wolz, Engineering Linear Layouts with SAT. Master Thesis, University of Tübingen, 2018

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[1] Doyle, P. "A 27-Vertex Graph That Is Vertex-Transitive and Edge-Transitive But Not L-Transitive." October 1998.

[2] Alspach, Brian; Marušič, Dragan; Nowitz, Lewis (1994), "Constructing Graphs which are ½-Transitive", Journal of the Australian Mathematical Society Series A, 56 (3): 391–402, doi:10.1017/S1446788700035564, archived from the original on 2003-11-27.

[3] Jonathan L. Gross, Jay Yellen, Handbook of Graph Theory, CRC Press, 2004, ISBN 1-58488-090-2, p. 491.

[4] Doyle, P. G. (1976), On Transitive Graphs, Senior Thesis, Harvard College. As cited by MathWorld.

[holt-5] Holt, Derek F. (1981), "A graph which is edge transitive but not arc transitive", Journal of Graph Theory, 5 (2): 201–204, doi:10.1002/jgt.3190050210.

[Mathworld-6] Weisstein, Eric W. "Doyle Graph". MathWorld.

[7] Jessica Wolz, Engineering Linear Layouts with SAT. Master Thesis, University of Tübingen, 2018