McGee graph
McGee graph | |
---|---|
Named after | W. F. McGee |
Vertices | 24 |
Edges | 36 |
Radius | 4 |
Diameter | 4[1] |
Girth | 7[1] |
Automorphisms | 32[1] |
Chromatic number | 3[1] |
Chromatic index | 3[1] |
Properties | Cubic Cage Hamiltonian |
Table of graphs and parameters |
In the mathematical field of graph theory, the McGee graph or the (3-7)-cage is a 3-regular graph with 24 vertices and 36 edges.[1]
The McGee graph is the unique (3,7)-cage (the smallest cubic graph of girth 7). It is also the smallest cubic cage that is not a Moore graph.
First discovered by Sachs but unpublished,[2] the graph is named after McGee who published the result in 1960.[3] Then, the McGee graph was proven the unique (3,7)-cage by Tutte in 1966.[4][5][6]
The McGee graph requires at least eight crossings in any drawing of it in the plane. It is one of five non-isomorphic graphs tied for being the smallest cubic graph that requires eight crossings. Another of these five graphs is the generalized Petersen graph G(12,5), also known as the Nauru graph.[7][8]
The McGee graph has radius 4, diameter 4, chromatic number 3 and chromatic index 3. It is also a 3-vertex-connected and a 3-edge-connected graph.
Algebraic properties
The characteristic polynomial of the McGee graph is : .
The automorphism group of the McGee graph is of order 32 and doesn't act transitively upon its vertices: there are two vertex orbits, of lengths 8 and 16. The McGee graph is the smallest cubic cage that is not a vertex-transitive graph.[9]
Gallery
-
The crossing number of the McGee graph is 8.
-
The chromatic number of the McGee graph is 3.
-
The chromatic index of the McGee graph is 3.
-
The acyclic chromatic number of the McGee graph is 3.
-
Alternative drawing of the McGee graph.
References
- ^ a b c d e f Weisstein, Eric W. "McGee Graph". MathWorld.
- ^ Kárteszi, F. "Piani finit ciclici come risoluzioni di un certo problemo di minimo." Boll. Un. Mat. Ital. 15, 522-528, 1960
- ^ McGee, W. F. "A Minimal Cubic Graph of Girth Seven." Canad. Math. Bull. 3, 149-152, 1960
- ^ Tutte, W. T. Connectivity in Graphs. Toronto, Ontario: University of Toronto Press, 1966
- ^ Wong, P. K. "Cages--A Survey." J. Graph Th. 6, 1-22, 1982
- ^ Brouwer, A. E.; Cohen, A. M.; and Neumaier, A. Distance Regular Graphs. New York: Springer-Verlag, p. 209, 1989
- ^ (sequence A110507 in the OEIS).
- ^ Pegg, E. T.; Exoo, G. (2009), "Crossing number graphs", Mathematica Journal, 11.
- ^ Bondy, J. A. and Murty, U. S. R. Graph Theory with Applications. New York: North Holland, p. 237, 1976.