Shannon multigraph

In the mathematical discipline of graph theory, Shannon multigraphs, named after Claude Shannon by Vizing (1965),^[1] are a special type of triangle graphs, which are used in the field of edge coloring in particular.

A Shannon multigraph is multigraph with 3 vertices for which either of the following conditions holds:

a) all 3 vertices are connected by the same number of edges.
b) as in a) and one additional edge is added.

More precisely one speaks of Shannon multigraph $Sh(n)$ , if the three vertices are connected by $\left\lfloor {\frac {n}{2}}\right\rfloor$ , $\left\lfloor {\frac {n}{2}}\right\rfloor$ and $\left\lfloor {\frac {n+1}{2}}\right\rfloor$ edges respectively. This multigraph has maximum degree $n$ . Its multiplicity (the maximum number of edges in a set of edges that all have the same endpoints) is $\left\lfloor {\frac {n+1}{2}}\right\rfloor$ .^[2]^[3]

Examples

Shannon multigraphs
Sh(2)
Sh(3)
Sh(4)
Sh(5)
Sh(6)
Sh(7)

Edge coloring

According to a theorem of Shannon (1949), every multigraph with maximum degree $\Delta$ has an edge coloring that uses at most ${\frac {3}{2}}\Delta$ colors.^[4] When $\Delta$ is even, the example of the Shannon multigraph with multiplicity $\Delta /2$ shows that this bound is tight: the vertex degree is exactly $\Delta$ , but each of the ${\frac {3}{2}}\Delta$ edges is adjacent to every other edge, so it requires ${\frac {3}{2}}\Delta$ colors in any proper edge coloring.^[3]

A version of Vizing's theorem states that every multigraph with maximum degree $\Delta$ and multiplicity $\mu$ may be colored using at most $\Delta +\mu$ colors.^[5] Again, this bound is tight for the Shannon multigraphs.^[3]

References

^ Vizing, V. G. (1965), "The chromatic class of a multigraph", Kibernetika, 1965 (3): 29–39, MR 0189915
^ Fiorini, S.; Wilson, Robin James (1977), Edge-colourings of graphs, Research Notes in Mathematics, vol. 16, London: Pitman, p. 34, ISBN 0-273-01129-4, MR 0543798
^ ^a ^b ^c Volkmann, Lutz (1996), Fundamente der Graphentheorie (in German), Wien: Springer, p. 289, ISBN 3-211-82774-9
^ Shannon, Claude E. (1949), "A theorem on coloring the lines of a network", J. Math. Physics, 28: 148–151, doi:10.1002/sapm1949281148, hdl:10338.dmlcz/101098, MR 0030203
^ Vizing, V. G. (1964), "On an estimate of the chromatic class of a p-graph", Diskret. Analiz., 3: 25–30, MR 0180505

External links

Lutz Volkmann: Graphen an allen Ecken und Kanten. Lecture notes 2006, p. 244 (German)

[v65-1] Vizing, V. G. (1965), "The chromatic class of a multigraph", Kibernetika, 1965 (3): 29–39, MR 0189915

[fw77-2] Fiorini, S.; Wilson, Robin James (1977), Edge-colourings of graphs, Research Notes in Mathematics, vol. 16, London: Pitman, p. 34, ISBN 0-273-01129-4, MR 0543798

[v96-3] Volkmann, Lutz (1996), Fundamente der Graphentheorie (in German), Wien: Springer, p. 289, ISBN 3-211-82774-9

[s49-4] Shannon, Claude E. (1949), "A theorem on coloring the lines of a network", J. Math. Physics, 28: 148–151, doi:10.1002/sapm1949281148, hdl:10338.dmlcz/101098, MR 0030203

[v64-5] Vizing, V. G. (1964), "On an estimate of the chromatic class of a p-graph", Diskret. Analiz., 3: 25–30, MR 0180505

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