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On Dirac's Generalization of Brooks' Theorem

Published online by Cambridge University Press:  20 November 2018

Hudson V. Kronk
Affiliation:
State University of New York at Binghaniton, Binghamton, New York
John Mitchem
Affiliation:
San Jose State College, San Jose, California
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It is easy to verify that any connected graph G with maximum degree s has chromatic number χ(G) ≦ 1 + s. In [1], R. L. Brooks proved that χ(G) ≦ s, unless s = 2 and G is an odd cycle or s > 2 and G is the complete graph Ks+1. This was the first significant theorem connecting the structure of a graph with its chromatic number. For s ≦ 4, Brooks' theorem says that every connected s-chromatic graph other than Ks contains a vertex of degree > s — 1. An equivalent formulation can be given in terms of s-critical graphs. A graph G is said to be s-critical if χ(G) = s, but every proper subgraph has chromatic number less than s. Each scritical graph has minimum degree ≦ s — 1. We can now restate Brooks' theorem: if an s-critical graph, s ≦ 4, is not Ks and has p vertices and q edges, then 2q ≦ (s — l)p + 1. Dirac [2] significantly generalized the theorem of Brooks by showing that 2q ≦ (s — 1)£ + s — 3 and that this result is best possible.

Type
Research Article
Copyright
Copyright © Canadian Mathematical Society 1972

References

1. Brooks, R. L., On coloring the nodes of a network, Proc. Cambridge Philos. Soc. 37 (1941), 194197.Google Scholar
2. Dirac, G. A., A theorem of R. L. Brooks and a conjecture of H. Hadwiger, Proc. London Math. Soc. 7 (1957), 161195.Google Scholar
3. Dirac, G. A., Short proof of a map-colour theorem, Can. J. Math. 9 (1957), 225226.Google Scholar
4. Melnikov, L. S. and Vizing, V. G., New proof of Brooks’ theorem, J. Combinatorial Theory 7 (1969), 289290.Google Scholar