Expansive: Difference between revisions

Latest revision as of 23:38, 22 May 2013

The Symmetric hypergraph theorem is a theorem in combinatorics that puts an upper bound on the chromatic number of a graph (or hypergraph in general). The original reference for this paper is unknown at the moment, and has been called folklore.^[1]

Statement

A group $G$ acting on a set $S$ is called transitive if given any two elements $x$ and $y$ in $S$ , there exists an element $f$ of $G$ such that $f(x)=y$ . A graph (or hypergraph) is called symmetric if it's automorphism group is transitive.

Theorem. Let $H=(S,E)$ be a symmetric hypergraph. Let $m=|S|$ , and let $\chi (H)$ denote the chromatic number of $H$ , and let $\alpha (H)$ denote the independence number of $H$ . Then

\chi (H)<1+{\frac {m}{\alpha (H)}}\ln m.

Applications

This theorem has applications to Ramsey theory, specifically graph Ramsey theory. Using this theorem, a relationship between the graph Ramsey numbers and the extremal numbers can be shown (see Graham-Rothschild-Spencer for the details).

Notes

↑ R. Graham, B. Rothschild, J. Spencer. Ramsey Theory. 2nd ed., Wiley, New-York, 1990.

[1] R. Graham, B. Rothschild, J. Spencer. Ramsey Theory. 2nd ed., Wiley, New-York, 1990.

[1]

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+The '''Symmetric hypergraph theorem''' is a theorem in [[combinatorics]] that puts an upper bound on the [[Graph coloring#Chromatic number|chromatic number]] of a [[Graph (mathematics)|graph]] (or [[hypergraph]] in general).  The original reference for this paper is unknown at the moment, and has been called folklore.<ref>R. Graham, B. Rothschild, J. Spencer. Ramsey Theory. 2nd ed., Wiley, New-York, 1990.</ref>
+==Statement==
+A [[Group (mathematics)|group]] <math>G</math> [[group action|acting on a set]] <math>S</math> is called ''[[Group action#Types of actions|transitive]]'' if given any two elements <math>x</math> and <math>y</math> in <math>S</math>, there exists an element <math>f</math> of <math>G</math> such that <math>f(x) = y</math>.  A graph (or hypergraph) is called ''symmetric'' if it's [[automorphism group]] is transitive.
+'''Theorem.'''  Let <math>H = (S, E)</math> be a symmetric hypergraph.  Let <math>m = |S|</math>, and let <math>\chi(H)</math> denote the chromatic number of <math>H</math>, and let <math>\alpha(H)</math> denote the [[Glossary of graph theory#Independence|independence number]] of <math>H</math>.  Then
+<center><math>\chi(H) < 1 + \frac{m}{\alpha(H)}\ln m.</math></center>
+==Applications==
+This theorem has applications to [[Ramsey theory]], specifically [[graph Ramsey theory]].  Using this theorem, a relationship between the graph Ramsey numbers and the extremal numbers can be shown (see Graham-Rothschild-Spencer for the details).
+==See also==
+* [[Ramsey theory]]
+==Notes==
+<references/>
+[[Category:Graph coloring]]
+[[Category:Theorems in graph theory]]

Expansive: Difference between revisions

Latest revision as of 23:38, 22 May 2013

Contents

Statement

Applications

See also

Notes

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Expansive: Difference between revisions

Latest revision as of 23:38, 22 May 2013

Statement

Applications

See also

Notes

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