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Upper chromatic number of finite projective planes

✍ Scribed by Gábor Bacsó; Zsolt Tuza

Publisher: John Wiley and Sons
Year: 2008
Tongue: English
Weight: 135 KB
Volume: 16
Category: Article
ISSN: 1063-8539
DOI: 10.1002/jcd.20169

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✦ Synopsis

Abstract

For a finite projective plane $\Pi$, let $\bar {\chi} (\Pi)$ denote the maximum number of classes in a partition of the point set, such that each line has at least two points in the same partition class. We prove that the best possible general estimate in terms of the order of projective planes is $q^2-q-\Theta(\sqrt q)$, which is tight apart from a multiplicative constant in the third term ${\sqrt q}$:

As $q\to\infty, \bar {\chi}({\Pi}) \leq q^2-q-\sqrt q/2 +o(\sqrt q)$ holds for every projective plane $\Pi$ of order q.

If q is a square, then the Galois plane of order q satisfies $\bar{\chi}(PG(2,q))\geq q^2-q-2\sqrt q $.

Our results asymptotically solve a ten‐year‐old open problem in the coloring theory of mixed hypergraphs, where $\bar {\chi}(\Pi)$ is termed the upper chromatic number of $\Pi$. Further improvements on the upper bound (1) are presented for Galois planes and their subclasses. © 2007 Wiley Periodicals, Inc. J Combin Designs 16: 221–230, 2008

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