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Mean value for the matching and dominating polynomial

100%
Arocha J., Llano B.
Discussiones Mathematicae Graph Theory
|
2000
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tom 20
|
nr 1
57-69
EN
The mean value of the matching polynomial is computed in the family of all labeled graphs with n vertices. We introduce the dominating polynomial of a graph whose coefficients enumerate the dominating sets for a graph and study some properties of the polynomial. The mean value of this polynomial is determined in a certain special family of bipartite digraphs.
2
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The Dichromatic Number of Infinite Families of Circulant Tournaments

100%
Javier N., Llano B.
Discussiones Mathematicae Graph Theory
|
2017
|
tom 37
|
nr 1
221-238
EN
The dichromatic number dc(D) of a digraph D is defined to be the minimum number of colors such that the vertices of D can be colored in such a way that every chromatic class induces an acyclic subdigraph in D. The cyclic circulant tournament is denoted by [...] T=C→2n+1(1,2,…,n) $T = \overrightarrow C _{2n + 1} (1,2, \ldots ,n)$ , where V (T) = ℤ2n+1 and for every jump j ∈ {1, 2, . . . , n} there exist the arcs (a, a + j) for every a ∈ ℤ2n+1. Consider the circulant tournament [...] C→2n+1〈k〉 $\overrightarrow C _{2n + 1} \left\langle k \right\rangle $ obtained from the cyclic tournament by reversing one of its jumps, that is, [...] C→2n+1 〈k〉 $\overrightarrow C _{2n + 1} \left\langle k \right\rangle $ has the same arc set as [...] C→2n+1(1,2,…,n) $\overrightarrow C _{2n + 1} (1,2, \ldots ,n)$ except for j = k in which case, the arcs are (a, a − k) for every a ∈ ℤ2n+1. In this paper, we prove that [...] dc(C→2n+1 〈k〉)∈{2,3,4} $dc ( {\overrightarrow C _{2n + 1} \left\langle k \right\rangle } ) \in \{ 2,3,4\}$ for every k ∈ {1, 2, . . . , n}. Moreover, we classify which circulant tournaments [...] C→2n+1 〈k〉 $\overrightarrow C _{2n + 1} \left\langle k \right\rangle$ are vertex-critical r-dichromatic for every k ∈ {1, 2, . . . , n} and r ∈ {2, 3, 4}. Some previous results by Neumann-Lara are generalized.
3
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Infinite families of tight regular tournaments

100%
Llano B., Olsen M.
Discussiones Mathematicae Graph Theory
|
2007
|
tom 27
|
nr 2
299-311
EN
In this paper, we construct infinite families of tight regular tournaments. In particular, we prove that two classes of regular tournaments, tame molds and ample tournaments are tight. We exhibit an infinite family of 3-dichromatic tight tournaments. With this family we positively answer to one case of a conjecture posed by V. Neumann-Lara. Finally, we show that any tournament with a tight mold is also tight.
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