On the Dichromatic Number of Surfaces

The dichromatic number $\overrightarrow{\chi}(D)$ of a digraph $D$ is the minimum number of colors needed to color the vertices of $D$ such that each color class induces an acyclic subdigraph of $D$. A digraph $D$ is $k$-critical if $\overrightarrow{\chi}(D) = k$ but $\overrightarrow{\chi}(D') < k$ for all proper subdigraphs $D'$ of $D$. We examine methods for creating infinite families of critical digraphs, the Dirac join and the directed and bidirected Hajós join. We prove that a digraph $D$ has dichromatic number at least $k$ if and only if it contains a subdigraph that can be obtained from bidirected complete graphs on $k$ vertices by directed Hajós joins and identifying non-adjacent vertices. Building upon that, we show that a digraph $D$ has dichromatic number at least $k$ if and only if it can be constructed from bidirected $K_k$'s by using directed and bidirected Hajós joins and identifying non-adjacent vertices (so called Ore joins), thereby transferring a well-known result of Urquhart to digraphs. Finally, we prove a Gallai-type theorem that characterizes the structure of the low vertex subdigraph of a critical digraph, that is, the subdigraph, which is induced by the vertices that have in-degree $k-1$ and out-degree $k-1$ in $D$.

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Extension of Gyárfás-Sumner Conjecture to Digraphs

The Electronic Journal of Combinatorics ◽

10.37236/9906 ◽

2021 ◽

Vol 28 (2) ◽

Author(s):

Pierre Aboulker ◽

Pierre Charbit ◽

Reza Naserasr

Keyword(s):

Chromatic Number ◽

Directed Path ◽

Complete Multipartite Graph ◽

Color Class ◽

Acyclic Digraph ◽

Minimum Number ◽

Multipartite Graph ◽

Complete Multipartite ◽

Dichromatic Number

The dichromatic number of a digraph $D$ is the minimum number of colors needed to color its vertices in such a way that each color class induces an acyclic digraph. As it generalizes the notion of the chromatic number of graphs, it has become the focus of numerous works. In this work we look at possible extensions of the Gyárfás-Sumner conjecture. In particular, we conjecture a simple characterization of sets $\mathcal F$ of three digraphs such that every digraph with sufficiently large dichromatic number must contain a member of $\mathcal F$ as an induced subdigraph. Among notable results, we prove that oriented $K_4$-free graphs without a directed path of length $3$ have bounded dichromatic number where a bound of $414$ is provided. We also show that an orientation of a complete multipartite graph with no directed triangle is $2$-colorable. To prove these results we introduce the notion of nice sets that might be of independent interest.

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Majority Colorings of Sparse Digraphs

The Electronic Journal of Combinatorics ◽

10.37236/10067 ◽

2021 ◽

Vol 28 (2) ◽

Author(s):

Michael Anastos ◽

Ander Lamaison ◽

Raphael Steiner ◽

Tibor Szabó

Keyword(s):

Chromatic Number ◽

Directed Graph ◽

Exponential Function ◽

Alternative Methods ◽

Vertex Coloring ◽

Local Lemma ◽

List Colorings ◽

Dichromatic Number

A majority coloring of a directed graph is a vertex-coloring in which every vertex has the same color as at most half of its out-neighbors. Kreutzer, Oum, Seymour, van der Zypen and Wood proved that every digraph has a majority $4$-coloring and conjectured that every digraph admits a majority $3$-coloring. They observed that the Local Lemma implies the conjecture for digraphs of large enough minimum out-degree if, crucially, the maximum in-degree is bounded by a(n exponential) function of the minimum out-degree. Our goal in this paper is to develop alternative methods that allow the verification of the conjecture for natural, broad digraph classes, without any restriction on the in-degrees. Among others, we prove the conjecture 1) for digraphs with chromatic number at most $6$ or dichromatic number at most $3$, and thus for all planar digraphs; and 2) for digraphs with maximum out-degree at most $4$. The benchmark case of $r$-regular digraphs remains open for $r \in [5,143]$. Our inductive proofs depend on loaded inductive statements about precoloring extensions of list-colorings. This approach also gives rise to stronger conclusions, involving the choosability version of majority coloring. We also give further evidence towards the existence of majority-$3$-colorings by showing that every digraph has a fractional majority 3.9602-coloring. Moreover we show that every digraph with large enough minimum out-degree has a fractional majority $(2+\varepsilon)$-coloring.

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DICHROMATIC NUMBER AND FRACTIONAL CHROMATIC NUMBER

Forum of Mathematics Sigma ◽

10.1017/fms.2016.28 ◽

2016 ◽

Vol 4 ◽

Author(s):

BOJAN MOHAR ◽

HEHUI WU

Keyword(s):

Chromatic Number ◽

Constant Factor ◽

Independent Interest ◽

Directed Cycle ◽

Significant Progress ◽

Fractional Chromatic Number ◽

Small Constant ◽

Dichromatic Number

The dichromatic number of a graph $G$ is the maximum integer $k$ such that there exists an orientation of the edges of $G$ such that for every partition of the vertices into fewer than $k$ parts, at least one of the parts must contain a directed cycle under this orientation. In 1979, Erdős and Neumann-Lara conjectured that if the dichromatic number of a graph is bounded, so is its chromatic number. We make the first significant progress on this conjecture by proving a fractional version of the conjecture. While our result uses a stronger assumption about the fractional chromatic number, it also gives a much stronger conclusion: if the fractional chromatic number of a graph is at least $t$, then the fractional version of the dichromatic number of the graph is at least ${\textstyle \frac{1}{4}}t/\log _{2}(2et^{2})$. This bound is best possible up to a small constant factor. Several related results of independent interest are given.

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Cycle reversions and dichromatic number in tournaments

European Journal of Combinatorics ◽

10.1016/j.ejc.2018.10.008 ◽

2019 ◽

Vol 77 ◽

pp. 31-48

Author(s):

Paul Ellis ◽

Dániel T. Soukup

Keyword(s):

Dichromatic Number

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