A viewpoint to the minimum coloring problem of hypergraphs

U. J. Nieminen

Displaying similar documents to “A viewpoint to the minimum coloring problem of hypergraphs”

A Note on Neighbor Expanded Sum Distinguishing Index

Evelyne Flandrin, Hao Li, Antoni Marczyk, Jean-François Saclé, Mariusz Woźniak (2017)

Discussiones Mathematicae Graph Theory

Similarity:

A total k-coloring of a graph G is a coloring of vertices and edges of G using colors of the set [k] = {1, . . . , k}. These colors can be used to distinguish the vertices of G. There are many possibilities of such a distinction. In this paper, we consider the sum of colors on incident edges and adjacent vertices.

On the Vertex Folkman Numbers Fv(2,...,2;q)

Nenov, Nedyalko (2009)

Serdica Mathematical Journal

Similarity:

2000 Mathematics Subject Classification: 05C55. In this paper we shall compute the Folkman numbers ... We prove also new bounds for some vertex and edge Folkman numbers.

Worm Colorings

Wayne Goddard, Kirsti Wash, Honghai Xu (2015)

Discussiones Mathematicae Graph Theory

Similarity:

Given a coloring of the vertices, we say subgraph H is monochromatic if every vertex of H is assigned the same color, and rainbow if no pair of vertices of H are assigned the same color. Given a graph G and a graph F, we define an F-WORM coloring of G as a coloring of the vertices of G without a rainbow or monochromatic subgraph H isomorphic to F. We present some results on this concept especially as regards to the existence, complexity, and optimization within certain graph classes....

The list Distinguishing Number Equals the Distinguishing Number for Interval Graphs

Poppy Immel, Paul S. Wenger (2017)

Discussiones Mathematicae Graph Theory

Similarity:

A distinguishing coloring of a graph G is a coloring of the vertices so that every nontrivial automorphism of G maps some vertex to a vertex with a different color. The distinguishing number of G is the minimum k such that G has a distinguishing coloring where each vertex is assigned a color from {1, . . . , k}. A list assignment to G is an assignment L = {L(v)}v∈V (G) of lists of colors to the vertices of G. A distinguishing L-coloring of G is a distinguishing coloring of G where the...

Vertex-distinguishing edge-colorings of linear forests

Sylwia Cichacz, Jakub Przybyło (2010)

Discussiones Mathematicae Graph Theory

Similarity:

In the PhD thesis by Burris (Memphis (1993)), a conjecture was made concerning the number of colors c(G) required to edge-color a simple graph G so that no two distinct vertices are incident to the same multiset of colors. We find the exact value of c(G) - the irregular coloring number, and hence verify the conjecture when G is a vertex-disjoint union of paths. We also investigate the point-distinguishing chromatic index, χ₀(G), where sets, instead of multisets, are required to be distinct,...

Vertex-Distinguishing IE-Total Colorings of Complete Bipartite Graphs Km,N(m < n)

Xiang’en Chen, Yuping Gao, Bing Yao (2013)

Discussiones Mathematicae Graph Theory

Similarity:

Let G be a simple graph. An IE-total coloring f of G is a coloring of the vertices and edges of G so that no two adjacent vertices receive the same color. Let C(u) be the set of colors of vertex u and edges incident to u under f. For an IE-total coloring f of G using k colors, if C(u) 6= C(v) for any two different vertices u and v of G, then f is called a k-vertex-distinguishing IE-total-coloring of G, or a k-VDIET coloring of G for short. The minimum number of colors required for a...

An improvement to Mathon's cyclotomic Ramsey colorings.

Xu, Xiaodong, Radziszowski, Stanislaw P. (2009)

The Electronic Journal of Combinatorics [electronic only]

Similarity:

The Ramsey number of diamond-matchings and loose cycles in hypergraphs.

Gyárfás, András, Sárközy, Gábor N., Szemerédi, Endre (2008)

The Electronic Journal of Combinatorics [electronic only]

Similarity:

A Tight Bound on the Set Chromatic Number

Jean-Sébastien Sereni, Zelealem B. Yilma (2013)

Discussiones Mathematicae Graph Theory

Similarity:

We provide a tight bound on the set chromatic number of a graph in terms of its chromatic number. Namely, for all graphs G, we show that χs(G) > ⌈log2 χ(G)⌉ + 1, where χs(G) and χ(G) are the set chromatic number and the chromatic number of G, respectively. This answers in the affirmative a conjecture of Gera, Okamoto, Rasmussen and Zhang.

On swell-colored complete graphs.

Ward, C., Szabó, S. (1994)

Acta Mathematica Universitatis Comenianae. New Series

Similarity:

A note on graph coloring extensions and list-colorings.

Axenovich, Maria (2003)

The Electronic Journal of Combinatorics [electronic only]

Similarity:

The set chromatic number of a graph

Gary Chartrand, Futaba Okamoto, Craig W. Rasmussen, Ping Zhang (2009)

Discussiones Mathematicae Graph Theory

Similarity:

For a nontrivial connected graph G, let c: V(G)→ N be a vertex coloring of G where adjacent vertices may be colored the same. For a vertex v of G, the neighborhood color set NC(v) is the set of colors of the neighbors of v. The coloring c is called a set coloring if NC(u) ≠ NC(v) for every pair u,v of adjacent vertices of G. The minimum number of colors required of such a coloring is called the set chromatic number χₛ(G) of G. The set chromatic numbers of some well-known classes of graphs...

Rainbow $H$ -factors.

Yuster, Raphael (2006)

The Electronic Journal of Combinatorics [electronic only]

Similarity: