Degrees in Oriented Hypergraphs and Ramsey p-Chromatic Number

Yair Caro; Adriana Hansberg

doi:10.37236/2576

Degrees in Oriented Hypergraphs and Ramsey p-Chromatic Number

The Electronic Journal of Combinatorics ◽

10.37236/2576 ◽

2012 ◽

Vol 19 (3) ◽

Cited By ~ 1

Author(s):

Yair Caro ◽

Adriana Hansberg

Keyword(s):

Chromatic Number ◽

Ramsey Numbers ◽

Uniform Hypergraphs ◽

Minimum Cover ◽

The Family ◽

Maximum Directed Cut

The family $D(k,m)$ of graphs having an orientation such that for every vertex $v \in V(G)$ either (outdegree) $\deg^+(v) \le k$ or (indegree) $\deg^-(v) \le m$ have been investigated recently in several papers because of the role $D(k,m)$ plays in the efforts to estimate the maximum directed cut in digraphs and the minimum cover of digraphs by directed cuts. Results concerning the chromatic number of graphs in the family $D(k,m)$ have been obtained via the notion of $d$-degeneracy of graphs. In this paper we consider a far reaching generalization of the family $D(k,m)$, in a complementary form, into the context of $r$-uniform hypergraphs, using a generalization of Hakimi's theorem to $r$-uniform hypergraphs and by showing some tight connections with the well known Ramsey numbers for hypergraphs.

On the Chromatic Thresholds of Hypergraphs

Combinatorics Probability Computing ◽

10.1017/s0963548315000061 ◽

2015 ◽

Vol 25 (2) ◽

pp. 172-212

Author(s):

JÓZSEF BALOGH ◽

JANE BUTTERFIELD ◽

PING HU ◽

JOHN LENZ ◽

DHRUV MUBAYI

Keyword(s):

Chromatic Number ◽

Minimum Degree ◽

Directed Graphs ◽

Open Problems ◽

Fibre Bundles ◽

Uniform Hypergraphs ◽

The Family ◽

Turán Number ◽

Chromatic Thresholds ◽

Extremal Set

Let $\mathcal{F}$ be a family of r-uniform hypergraphs. The chromatic threshold of $\mathcal{F}$ is the infimum of all non-negative reals c such that the subfamily of $\mathcal{F}$ comprising hypergraphs H with minimum degree at least $c \binom{| V(H) |}{r-1}$ has bounded chromatic number. This parameter has a long history for graphs (r = 2), and in this paper we begin its systematic study for hypergraphs.Łuczak and Thomassé recently proved that the chromatic threshold of the so-called near bipartite graphs is zero, and our main contribution is to generalize this result to r-uniform hypergraphs. For this class of hypergraphs, we also show that the exact Turán number is achieved uniquely by the complete (r + 1)-partite hypergraph with nearly equal part sizes. This is one of very few infinite families of non-degenerate hypergraphs whose Turán number is determined exactly. In an attempt to generalize Thomassen's result that the chromatic threshold of triangle-free graphs is 1/3, we prove bounds for the chromatic threshold of the family of 3-uniform hypergraphs not containing {abc, abd, cde}, the so-called generalized triangle.In order to prove upper bounds we introduce the concept of fibre bundles, which can be thought of as a hypergraph analogue of directed graphs. This leads to the notion of fibre bundle dimension, a structural property of fibre bundles that is based on the idea of Vapnik–Chervonenkis dimension in hypergraphs. Our lower bounds follow from explicit constructions, many of which use a hypergraph analogue of the Kneser graph. Using methods from extremal set theory, we prove that these Kneser hypergraphs have unbounded chromatic number. This generalizes a result of Szemerédi for graphs and might be of independent interest. Many open problems remain.

Minimum Clique Number, Chromatic Number, and Ramsey Numbers

The Electronic Journal of Combinatorics ◽

10.37236/2125 ◽

2012 ◽

Vol 19 (1) ◽

Cited By ~ 2

Author(s):

Gaku Liu

Keyword(s):

Chromatic Number ◽

Asymptotic Properties ◽

Inverse Function ◽

Clique Number ◽

Ramsey Number ◽

Growth Order ◽

Ramsey Numbers

Let $Q(n,c)$ denote the minimum clique number over graphs with $n$ vertices and chromatic number $c$. We investigate the asymptotics of $Q(n,c)$ when $n/c$ is held constant. We show that when $n/c$ is an integer $\alpha$, $Q(n,c)$ has the same growth order as the inverse function of the Ramsey number $R(\alpha+1,t)$ (as a function of $t$). Furthermore, we show that if certain asymptotic properties of the Ramsey numbers hold, then $Q(n,c)$ is in fact asymptotically equivalent to the aforementioned inverse function. We use this fact to deduce that $Q(n,\lceil n/3 \rceil)$ is asymptotically equivalent to the inverse function of $R(4,t)$.

Conflict-Free Colourings of Uniform Hypergraphs With Few Edges

Combinatorics Probability Computing ◽

10.1017/s0963548312000156 ◽

2012 ◽

Vol 21 (4) ◽

pp. 611-622 ◽

Cited By ~ 2

Author(s):

A. KOSTOCHKA ◽

M. KUMBHAT ◽

T. ŁUCZAK

Keyword(s):

Chromatic Number ◽

Upper Bound ◽

Upper Bounds ◽

Uniform Hypergraph ◽

Lower And Upper Bounds ◽

Uniform Hypergraphs ◽

Minimum Number

A colouring of the vertices of a hypergraph is called conflict-free if each edge e of contains a vertex whose colour does not repeat in e. The smallest number of colours required for such a colouring is called the conflict-free chromatic number of , and is denoted by χCF(). Pach and Tardos proved that for an (2r − 1)-uniform hypergraph with m edges, χCF() is at most of the order of rm1/r log m, for fixed r and large m. They also raised the question whether a similar upper bound holds for r-uniform hypergraphs. In this paper we show that this is not necessarily the case. Furthermore, we provide lower and upper bounds on the minimum number of edges of an r-uniform simple hypergraph that is not conflict-free k-colourable.

HYPERGRAPH RAMSEY NUMBERS AND ADIABATIC QUANTUM ALGORITHM

International Journal of Quantum Information ◽

10.1142/s0219749912500670 ◽

2012 ◽

Vol 10 (06) ◽

pp. 1250067 ◽

Cited By ~ 1

Author(s):

RI QU ◽

SU-LI ZHAO ◽

YAN-RU BAO ◽

XIAO-CHUN CAO

Keyword(s):

Combinatorial Optimization ◽

Optimization Problem ◽

Quantum Algorithm ◽

Combinatorial Optimization Problem ◽

Quantum Evolution ◽

Ramsey Numbers ◽

Uniform Hypergraphs

Gaitan and Clark [Phys. Rev. Lett.108 (2012) 010501] have recently presented a quantum algorithm for the computation of the Ramsey numbers R(m, n) using adiabatic quantum evolution (AQE). We consider that the two-color Ramsey numbers R(m, n; r) for r-uniform hypergraphs can be computed by using the similar ways in Phys. Rev. Lett.108 (2012) 010501. In this paper, we show how the computation of R(m, n; r) can be mapped to a combinatorial optimization problem whose solution be found using AQE.

Gallai–Ramsey numbers for graphs with chromatic number three

Discrete Applied Mathematics ◽

10.1016/j.dam.2021.07.024 ◽

2021 ◽

Vol 304 ◽

pp. 110-118

Author(s):

Qinghong Zhao ◽

Bing Wei

Keyword(s):

Chromatic Number ◽

Ramsey Numbers

On induced Ramsey numbers fork-uniform hypergraphs

Random Structures and Algorithms ◽

10.1002/rsa.20580 ◽

2015 ◽

Vol 48 (1) ◽

pp. 5-20

Author(s):

Domingos Dellamonica ◽

Steven La Fleur ◽

Vojtěch Rödl

Keyword(s):

Ramsey Numbers ◽

Uniform Hypergraphs

A Note on Embedding Hypertrees

The Electronic Journal of Combinatorics ◽

10.37236/256 ◽

2009 ◽

Vol 16 (1) ◽

Cited By ~ 3

Author(s):

Po-Shen Loh

Keyword(s):

Graph Theory ◽

Chromatic Number ◽

Classical Result ◽

Uniform Hypergraph ◽

Uniform Hypergraphs

A classical result from graph theory is that every graph with chromatic number $\chi > t$ contains a subgraph with all degrees at least $t$, and therefore contains a copy of every $t$-edge tree. Bohman, Frieze, and Mubayi recently posed this problem for $r$-uniform hypergraphs. An $r$-tree is a connected $r$-uniform hypergraph with no pair of edges intersecting in more than one vertex, and no sequence of distinct vertices and edges $(v_1, e_1, \ldots, v_k, e_k)$ with all $e_i \ni \{v_i, v_{i+1}\}$, where we take $v_{k+1}$ to be $v_1$. Bohman, Frieze, and Mubayi proved that $\chi > 2rt$ is sufficient to embed every $r$-tree with $t$ edges, and asked whether the dependence on $r$ was necessary. In this note, we completely solve their problem, proving the tight result that $\chi > t$ is sufficient to embed any $r$-tree with $t$ edges.

Colour Classes for r-Graphs

Canadian Mathematical Bulletin ◽

10.4153/cmb-1972-063-2 ◽

1972 ◽

Vol 15 (3) ◽

pp. 349-354 ◽

Cited By ~ 14

Author(s):

E. J. Cockayne

Keyword(s):

Structural Properties ◽

Chromatic Number ◽

Ramsey Numbers ◽

Graph Theoretic ◽

Special Cases ◽

Finite Set ◽

Colour Classes

By an r-graph G we mean a finite set V(G) of elements called vertices and a set E(G) of some of the r-subsets of V(G) called edges. This paper defines certain colour classes of r-graphs which connect the material of a variety of recent graph theoretic literature in that many existing results may be reformulated as structural properties of the classes for some special cases of r-graphs. It is shown that the concepts of Ramsey Numbers, chromatic number and index may be defined in terms of these classes. These concepts and some of their properties are generalized. The final subsection compares two existing bounds for the chromatic number of a graph.

Ramsey Numbers of Ordered Graphs

The Electronic Journal of Combinatorics ◽

10.37236/7816 ◽

2020 ◽

Vol 27 (1) ◽

Cited By ~ 1

Author(s):

Martin Balko ◽

Josef Cibulka ◽

Karel Král ◽

Jan Kynčl

Keyword(s):

Chromatic Number ◽

Complete Graph ◽

Positive Answer ◽

Ramsey Number ◽

Ramsey Numbers ◽

Minimum Number ◽

Ordered Graphs ◽

Constant Interval ◽

Monochromatic Copy ◽

Special Classes

An ordered graph is a pair $\mathcal{G}=(G,\prec)$ where $G$ is a graph and $\prec$ is a total ordering of its vertices. The ordered Ramsey number $\overline{R}(\mathcal{G})$ is the minimum number $N$ such that every ordered complete graph with $N$ vertices and with edges colored by two colors contains a monochromatic copy of $\mathcal{G}$. In contrast with the case of unordered graphs, we show that there are arbitrarily large ordered matchings $\mathcal{M}_n$ on $n$ vertices for which $\overline{R}(\mathcal{M}_n)$ is superpolynomial in $n$. This implies that ordered Ramsey numbers of the same graph can grow superpolynomially in the size of the graph in one ordering and remain linear in another ordering. We also prove that the ordered Ramsey number $\overline{R}(\mathcal{G})$ is polynomial in the number of vertices of $\mathcal{G}$ if the bandwidth of $\mathcal{G}$ is constant or if $\mathcal{G}$ is an ordered graph of constant degeneracy and constant interval chromatic number. The first result gives a positive answer to a question of Conlon, Fox, Lee, and Sudakov. For a few special classes of ordered paths, stars or matchings, we give asymptotically tight bounds on their ordered Ramsey numbers. For so-called monotone cycles we compute their ordered Ramsey numbers exactly. This result implies exact formulas for geometric Ramsey numbers of cycles introduced by Károlyi, Pach, Tóth, and Valtr.

Anti-Ramsey Numbers in Complete k-Partite Graphs

Mathematical Problems in Engineering ◽

10.1155/2020/5136104 ◽

2020 ◽

Vol 2020 ◽

pp. 1-5

Author(s):

Jili Ding ◽

Hong Bian ◽

Haizheng Yu

Keyword(s):

Spanning Trees ◽

Edge Coloring ◽

Perfect Matchings ◽

Ramsey Number ◽

Hamilton Cycles ◽

Ramsey Numbers ◽

The Family

The anti-Ramsey number ARG,H is the maximum number of colors in an edge-coloring of G such that G contains no rainbow subgraphs isomorphic to H. In this paper, we discuss the anti-Ramsey numbers ARKp1,p2,…,pk,Tn, ARKp1,p2,…,pk,ℳ, and ARKp1,p2,…,pk,C of Kp1,p2,…,pk, where Tn,ℳ, and C denote the family of all spanning trees, the family of all perfect matchings, and the family of all Hamilton cycles in Kp1,p2,…,pk, respectively.