The Number of Edge Colorings With No Monochromatic Cliques

Alon, Noga; Balogh, József; Keevash, Peter; Sudakov, Benny

doi:10.1112/s0024610704005563

Cited by 70 publications

(222 citation statements)

References 8 publications

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“…Our approach in the proof of Lemma 2.1 is similar to the one from [2] and [3], which is based on two important tools, the Simonovits stability theorem and the Szemerédi regularity lemma. However, we shall require a (somewhat uncommon) version of the regularity lemma for directed graphs and a few other additional ideas.…”

Section: Graphs With Many T -Free Orientationsmentioning

confidence: 99%

“…In section 4 we give a different proof for the special case T = C 3 that avoids using the regularity lemma, and obtain a moderate value for n 0 (C 3 ) (that can be optimized to less than 10000). Section 4 also contains a description of a simple reduction from the problem of counting the number or red-blue edge colorings of a graph G having no monochromatic K k (solved in [11] for k = 3 and in [2] for k > 3) to the problem of counting the number of orientations of a graph G that do not contain the transitive tournament on k vertices, denoted T k . Using this reduction we show, in particular, that n 0 (T 3 ) = 1.…”

mentioning

confidence: 99%

“…It is based on the basic approach in [2] with some additional ideas, and uses several tools from Extremal Graph Theory, including a (somewhat uncommon) directed version of the regularity lemma of Szemerédi. It provides a rare example in which this lemma is used to prove results on directed graphs, and an even more rare example of a precise result obtained with the lemma.…”

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confidence: 99%

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The Number Of Orientations Having No Fixed Tournament

Alon

Yuster

2006

Combinatorica

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Let T be a fixed tournament on k vertices. Let D(n, T ) denote the maximum number of orientations of an n-vertex graph that have no copy of T . We prove that D(n, T ) = 2 t k−1 (n) for all sufficiently (very) large n, where t k−1 (n) is the maximum possible number of edges of a graph on n vertices with no K k , (determined by Turán's Theorem). The proof is based on a directed version of Szemerédi's regularity lemma together with some additional ideas and tools from Extremal Graph Theory, and provides an example of a precise result proved by applying this lemma. For the two possible tournaments with three vertices we obtain separate proofs that avoid the use of the regularity lemma and therefore show that in these cases D(n, T ) = 2 n 2 /4 already holds for (relatively) small values of n.

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Section: Graphs With Many T -Free Orientationsmentioning

confidence: 99%

mentioning

confidence: 99%

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confidence: 99%

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The Number Of Orientations Having No Fixed Tournament

Alon

Yuster

2006

Combinatorica

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“…The process of separating the argument into a stability stage and a refinement stage focuses attention on the particular difficulties of each, and often leads to progress where the raw problem has appeared intractable. For recent examples we refer to our proofs of the conjecture of Sós on the Turán number of the Fano plane [4], and a conjecture of Yuster on edge colorings with no monochromatic cliques [1].…”

Section: Discussionmentioning

confidence: 99%

“…Looking at the vertices of such an edge in some order, we can select the first 2 vertices in αn(αn − 1) ways. Since the edge is good, the choice of 2 vertices together with a restricts the fourth vertex to lie in some particular class V i , so it can be chosen in at most 1 2 + 10 −6 n ways. Note that we have counted each edge 6 times, so we get at most αn(αn…”

Section: Theorem 22mentioning

confidence: 99%

On A Hypergraph Turán Problem Of Frankl

Keevash

Sudakov

2005

Combinatorica

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Let C (2k) r be the 2k-uniform hypergraph obtained by letting P 1 , · · · , P r be pairwise disjoint sets of size k and taking as edges all sets P i ∪ P j with i = j. This can be thought of as the 'k-expansion' of the complete graph K r : each vertex has been replaced with a set of size k. An example of a hypergraph with vertex set V that does not contain C (2k) 3 can be obtained by partitioning V = V 1 ∪V 2 and taking as edges all sets of size 2k that intersect each of V 1 and V 2 in an odd number of elements. Let B (2k) n denote a hypergraph on n vertices obtained by this construction that has as many edges as possible. We prove a conjecture of Frankl, which states that any hypergraph on n vertices that contains no C (2k) 3 has at most as many edges as B (2k) n . Sidorenko has given an upper bound of r−2 r−1 for the Turán density of C (2k) r for any r, and a construction establishing a matching lower bound when r is of the form 2 p + 1. In this paper we also show that when r = 2 p + 1, any C (4) r -free hypergraph of density r−2 r−1 − o(1) looks approximately like Sidorenko's construction. On the other hand, when r is not of this form, we show that corresponding constructions do not exist and improve the upper bound on the Turán density of C (4) r to r−2 r−1 − c(r), where c(r) is a constant depending only on r.The backbone of our arguments is a strategy of first proving approximate structure theorems, and then showing that any imperfections in the structure must lead to a suboptimal configuration. The tools for its realisation draw on extremal graph theory, linear algebra, the Kruskal-Katona theorem and properties of Krawtchouck polynomials.

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Exact Results on the Number of Restricted Edge Colorings for Some Families of Linear Hypergraphs

Lefmann

Person

2012

Journal of Graph Theory

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For k‐uniform hypergraphs F and H and an integer r≥2, let cr,F(H) denote the number of r‐colorings of the set of hyperedges of H with no monochromatic copy of F and let cr,F(n)=trueprefixmaxH∈scriptHncr,F(H), where the maximum is taken over the family Hn of all k‐uniform hypergraphs on n vertices. Moreover, let ex (n,F) be the usual extremal function, i.e., the maximum number of hyperedges of an n‐vertex k‐uniform hypergraph which contains no copy of F. Here, we consider the question for determining cr,F(n) for F being the k‐uniform expanded, complete graph Hℓ+1k or the k‐uniform Fan(k)‐hypergraph Fℓ+1k with core of size (ℓ+1), where ℓ≥k≥3, and we show cr,F(n)=r ex (n,F)for r=2,3 and n large enough. Moreover, for r=2 or r=3, for k‐uniform hypergraphs H on n vertices, the equality cr,F(H)=r ex (n,F) only holds if H is isomorphic to the ℓ‐partite, k‐uniform Turán hypergraph on n vertices, once n is large enough. On the other hand, we show that cr,F(n) is exponentially larger than r ex (n,F), if r≥4.

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The Number of Edge Colorings With No Monochromatic Cliques

Cited by 70 publications

References 8 publications

The Number Of Orientations Having No Fixed Tournament

The Number Of Orientations Having No Fixed Tournament

On A Hypergraph Turán Problem Of Frankl

Exact Results on the Number of Restricted Edge Colorings for Some Families of Linear Hypergraphs

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