Abstract
The Kneser graph $KG_{n,k}$ is the graph whose vertices are the $k$-element subsets of $[n],$ with two vertices adjacent if and only if the corresponding sets are disjoint. A famous result due to Lovász states that the chromatic number of $KG_{n,k}$ is equal to $n-2k+2$. In this paper we discuss the chromatic number of random Kneser graphs and hypergraphs. It was studied in two recent papers, one due to Kupavskii, who proposed the problem and studied the graph case, and the more recent one due to Alishahi and Hajiabolhassan. The authors of the latter paper had extended the result of Kupavskii to the case of general Kneser hypergraphs. Moreover, they have improved the bounds of Kupavskii in the graph case for many values of parameters.In the present paper we present a purely combinatorial approach to the problem based on blow-ups of graphs, which gives much better bounds on the chromatic number of random Kneser and Schrijver graphs and Kneser hypergraphs. This allows us to improve all known results on the topic. The most interesting improvements are obtained in the case of $r$-uniform Kneser hypergraphs with $r\ge 3$, where we managed to replace certain polynomial dependencies of the parameters by the logarithmic ones.
Highlights
Kneser graphs and hypergraphs are very popular and well-studied objects in combinatorics
In the present paper we present a purely combinatorial approach to the problem based on blow-ups of graphs, which gives much better bounds on the chromatic number of random Kneser and Schrijver graphs and Kneser hypergraphs
In this paper we describe a purely combinatorial approach to the problem, which allows us to significantly improve all previously known bounds on the chromatic numbers in the most interesting cases: for random subgraphs of Kneser and Schrijver graphs and Kneser hypergraphs
Summary
Kneser graphs and hypergraphs are very popular and well-studied objects in combinatorics. I. Barany [5] gave an elegant alternative proof of Lovasz’ result, and several authors studied the chromatic number of Kneser (disjointness) graphs of arbitrary set systems. Krız [23], [24] obtained the bound on the chromatic number of Kneser hypergraphs of general set families. Erdos [15] asked a more general question: what is the size of the largest family of k-element subsets of [n] with no r pairwise disjoint sets? In this paper we describe a purely combinatorial approach to the problem, which allows us to significantly improve all previously known bounds on the chromatic numbers in the most interesting cases: for random subgraphs of (complete) Kneser and Schrijver graphs and Kneser hypergraphs. This does not, cover all generalized Kneser hypergraphs, so the result of Alishahi and Hajabolhassan remains best known in some cases
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