English

Ramsey problems for Berge hypergraphs

Combinatorics 2019-05-08 v3

Abstract

For a graph GG, a hypergraph H\mathcal{H} is a Berge copy of GG (or a Berge-GG in short), if there is a bijection f:E(G)E(H)f : E(G) \rightarrow E(\mathcal{H}) such that for each eE(G)e \in E(G) we have ef(e)e \subseteq f(e). We denote the family of rr-uniform hypergraphs that are Berge copies of GG by BrGB^rG. For families of rr-uniform hypergraphs H\mathbf{H} and H\mathbf{H}', we denote by R(H,H)R(\mathbf{H},\mathbf{H}') the smallest number nn such that in any blue-red coloring of Knr\mathcal{K}_n^r (the complete rr-uniform hypergraph on nn vertices) there is a monochromatic blue copy of a hypergraph in H\mathbf{H} or a monochromatic red copy of a hypergraph in H\mathbf{H}'. Rc(H)R^c(\mathbf{H}) denotes the smallest number nn such that in any coloring of the hyperedges of Knr\mathcal{K}_n^r with cc colors, there is a monochromatic copy of a hypergraph in H\mathbf{H}. In this paper we initiate the general study of the Ramsey problem for Berge hypergraphs, and show that if r>2cr> 2c, then Rc(BrKn)=nR^c(B^rK_n)=n. In the case r=2cr = 2c, we show that Rc(BrKn)=n+1R^c(B^rK_n)=n+1, and if GG is a non-complete graph on nn vertices, then Rc(BrG)=nR^c(B^rG)=n, assuming nn is large enough. In the case r<2cr < 2c we also obtain bounds on Rc(BrKn)R^c(B^rK_n). Moreover, we also determine the exact value of R(B3T1,B3T2)R(B^3T_1,B^3T_2) for every pair of trees T1T_1 and T2T_2.

Keywords

Cite

@article{arxiv.1808.10434,
  title  = {Ramsey problems for Berge hypergraphs},
  author = {Dániel Gerbner and Abhishek Methuku and Gholamreza Omidi and Máté Vizer},
  journal= {arXiv preprint arXiv:1808.10434},
  year   = {2019}
}

Comments

Revised based on the suggestions of the referees

R2 v1 2026-06-23T03:49:35.059Z