English

Set Representations of Linegraphs

Combinatorics 2013-09-04 v2

Abstract

Let GG be a graph with vertex set V(G)V(G) and edge set E(G)E(G). A family S\mathcal{S} of nonempty sets {S1,,Sn}\{S_1,\ldots,S_n\} is a set representation of GG if there exists a one-to-one correspondence between the vertices v1,,vnv_1, \ldots, v_n in V(G)V(G) and the sets in S\mathcal{S} such that vivjE(G)v_iv_j \in E(G) if and only if SiSj\esS_i\cap S_j\neq \es. A set representation S\mathcal{S} is a distinct (respectively, antichain, uniform and simple) set representation if any two sets SiS_i and SjS_j in S\mathcal{S} have the property SiSjS_i\neq S_j (respectively, SiSjS_i\nsubseteq S_j, Si=Sj|S_i|=|S_j| and SiSj1|S_i\cap S_j|\leqslant 1). Let U(S)=i=1nSiU(\mathcal{S})=\bigcup_{i=1}^n S_i. Two set representations S\mathcal{S} and S\mathcal{S}' are isomorphic if S\mathcal{S}' can be obtained from S\mathcal{S} by a bijection from U(S)U(\mathcal{S}) to U(S)U(\mathcal{S}'). Let FF denote a class of set representations of a graph GG. The type of FF is the number of equivalence classes under the isomorphism relation. In this paper, we investigate types of set representations for linegraphs. We determine the types for the following categories of set representations: simple-distinct, simple-antichain, simple-uniform and simple-distinct-uniform.

Keywords

Cite

@article{arxiv.1309.0170,
  title  = {Set Representations of Linegraphs},
  author = {Jun-Lin Guo and Tao-Ming Wang and Yue-Li Wang and Ton Kloks},
  journal= {arXiv preprint arXiv:1309.0170},
  year   = {2013}
}
R2 v1 2026-06-22T01:18:33.177Z