English

A sharp upper bound for the independence number

Combinatorics 2013-08-20 v3

Abstract

An rr-graph GG is a pair (V,E)(V,E) such that VV is a set and EE is a family of rr-element subsets of VV. The \emph{independence number} α(G)\alpha(G) of GG is the size of a largest subset II of VV such that no member of EE is a subset of II. The \emph{transversal number} τ(G)\tau(G) of GG is the size of a smallest subset TT of VV that intersects each member of EE. GG is said to be \emph{connected} if for every distinct vv and ww in VV there exists a \emph{path} from vv to ww (that is, a sequence e1,,epe_1, \dots, e_p of members of EE such that ve1v \in e_1, wepw \in e_p, and if p2p \geq 2, then for each i{1,,p1}i \in \{1, \dots, p-1\}, eie_i intersects ei+1e_{i+1}). The \emph{degree} of a member vv of VV is the number of members of EE that contain vv. The maximum of the degrees of the members of VV is denoted by Δ(G)\Delta(G). We show that for any 1k<n1 \leq k < n, if G=(V,E)G = (V,E) is a connected rr-graph, V=n|V| = n, and Δ(G)=k\Delta(G) = k, then α(G)nn1k(r1),τ(G)n1k(r1),\alpha(G) \leq n - \left \lceil \frac{n-1}{k(r-1)} \right \rceil, \quad \tau(G) \geq \left \lceil \frac{n-1}{k(r-1)} \right \rceil, and these bounds are sharp. The two bounds are equivalent.

Keywords

Cite

@article{arxiv.1007.5426,
  title  = {A sharp upper bound for the independence number},
  author = {Peter Borg},
  journal= {arXiv preprint arXiv:1007.5426},
  year   = {2013}
}

Comments

8 pages

R2 v1 2026-06-21T15:55:06.625Z