English

Upper bounds on the $k$-isolation number

Combinatorics 2025-02-17 v2

Abstract

The isolation number of a graph GG (also called the vertex-edge domination number of GG), denoted by ι(G)\iota(G), is the size of a smallest subset DD of the vertex set V(G)V(G) of GG such that GN[D]G-N[D] (the graph obtained by deleting the closed neighbourhood N[D]N[D] of DD from GG) has no edges. For k1k \geq 1, the kk-isolation number of GG is the size of a smallest subset DD of V(G)V(G) such that the maximum degree of GN[D]G-N[D] is at most k1k-1. Thus, ι1(G)=ι(G)\iota_1(G) = \iota(G). Let nn and \ell be the number of vertices and the number of leaves of GG, respectively. We show that if n3n \geq 3 and GG is connected, then ιk(G)n2\iota_k(G) \leq \frac{n - \ell}{2}. We also show that if GG is a tree TT, then ι(T)n+4\iota(T) \leq \frac{n + \ell}{4} and ιk(T)n+2k+1\iota_k(T) \leq \frac{n + \ell}{2k+1} for k2k \geq 2. These bounds together improve the inequality ιk(T)nk+2\iota_k(T) \leq \frac{n}{k+2} of Caro and Hansberg except that their inequality is better if k2k \geq 2 and k1k+2n<<kk+2n\frac{k-1}{k+2}n < \ell < \frac{k}{k+2}n. Each of the new bounds is attainable if it is an integer. For each of them, we characterize all the graphs that attain it.

Keywords

Cite

@article{arxiv.2408.14653,
  title  = {Upper bounds on the $k$-isolation number},
  author = {Peter Borg and Magdalena Lemańska and Mercè Mora and María José Souto-Salorio},
  journal= {arXiv preprint arXiv:2408.14653},
  year   = {2025}
}

Comments

28 pages, 12 figures

R2 v1 2026-06-28T18:24:36.174Z