English

Exponential Independence

Combinatorics 2016-05-20 v1

Abstract

For a set SS of vertices of a graph GG, a vertex uu in V(G)SV(G)\setminus S, and a vertex vv in SS, let dist(G,S)(u,v){\rm dist}_{(G,S)}(u,v) be the distance of uu and vv in the graph G(S{v})G-(S\setminus \{ v\}). Dankelmann et al. (Domination with exponential decay, Discrete Math. 309 (2009) 5877-5883) define SS to be an exponential dominating set of GG if w(G,S)(u)1w_{(G,S)}(u)\geq 1 for every vertex uu in V(G)SV(G)\setminus S, where w(G,S)(u)=vS(12)dist(G,S)(u,v)1w_{(G,S)}(u)=\sum\limits_{v\in S}\left(\frac{1}{2}\right)^{{\rm dist}_{(G,S)}(u,v)-1}. Inspired by this notion, we define SS to be an exponential independent set of GG if w(G,S{u})(u)<1w_{(G,S\setminus \{ u\})}(u)<1 for every vertex uu in SS, and the exponential independence number αe(G)\alpha_e(G) of GG as the maximum order of an exponential independent set of GG. Similarly as for exponential domination, the non-local nature of exponential independence leads to many interesting effects and challenges. Our results comprise exact values for special graphs as well as tight bounds and the corresponding extremal graphs. Furthermore, we characterize all graphs GG for which αe(H)\alpha_e(H) equals the independence number α(H)\alpha(H) for every induced subgraph HH of GG, and we give an explicit characterization of all trees TT with αe(T)=α(T)\alpha_e(T)=\alpha(T).

Keywords

Cite

@article{arxiv.1605.05991,
  title  = {Exponential Independence},
  author = {Simon Jäger and Dieter Rautenbach},
  journal= {arXiv preprint arXiv:1605.05991},
  year   = {2016}
}
R2 v1 2026-06-22T14:04:44.273Z