English

Spreading in graphs

Combinatorics 2023-10-03 v2

Abstract

Several concepts that model processes of spreading (of information, disease, objects, etc.) in graphs or networks have been studied. In many contexts, we assume that some vertices of a graph GG are contaminated initially, before the process starts. By the qq-forcing rule, a contaminated vertex having at most qq uncontaminated neighbors enforces all the neighbors to become contaminated, while by the pp-percolation rule, an uncontaminated vertex becomes contaminated if at least pp of its neighbors are contaminated. In this paper, we consider sets SS that are at the same time qq-forcing sets and pp-percolating sets, and call them (p,q)(p,q)-spreading sets. Given positive integers pp and qq, the minimum cardinality of a (p,q)(p,q)-spreading set in GG is a (p,q)(p,q)-spreading number, σ(p,q)(G)\sigma_{(p,q)}(G), of GG. While qq-forcing sets have been studied in a dozen of papers, the decision version of the corresponding graph invariant has not been considered earlier, and we fill the gap by proving its NP-completeness. This, in turn, enables us to prove the NP-completeness of the decision version of the (p,q)(p,q)-spreading number in graphs for an arbitrary choice of pp and qq. Again, for every pNp\in \mathbb{N} and qN{}q\in\mathbb{N}\cup\{\infty\}, we find a linear-time algorithm for determining the (p,q)(p,q)-spreading number of a tree. In addition, we present a lower and an upper bound on the (p,q)(p,q)-spreading number of a tree and characterize extremal families of trees. In the case of square grids, we combine some known results and new results on (2,1)(2,1)-spreading and (4,q)(4,q)-spreading to obtain σ(p,q)(PmPn)\sigma_{(p,q)}(P_m\Box P_n) for all (p,q)(N{3})×(N{})(p,q)\in (\mathbb{N}\setminus\{3\})\times (\mathbb{N}\cup\{\infty\}) and all m,nNm,n\in\mathbb{N}.

Keywords

Cite

@article{arxiv.2309.16852,
  title  = {Spreading in graphs},
  author = {Boštjan Brešar and Tanja Dravec and Aysel Erey and Jaka Hedžet},
  journal= {arXiv preprint arXiv:2309.16852},
  year   = {2023}
}

Comments

20 pages, 5 figures

R2 v1 2026-06-28T12:35:31.377Z