Spreading in graphs
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 are contaminated initially, before the process starts. By the -forcing rule, a contaminated vertex having at most uncontaminated neighbors enforces all the neighbors to become contaminated, while by the -percolation rule, an uncontaminated vertex becomes contaminated if at least of its neighbors are contaminated. In this paper, we consider sets that are at the same time -forcing sets and -percolating sets, and call them -spreading sets. Given positive integers and , the minimum cardinality of a -spreading set in is a -spreading number, , of . While -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 -spreading number in graphs for an arbitrary choice of and . Again, for every and , we find a linear-time algorithm for determining the -spreading number of a tree. In addition, we present a lower and an upper bound on the -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 -spreading and -spreading to obtain for all and all .
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