Target set selection with maximum activation time

Abstract

A target set selection model is a graph G with a threshold function τ:V N upper-bounded by the vertex degree. For a given model, a set S0⊂eq V(G) is a target set if V(G) can be partitioned into non-empty subsets S0,S1,…c,St such that, for i ∈ \1, …, t\, Si contains exactly every vertex v having at least τ(v) neighbors in S0… Si-1. We say that t is the activation time tτ(S0) of the target set S0. The problem of, given such a model, finding a target set of minimum size has been extensively studied in the literature. In this article, we investigate its variant, which we call TSS-time, in which the goal is to find a target set S0 that maximizes tτ(S0). That is, given a graph G, a threshold function τ in G, and an integer k, the objective of the TSS-time problem is to decide whether G contains a target set S0 such that tτ(S0)≥ k. Let τ* = v ∈ V(G) τ(v). Our main result is the following dichotomy about the complexity of TSS-time when G belongs to a minor-closed graph class C: if C has bounded local treewidth, the problem is FPT parameterized by k and τ; otherwise, it is NP-complete even for fixed k=4 and τ=2. We also prove that, with τ*=2, the problem is NP-hard in bipartite graphs for fixed k=5, and from previous results we observe that TSS-time is NP-hard in planar graphs and W[1]-hard parameterized by treewidth. Finally, we present a linear-time algorithm to find a target set S0 in a given tree maximizing tτ(S0).