Contagious Sets in Expanders

Abstract

We consider the following activation process in undirected graphs: a vertex is active either if it belongs to a set of initially activated vertices or if at some point it has at least r active neighbors, where r>1 is the activation threshold. A contagious set is a set whose activation results with the entire graph being active. Given a graph G, let m(G,r) be the minimal size of a contagious set. Computing m(G,r) is NP-hard. It is known that for every d-regular or nearly d-regular graph on n vertices, m(G,r) O(nrd). We consider such graphs that additionally have expansion properties, parameterized by the spectral gap and/or the girth of the graphs. The general flavor of our results is that sufficiently strong expansion (e.g., λ(G)=O(d), or girth ( d)) implies that m(G,2) O(nd2) (and more generally, m(G,r) O(ndr/(r-1))). Significantly weaker expansion properties suffice in order to imply that m(G,2) O(n dd2). For example, we show this for graphs of girth at least~7, and for graphs with λ(G)<(1-ε)d, provided the graph has no 4-cycles. Nearly d-regular expander graphs can be obtained by considering the binomial random graph G(n,p) with p dn and d > n. For such graphs we prove that (nd2 d) m(G,2) O(n dd2 d) almost surely. Our results are algorithmic, entailing simple and efficient algorithms for selecting contagious sets.