Abstract. We study the diffusion of epidemics on networks that are partitioned into local communities. The gross structure of hierarchical networks of this kind can be described by a quotient graph. The rationale of this approach is that individuals infect those belonging to the same community with higher probability than individuals in other communities. In community models the nodal infection probability is thus expected to depend mainly on the interaction of a few, large interconnected clusters. In this work, we describe the epidemic process as a continuous-time individual-based susceptible-infected-susceptible (SIS) model using a first-order mean-field approximation.A key feature of our model is that the spectral radius of this smaller quotient graph (which only captures the macroscopic structure of the community network) is all we need to know in order to decide whether the overall healthy-state defines a globally asymptotically stable or an unstable equilibrium. Indeed, the spectral radius is related to the epidemic threshold of the system.Moreover we prove that, above the threshold, another steady-state exists that can be computed using a lower-dimensional dynamical system associated with the evolution of the process on the quotient graph. Our investigations are based on the graph-theoretical notion of equitable partition and of its recent and rather flexible generalization, that of almost equitable partition.Key words. susceptible-infected-susceptible model, hierarchical networks, graph spectra, equitable and almost equitable partitions AMS subject classifications.1. Introduction. Metapopulation models of epidemics consider the entire population partitioned into communities (also called households, clusters or subgraphs). Such models assume that each community shares a common environment or is defined by a specific relationship (see, e.g., [1,2,3]).Several authors also account for the effect of migration between communities [4,5]. Conversely, the model we are interested in suits better the diffusion of computer viruses or stable social communities, which do not change during the infection period; hence we do not consider migration.In this work, we study the diffusion of epidemics over an undirected graph G = (V, E) with edge set E and node set V . The order of G, denoted N , is the cardinality of V , whereas the size of G is the cardinality of E, denoted L. Connectivity of the graph G is conveniently encoded in the N × N adjacency matrix A. We are interested in the case of networks that can be naturally partitioned into n communities: they are represented by a node set partition π = {V 1 , ..., V n }, i.e., a sequence of mutually disjoint nonempty subsets of V , called cells, whose union is V .The epidemic model adopted in the rest of the paper is a continuous-time Markovian individual-based susceptible-infected-susceptible (SIS) model. In the SIS model a node can be repeatedly infected, recover and yet be infected again. The viral state of a node i, at time t, is thus described by a Bernoulli random var...
