Abstract
Using the continuous-time susceptible-infected-susceptible (SIS) model on networks, we investigate the problem of inferring the class of the underlying network when epidemic data is only available at population-level (i.e., the number of infected individuals at a finite set of discrete times of a single realisation of the epidemic), the only information likely to be available in real world settings. To tackle this, epidemics on networks are approximated by a Birth-and-Death process which keeps track of the number of infected nodes at population level. The rates of this surrogate model encode both the structure of the underlying network and disease dynamics. We use extensive simulations over Regular, Erdős–Rényi and Barabási–Albert networks to build network class-specific priors for these rates. We then use Bayesian model selection to recover the most likely underlying network class, based only on a single realisation of the epidemic. We show that the proposed methodology yields good results on both synthetic and real-world networks.
Highlights
Using the continuous-time susceptible-infected-susceptible (SIS) model on networks, we investigate the problem of inferring the class of the underlying network when epidemic data is only available at population-level, the only information likely to be available in real world settings
In the framework presented so far, we proposed a surrogate model which approximates the evolution of the total number of infected nodes in a SIS epidemic on a network
We proposed a new inference scheme that uses population-level incidence data at discrete regular times to infer the most likely network class over which the epidemic has initially spread
Summary
It is worth noting that, in the case of B–A networks there are a few parameter combinations where the agreement between the master equation with the rates given by the (C, a, p) model and simulation results is poorer, see Fig. 2c. This is despite the seemingly small discrepancy between ( k, ak ) curve and the corresponding (C, a, p) model (not shown). This gives us confidence that the surrogate model is a viable model
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