2013
DOI: 10.1098/rspa.2012.0436
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How big is an outbreak likely to be? Methods for epidemic final-size calculation

Abstract: Epidemic models have become a routinely used tool to inform policy on infectious disease. A particular interest at the moment is the use of computationally intensive inference to parametrize these models. In this context, numerical efficiency is critically important. We consider methods for evaluating the probability mass function of the total number of infections over the course of a stochastic epidemic, with a focus on homogeneous finite populations, but also considering heterogeneous and large populations. … Show more

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Cited by 56 publications
(64 citation statements)
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“…The final size analysis has been deepened by Ball for the single population scenario [24] and also extended to include multi-type epidemics [25,30]. For a thorough discussion of numerical methods, and potential pitfalls, for solving the resultant final size distributions see House et al [128]. The major drawback to using result (53) is that ∆T and e next are represented implicitly in terms of a set of exp(1) distributed 'latent' random variables [64] rather than given directly.…”
Section: Non-markovian Arrival Timesmentioning
confidence: 99%
“…The final size analysis has been deepened by Ball for the single population scenario [24] and also extended to include multi-type epidemics [25,30]. For a thorough discussion of numerical methods, and potential pitfalls, for solving the resultant final size distributions see House et al [128]. The major drawback to using result (53) is that ∆T and e next are represented implicitly in terms of a set of exp(1) distributed 'latent' random variables [64] rather than given directly.…”
Section: Non-markovian Arrival Timesmentioning
confidence: 99%
“…For this variable y = 0 means that the entire population becomes infected and then removed during the epidemic, while y = 1 means that the disease dies out without causing any infection. Equation (12) takes the form yS 0 = y 2/n N τ +γ τ − y 1/n N γ τ for the new unknown y. This form is not suitable to prove the uniqueness and to apply the iteration hence the following transformations are carried out first to obtain a proper fixed point equation.…”
Section: Uniqueness Of the Nontrivial Solution Of The Implicit Equationmentioning
confidence: 99%
“…The final epidemic size was determined for the same values of τ from the homogeneous mean-field given by (4) using the iteration in Proposition 2. Similarly, using the iteration in Proposition 6, the final epidemic size is determined from the homogeneous pairwise model as R ∞ = N − S ∞ with S ∞ being the solution of (12). The comparison is shown in Figure 1 for a complete graph with N = 1000 nodes varying τ from 0 to 0.005.…”
Section: Comparison Of Mean-field and Stochastic Models For The Complmentioning
confidence: 99%
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“…This is the probability distribution that a given proportion of the clump will have been infected over the course of the within-clump epidemic. This can be calculated via a number of methods (Ball, 1986;House et al, 2013). Figure 3 shows the mean and variance of the offspring distribution as a function of β and n; the mean is equal to R * .…”
Section: Initial Behaviourmentioning
confidence: 99%