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A household SIR epidemic model incorporating time of day effects

Part of: Markov processes Stochastic processes

Published online by Cambridge University Press:  21 June 2016

Peter Neal
Peter Neal*
Affiliation:
Lancaster University
*
* Postal address: Department of Mathematics and Statistics, Fylde College, Lancaster University, Lancaster LA1 4YF, UK. Email address: [email protected]
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Abstract

During the course of a day an individual typically mixes with different groups of individuals. Epidemic models incorporating population structure with individuals being able to infect different groups of individuals have received extensive attention in the literature. However, almost exclusively the models assume that individuals are able to simultaneously infect members of all groups, whereas in reality individuals will typically only be able to infect members of any group they currently reside in. In this paper we develop a model where individuals move between a community and their household during the course of the day, only infecting within their current group. By defining a novel branching process approximation with an explicit expression for the probability generating function of the offspring distribution, we are able to derive the probability of a major epidemic outbreak.

Keywords

Birth–death processbranching processhouseholds SIR epidemic model

MSC classification

Primary: 92D30: Epidemiology
Secondary: 60J80: Branching processes (Galton-Watson, birth-and-death, etc.) 60G10: Stationary processes
Type
Research Papers
Information
Journal of Applied Probability , Volume 53 , Issue 2 , June 2016 , pp. 489 - 501
Copyright
Copyright © Applied Probability Trust 2016 

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References

Aldous, D. J. (1985).Exchangeability and related topics. In Ecole d'Été de Probabilités de Saint-Flour XIII—1993 (Lecture Notes Math.1117), Springer, Berlin, pp.1198.Google Scholar
Ball, F. (1983).The threshold behaviour of epidemic models.J. Appl. Prob. 20, 227241.Google Scholar
Ball, F. (1996).Threshold behaviour in stochastic epidemics among households. In Athens Conference on Applied Probability and Time Series Analysis, Vol. I, Springer, New York, pp.253266.Google Scholar
Ball, F. and Donnelly, P. (1995).Strong approximations for epidemic models.Stoch. Process. Appl. 55, 121.Google Scholar
Ball, F. and Neal, P. (2002).A general model for stochastic SIR epidemics with two levels of mixing.Math. Biosci. 180, 73102.Google Scholar
Ball, F. and Neal, P. (2003).The great circle epidemic model.Stoch. Process. Appl. 107, 233268.Google Scholar
Ball, F. and Neal, P. (2008).Network epidemic models with two levels of mixing.Math. Biosci. 212, 6987.Google Scholar
Ball, F., Mollison, D. and Scalia-Tomba, G. (1997).Epidemics with two levels of mixing.Ann. Appl. Prob. 7, 4689.Google Scholar
Barbour, A. D. (1976).Network of queues and the method of stages.Adv. Appl. Prob. 8, 584591.Google Scholar
Gani, J. and Stals, L. (2007).A note on three stochastic processes with immigration.ANZIAM J. 48, 409418.Google Scholar
Grimmett, G. R. and Strizaker, D. R. (1992).Probability and Random Processes, 2nd edn.Oxford University Press.Google Scholar
Lamperti, J. (1967).Continuous state branching processes.Bull. Amer. Math. Soc. 73, 382386.CrossRefGoogle Scholar
Lloyd, A. L. (2001).Destabilization of epidemic models with the inclusion of realistic distributions of infectious periods.Proc. R. Soc. London B 268, 985993.Google Scholar
Pellis, L., Ball, F. and Trapman, P. (2012).Reproduction numbers for epidemic models with households and other social structures. I. Definition and calculation of R 0.Math. Biosci. 235, 8597.CrossRefGoogle ScholarPubMed
Whittle, P. (1955).The outcome of a stochastic epidemic—a note on Bailey's paper.Biometrika 42, 116122.Google Scholar