On methods for studying stochastic disease dynamics

Models that deal with the individual level of populations have shown the importance of stochasticity in ecology, epidemiology and evolution. An increasingly common approach to studying these models is through stochastic (event-driven) simulation. One striking disadvantage of this approach is the nee...

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Veröffentlicht in:	Journal of the Royal Society interface 2008-02, Vol.5 (19), p.171-181
Hauptverfasser:	Keeling, M.J, Ross, J.V
Format:	Artikel
Sprache:	eng
Schlagworte:	Communicable Diseases - transmission Computer Simulation Disease Dynamics Disease Outbreaks Endemic Diseases Humans Kolmogorov Forward Equations Models, Biological Parameter Estimation Research Article Stochastic Processes Stochasticity Time To Extinction Total Costs
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container_title	Journal of the Royal Society interface
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creator	Keeling, M.J Ross, J.V
description	Models that deal with the individual level of populations have shown the importance of stochasticity in ecology, epidemiology and evolution. An increasingly common approach to studying these models is through stochastic (event-driven) simulation. One striking disadvantage of this approach is the need for a large number of replicates to determine the range of expected behaviour. Here, for a class of stochastic models called Markov processes, we present results that overcome this difficulty and provide valuable insights, but which have been largely ignored by applied researchers. For these models, the so-called Kolmogorov forward equation (also called the ensemble or master equation) allows one to simultaneously consider the probability of each possible state occurring. Irrespective of the complexities and nonlinearities of population dynamics, this equation is linear and has a natural matrix formulation that provides many analytical insights into the behaviour of stochastic populations and allows rapid evaluation of process dynamics. Here, using epidemiological models as a template, these ensemble equations are explored and results are compared with traditional stochastic simulations. In addition, we describe further advantages of the matrix formulation of dynamics, providing simple exact methods for evaluating expected eradication (extinction) times of diseases, for comparing expected total costs of possible control programmes and for estimation of disease parameters.
doi_str_mv	10.1098/rsif.2007.1106
format	Article
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subjects	Communicable Diseases - transmission Computer Simulation Disease Dynamics Disease Outbreaks Endemic Diseases Humans Kolmogorov Forward Equations Models, Biological Parameter Estimation Research Article Stochastic Processes Stochasticity Time To Extinction Total Costs
title	On methods for studying stochastic disease dynamics
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