Using pair approximations to predict takeover dynamics in spatially structured populations

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Using pair approximations to predict takeover dynamics in spatially structured populations

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Genetic And Evolutionary Computation Conference archive
Proceedings of the 2007 GECCO conference companion on Genetic and evolutionary computation table of contents

London, United Kingdom

SESSION: Late-breaking papers table of contents

Pages 2557-2564

Year of Publication: 2007

ISBN:978-1-59593-698-1

Authors

Joshua L. Payne	University of Vermont, Burlington, VT
Margaret J. Eppstein	University of Vermont, Burlington, VT

Sponsors

ACM: Association for Computing Machinery
SIGEVO: ACM Special Interest Group on Genetic and Evolutionary Computation

Publisher

ACM New York, NY, USA

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Downloads (6 Weeks): 4, Downloads (12 Months): 42, Citation Count: 1

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ABSTRACT

The topological properties of a network directly impact the flow of information through a system. For example, in natural populations, the network of inter-individual contacts affects the rate of flow of infectious disease. Similarly, in evolutionary systems, the topological properties of the underlying population structure affect the rate of flow of genetic information, and thus affect selective pressure. One commonly employed method for quantifying the influence of the population structure on selective pressure is through the analysis of takeover time. In this study, we reformulate takeover time analysis in terms of the well-known Susceptible-Infectious-Susceptible (SIS) model of disease spread. We then adapt an analytical technique, called the pair approximation, to provide a general model of takeover dynamics. We compare the results of this model to simulation data on a total of six regular population structures and discuss the strengths and limitations of the approximation.

REFERENCES

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