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A model for the spatial spread of an epidemic

Journal of Mathematical Biology volume 4pages 337–351 (1977)Cite this article

Summary

We set up a deterministic model for the spatial spread of an epidemic. Essentially, the model consists of a nonlinear integral equation which has an unique solution. We show that this solution has a temporally asymptotic limit which describes the final state of the epidemic and is the minimal solution of another nonlinear integral equation. We outline the asymptotic behaviour of this minimal solution at a great distance from the epidemic's origin and generalize D. G. Kendall's pandemic threshold theorem (1957).

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  1. Mathematisches Institut, Universität Münster, Roxeler Straße 64, D-4400, Münster, Federal Republic of Germany

    H. R. Thieme

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  1. H. R. Thieme
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Thieme, H.R. A model for the spatial spread of an epidemic. J. Math. Biol. 4, 337–351 (1977). https://doi.org/10.1007/BF00275082

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  • DOI: https://doi.org/10.1007/BF00275082

Keywords

  • Integral Equation
  • Stochastic Process
  • Unique Solution
  • Asymptotic Behaviour
  • Probability Theory