• Title of article

    Hopf bifurcation in epidemic models with a latent period and nonpermanent immunity

  • Author/Authors

    Greenhalgh، نويسنده , , D.، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 1997
  • Pages
    23
  • From page
    85
  • To page
    107
  • Abstract
    In this paper, some SEIRS epidemiological models with vaccination and temporary immunity are considered. First of all, previously published work is reviewed. In the next section, a general model with a constant contact rate and a density-dependent death rate is examined. The model is reformulated in terms of the proportions of susceptible, incubating, infectious, and immune individuals. Next the equilibrium and stability properties of this model are examined, assuming that the average duration of immunity exceeds the infectious period. There is a threshold parameter Ro and the disease can persist if and only if Ro exceeds one. The disease-free equilibrium always exists and is locally stable if Ro < 1 and unstable if Ro > 1. Conditions are derived for the global stability of the disease-free equilibrium. For Ro > 1, the endemic equilibrium is unique and locally asymptotically stable. e full model dealing with numbers of individuals, there are two critical contact rates. These give conditions for the disease, respectively, to drive a population which would otherwise persist at a finite level or explode to extinction and to cause a population that would otherwise explode to be regulated at a finite level. If the contact rate β(N) is a monotone increasing function of the population size, then we find that there are now three threshold parameters which determine whether or not the disease can persist proportionally. Moreover, the endemic equilibrium need no longer be locally asymptotically stable. Instead stable limit cycles can arise by supercritical Hopf bifurcation from the endemic equilibrium as this equilibrium loses its stability. This is confirmed numerically.
  • Keywords
    Hopf bifurcation , Threshold parameter , SEIRS epidemic model , Equilibrium and stability analysis , contact rate
  • Journal title
    Mathematical and Computer Modelling
  • Serial Year
    1997
  • Journal title
    Mathematical and Computer Modelling
  • Record number

    1590752