Prelude to hopf bifurcation in an epidemic model: Analysis of a characteristic equation associated with a nonlinear Volterra integral equation

O. Diekmann; R. Montijn

doi:10.1007/BF02154757

Prelude to hopf bifurcation in an epidemic model: Analysis of a characteristic equation associated with a nonlinear Volterra integral equation

O. Diekmann^*
, R. Montijn

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

We discuss a simple deterministic model for the spread, in a closed population, of an infectious disease which confers only temporary immunity. The model leads to a nonlinear Volterra integral equation of convolution type. We are interested in the bifurcation of periodic solutions from a constant solution (the endemic state) as a certain parameter (the population size) is varied. Thus we are led to study a characteristic equation. Our main result gives a fairly detailed description (in terms of Fourier coefficients of the kernel) of the traffic of roots across the imaginary axis. As a corollary we obtain the following: if the period of immunity is longer than the preceding period of incubation and infectivity, then the endemic state is unstable for large population sizes and at least one periodic solution will originate.

Original language	English
Pages (from-to)	117-127
Number of pages	11
Journal	Journal of Mathematical Biology
Volume	14
Issue number	1
DOIs	https://doi.org/10.1007/BF02154757
Publication status	Published - 1 Jan 1982
Externally published	Yes

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SDG 3 Good Health and Well-being

Keywords

Characteristic equation
Epidemic model
Hopf bifurcation
Nonlinear Volterra integral equation
Temporary immunity

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10.1007/BF02154757

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title = "Prelude to hopf bifurcation in an epidemic model: Analysis of a characteristic equation associated with a nonlinear Volterra integral equation",

abstract = "We discuss a simple deterministic model for the spread, in a closed population, of an infectious disease which confers only temporary immunity. The model leads to a nonlinear Volterra integral equation of convolution type. We are interested in the bifurcation of periodic solutions from a constant solution (the endemic state) as a certain parameter (the population size) is varied. Thus we are led to study a characteristic equation. Our main result gives a fairly detailed description (in terms of Fourier coefficients of the kernel) of the traffic of roots across the imaginary axis. As a corollary we obtain the following: if the period of immunity is longer than the preceding period of incubation and infectivity, then the endemic state is unstable for large population sizes and at least one periodic solution will originate.",

keywords = "Characteristic equation, Epidemic model, Hopf bifurcation, Nonlinear Volterra integral equation, Temporary immunity",

author = "O. Diekmann and R. Montijn",

year = "1982",

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T1 - Prelude to hopf bifurcation in an epidemic model

T2 - Analysis of a characteristic equation associated with a nonlinear Volterra integral equation

AU - Diekmann, O.

AU - Montijn, R.

PY - 1982/1/1

Y1 - 1982/1/1

N2 - We discuss a simple deterministic model for the spread, in a closed population, of an infectious disease which confers only temporary immunity. The model leads to a nonlinear Volterra integral equation of convolution type. We are interested in the bifurcation of periodic solutions from a constant solution (the endemic state) as a certain parameter (the population size) is varied. Thus we are led to study a characteristic equation. Our main result gives a fairly detailed description (in terms of Fourier coefficients of the kernel) of the traffic of roots across the imaginary axis. As a corollary we obtain the following: if the period of immunity is longer than the preceding period of incubation and infectivity, then the endemic state is unstable for large population sizes and at least one periodic solution will originate.

AB - We discuss a simple deterministic model for the spread, in a closed population, of an infectious disease which confers only temporary immunity. The model leads to a nonlinear Volterra integral equation of convolution type. We are interested in the bifurcation of periodic solutions from a constant solution (the endemic state) as a certain parameter (the population size) is varied. Thus we are led to study a characteristic equation. Our main result gives a fairly detailed description (in terms of Fourier coefficients of the kernel) of the traffic of roots across the imaginary axis. As a corollary we obtain the following: if the period of immunity is longer than the preceding period of incubation and infectivity, then the endemic state is unstable for large population sizes and at least one periodic solution will originate.

KW - Characteristic equation

KW - Epidemic model

KW - Hopf bifurcation

KW - Nonlinear Volterra integral equation

KW - Temporary immunity

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AN - SCOPUS:0020026487

SN - 0303-6812

VL - 14

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JO - Journal of Mathematical Biology

JF - Journal of Mathematical Biology

IS - 1

ER -

Prelude to hopf bifurcation in an epidemic model: Analysis of a characteristic equation associated with a nonlinear Volterra integral equation

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