Dynamic behaviour of a discrete-time SIR model with information dependent vaccine uptake

Alberto d’Onofrio; Piero Manfredi; Ernesto Salinelli

doi:10.1080/10236198.2015.1107549

Dynamic behaviour of a discrete-time SIR model with information dependent vaccine uptake

Alberto d’Onofrio, Piero Manfredi, Ernesto Salinelli

Dipartimento di Medicina Traslazionale

Risultato della ricerca: Contributo su rivista › Articolo in rivista › peer review

Abstract

This paper proposes and analyzes a discrete-time deterministic SIR model with information dependent immunization behaviour, where vaccination coverage at birth during any period of time is a general phenomenological function of the risk of infection that is perceived at the beginning of the period. Results on existence of equilibria, their local stability, and system persistence are proved. Then, by considering the noteworthy subcase of a piecewise linear ‘prevalence-dependent’ coverage function, the local stability of the endemic state is proved and conditions for its global asymptotic stability are given. Some insight on both Neimarck-Sacher and period-doubling bifurcations are provided. Overall we show that prevalence-dependent coverage is an essentially stabilising force. However period-doubling bifurcations are possible though under stressed parameter constellations.

Lingua originale	Inglese
pagine (da-a)	485-512
Numero di pagine	28
Rivista	Journal of Difference Equations and Applications
Volume	22
Numero di pubblicazione	3
DOI	https://doi.org/10.1080/10236198.2015.1107549
Stato di pubblicazione	Pubblicato - 3 mar 2016

OSS delle Nazioni Unite

Questo processo contribuisce al raggiungimento dei seguenti obiettivi di sviluppo sostenibile

Accesso al documento

10.1080/10236198.2015.1107549

Altri file e collegamenti

Link to publication in Scopus

Cita questo

@article{5615e0ff29e24d37a96f29b12420404e,

title = "Dynamic behaviour of a discrete-time SIR model with information dependent vaccine uptake",

abstract = "This paper proposes and analyzes a discrete-time deterministic SIR model with information dependent immunization behaviour, where vaccination coverage at birth during any period of time is a general phenomenological function of the risk of infection that is perceived at the beginning of the period. Results on existence of equilibria, their local stability, and system persistence are proved. Then, by considering the noteworthy subcase of a piecewise linear {\textquoteleft}prevalence-dependent{\textquoteright} coverage function, the local stability of the endemic state is proved and conditions for its global asymptotic stability are given. Some insight on both Neimarck-Sacher and period-doubling bifurcations are provided. Overall we show that prevalence-dependent coverage is an essentially stabilising force. However period-doubling bifurcations are possible though under stressed parameter constellations.",

keywords = "Discrete deterministic SIR models, global stability, oscillations, persistence, rational opposition to vaccination",

author = "Alberto d{\textquoteright}Onofrio and Piero Manfredi and Ernesto Salinelli",

note = "Publisher Copyright: {\textcopyright} 2015 Taylor & Francis.",

year = "2016",

month = mar,

day = "3",

doi = "10.1080/10236198.2015.1107549",

language = "English",

volume = "22",

pages = "485--512",

journal = "Journal of Difference Equations and Applications",

issn = "1023-6198",

publisher = "Taylor and Francis Ltd.",

number = "3",

}

TY - JOUR

T1 - Dynamic behaviour of a discrete-time SIR model with information dependent vaccine uptake

AU - d’Onofrio, Alberto

AU - Manfredi, Piero

AU - Salinelli, Ernesto

PY - 2016/3/3

Y1 - 2016/3/3

N2 - This paper proposes and analyzes a discrete-time deterministic SIR model with information dependent immunization behaviour, where vaccination coverage at birth during any period of time is a general phenomenological function of the risk of infection that is perceived at the beginning of the period. Results on existence of equilibria, their local stability, and system persistence are proved. Then, by considering the noteworthy subcase of a piecewise linear ‘prevalence-dependent’ coverage function, the local stability of the endemic state is proved and conditions for its global asymptotic stability are given. Some insight on both Neimarck-Sacher and period-doubling bifurcations are provided. Overall we show that prevalence-dependent coverage is an essentially stabilising force. However period-doubling bifurcations are possible though under stressed parameter constellations.

AB - This paper proposes and analyzes a discrete-time deterministic SIR model with information dependent immunization behaviour, where vaccination coverage at birth during any period of time is a general phenomenological function of the risk of infection that is perceived at the beginning of the period. Results on existence of equilibria, their local stability, and system persistence are proved. Then, by considering the noteworthy subcase of a piecewise linear ‘prevalence-dependent’ coverage function, the local stability of the endemic state is proved and conditions for its global asymptotic stability are given. Some insight on both Neimarck-Sacher and period-doubling bifurcations are provided. Overall we show that prevalence-dependent coverage is an essentially stabilising force. However period-doubling bifurcations are possible though under stressed parameter constellations.

KW - Discrete deterministic SIR models

KW - global stability

KW - oscillations

KW - persistence

KW - rational opposition to vaccination

UR - http://www.scopus.com/inward/record.url?scp=84946945049&partnerID=8YFLogxK

U2 - 10.1080/10236198.2015.1107549

DO - 10.1080/10236198.2015.1107549

M3 - Article

SN - 1023-6198

VL - 22

SP - 485

EP - 512

JO - Journal of Difference Equations and Applications

JF - Journal of Difference Equations and Applications

IS - 3

ER -

Dynamic behaviour of a discrete-time SIR model with information dependent vaccine uptake

Abstract

OSS delle Nazioni Unite

Accesso al documento

Altri file e collegamenti

Fingerprint

Cita questo