Global Dynamics of a Delayed Fractional-Order Viral Infection Model With Latently Infected Cells

C. Rajivganthi; F. A. Rihan

doi:10.3389/fams.2021.771662

Global Dynamics of a Delayed Fractional-Order Viral Infection Model With Latently Infected Cells

C. Rajivganthi, F. A. Rihan

Department of Mathematical Sciences

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

1 Citation (Scopus)

Abstract

In this paper, we propose a fractional-order viral infection model, which includes latent infection, a Holling type II response function, and a time-delay representing viral production. Based on the characteristic equations for the model, certain sufficient conditions guarantee local asymptotic stability of infection-free and interior steady states. Whenever the time-delay crosses its critical value (threshold parameter), a Hopf bifurcation occurs. Furthermore, we use LaSalle’s invariance principle and Lyapunov functions to examine global stability for infection-free and interior steady states. Our results are illustrated by numerical simulations.

Original language	English
Article number	771662
Journal	Frontiers in Applied Mathematics and Statistics
Volume	7
DOIs	https://doi.org/10.3389/fams.2021.771662
Publication status	Published - Dec 8 2021

Keywords

bifurcation
fractional order
stability
time-delay
viral infection model

ASJC Scopus subject areas

Statistics and Probability
Applied Mathematics

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10.3389/fams.2021.771662

Cite this

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title = "Global Dynamics of a Delayed Fractional-Order Viral Infection Model With Latently Infected Cells",

abstract = "In this paper, we propose a fractional-order viral infection model, which includes latent infection, a Holling type II response function, and a time-delay representing viral production. Based on the characteristic equations for the model, certain sufficient conditions guarantee local asymptotic stability of infection-free and interior steady states. Whenever the time-delay crosses its critical value (threshold parameter), a Hopf bifurcation occurs. Furthermore, we use LaSalle{\textquoteright}s invariance principle and Lyapunov functions to examine global stability for infection-free and interior steady states. Our results are illustrated by numerical simulations.",

keywords = "bifurcation, fractional order, stability, time-delay, viral infection model",

author = "C. Rajivganthi and Rihan, {F. A.}",

note = "Funding Information: This research was funded by UAE University, fund # 12S005-UPAR 2020. Publisher Copyright: Copyright {\textcopyright} 2021 Rajivganthi and Rihan.",

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AU - Rihan, F. A.

PY - 2021/12/8

Y1 - 2021/12/8

N2 - In this paper, we propose a fractional-order viral infection model, which includes latent infection, a Holling type II response function, and a time-delay representing viral production. Based on the characteristic equations for the model, certain sufficient conditions guarantee local asymptotic stability of infection-free and interior steady states. Whenever the time-delay crosses its critical value (threshold parameter), a Hopf bifurcation occurs. Furthermore, we use LaSalle’s invariance principle and Lyapunov functions to examine global stability for infection-free and interior steady states. Our results are illustrated by numerical simulations.

AB - In this paper, we propose a fractional-order viral infection model, which includes latent infection, a Holling type II response function, and a time-delay representing viral production. Based on the characteristic equations for the model, certain sufficient conditions guarantee local asymptotic stability of infection-free and interior steady states. Whenever the time-delay crosses its critical value (threshold parameter), a Hopf bifurcation occurs. Furthermore, we use LaSalle’s invariance principle and Lyapunov functions to examine global stability for infection-free and interior steady states. Our results are illustrated by numerical simulations.

KW - bifurcation

KW - fractional order

KW - stability

KW - time-delay

KW - viral infection model

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Global Dynamics of a Delayed Fractional-Order Viral Infection Model With Latently Infected Cells

Abstract

Keywords

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