Analyzing Bifurcations and Optimal Control Strategies in SIRS Epidemic Models: Insights from Theory and COVID-19 Data

Analyzing Bifurcations and Optimal Control Strategies in SIRS Epidemic Models: Insights from Theory and COVID-19 Data

This study investigates the dynamic behavior of an SIRS epidemic model in discrete time, focusing primarily on mathematical analysis. We identify two equilibrium points, disease-free and endemic, with our main focus on the stability of the endemic state. Using data from the US Department of Health a...

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Veröffentlicht in:Mathematical and computational applications 2024-08, Vol.29 (4), p.69
Hauptverfasser: Mohamed Cherif Belili, Sahari, Mohamed Lamine, Kebiri, Omar, Halim Zeghdoudi
Format: Artikel
Sprache:eng
Schlagworte:
bifurcation curve
Bifurcations
COVID-19
Data analysis
discrete epidemic model
Disease control
Disease transmission
Eigenvalues
Emigration
Epidemics
Equilibrium
flip bifurcation
Immigration
Mathematical analysis
Maximum principle
numerical simulation
Optimal control
Optimization
Pandemics
Parameter estimation
Parameter identification
Population
Simulation
stability
transcritical bifurcation
Viral diseases
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Zusammenfassung:This study investigates the dynamic behavior of an SIRS epidemic model in discrete time, focusing primarily on mathematical analysis. We identify two equilibrium points, disease-free and endemic, with our main focus on the stability of the endemic state. Using data from the US Department of Health and optimizing the SIRS model, we estimate model parameters and analyze two types of bifurcations: Flip and Transcritical. Bifurcation diagrams and curves are presented, employing the Carcasses method. for the Flip bifurcation and an implicit function approach for the Transcritical bifurcation. Finally, we apply constrained optimal control to the infection and recruitment rates in the discrete SIRS model. Pontryagin’s maximum principle is employed to determine the optimal controls. Utilizing COVID-19 data from the USA, we showcase the effectiveness of the proposed control strategy in mitigating the pandemic’s spread.
ISSN:1300-686X
2297-8747
DOI:10.3390/mca29040069