Periodic Behaviour of an Epidemic in a Seasonal Environment with Vaccination

Infectious diseases include all diseases caused by the transmission of a pathogenic agent such as bacteria, viruses, parasites, prions, and fungi. They, therefore, cover a wide spectrum of benign pathologies such as colds or angina but also very serious ones such as AIDS, hepatitis, malaria, or tuberculosis. Many epidemic diseases exhibit seasonal peak periods. Studying the population behaviours due to seasonal environment becomes a necessity for predicting the risk of disease transmission and trying to control it. In this work, we considered a five-dimensional system for a fatal disease in a seasonal environment. We studied, in the first step, the autonomous system by investigating the global stability of the steady states. In a second step, we established the existence, uniqueness, positivity, and boundedness of a periodic orbit. We showed that the global dynamics are determined using the basic reproduction number denoted by R-0 and calculated using the spectral radius of an integral operator. The global stability of the disease-free periodic solution was satisfied if R-0<1, and we show also the persistence of the disease once R-0>1. Finally, we displayed some numerical investigations supporting the theoretical findings, where the trajectories converge to a limit cycle if R-0>1.

Automated summary

Infectious diseases encompass a wide range of diseases caused by various pathogens. The study of population behaviors in relation to seasonal environment is crucial for predicting disease transmission and controlling it. In this research, a five-dimensional system for a fatal disease in a seasonal environment was considered. The study focused on the global stability of steady states and the existence of a periodic orbit. The findings showed that the disease dynamics are determined by the basic reproduction number (R-0), and numerical investigations supported the theoretical results.