Infectious disease outbreaks pose ongoing challenges to global public health, particularly due to the recurrent and dynamic nature of many pathogens. Mathematical modeling offers a powerful tool for analyzing and predicting the spread of infectious diseases. This study focuses on the SIRS (Susceptible–Infectious–Recovered–Susceptible) model, a compartmental framework that accounts for temporary immunity and its loss over time. We present two case studies—Influenza and Pertussis— to examine how variations in transmission rate, recovery rate, and immunity loss rate influence epidemic behavior. Simulations reveal that diseases with slower immunity loss, such as influenza, tend to stabilize over time with predictable seasonal peaks, whereas faster immunity loss, as in pertussis, leads to sharper and more frequent outbreaks. These insights underline the importance of tailoring vaccination strategies and public health interventions to specific epidemiological dynamics. The results demonstrate the SIRS model’s utility in forecasting disease trends and informing control policies, thus providing a foundational approach for anticipating and managing future outbreaks.
K. Sujatha (Wed,) studied this question.