Abstract
Presently, the whole world is facing the global imbalance and challenges caused by the pandemic COVID-19. So all are eager to discover the protective method for this pandemic. It is a great opportunity for researchers to analyse the high rate of spreading of virus and also about the increase in the number of deaths due to this hazard. In order to understand that we think of a proper mathematical model with its associated parameters that lead to better prediction of spread of virus and its future preparedness. Here a dynamic epidemic model is developed to study the dynamic behaviour and control technique of COVID-19. We have mainly focused on hospitalized quarantine. In this chapter, first we propose the mathematical model and justifying its positivity. Here both the stability analyses like local and global are discussed, which depends upon the basic reproduction number. The numerical simulation and graphical analysis are analysed with the help of Runge–Kutta methods of said model. Finally, the outcomes of the model represent that person-to-person contact is the main cause of this pandemic COVID-19. Lastly, this model concludes that hospitalization is the best approach to reduce the infection and fearness of pandemic situations.
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Dihudi, B., Rao, Y.S., Rout, S.K., Panda, T.C. (2021). Transmission Modelling on COVID-19 Pandemic and Its Challenges. In: Agrawal, R., Mittal, M., Goyal, L.M. (eds) Sustainability Measures for COVID-19 Pandemic. Springer, Singapore. https://doi.org/10.1007/978-981-16-3227-3_5
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DOI: https://doi.org/10.1007/978-981-16-3227-3_5
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