Stochastic and Deterministic Model for Transmission of Monkey pox Disease

Authors

  • IO Ogwuche
  • Emeoyi A. T Department of Mathematics and Computer Science, Benue State University, Makurdi

Keywords:

Stochastic Differential Equation, Drift, Volatity

Abstract

In this paper, a SIR Model is established for Monkey Pox disease. SIR is an acronym which stands for Susceptible, Infectious and Recovered groups in a given population. An equivalent deterministic model which is an auxiliary tool is transformed into a stochastic model. The stochastic model is studied by numerical simulation which is used to analyse the control of transmission of the disease. Numerical simulation of the model shows that an increase in vaccination leads to low disease prevalent in a
population. Raising awareness of risk factors and educating people about the measure they can take to reduce exposure to the virus is the main prevention strategy for Monkey Pox 

Author Biography

IO Ogwuche

 

 

References

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Published

2024-06-14

How to Cite

Ogwuche, I., & Emeonyi, A. T. (2024). Stochastic and Deterministic Model for Transmission of Monkey pox Disease. NIGERIAN ANNALS OF PURE AND APPLIED SCIENCES, 6(1). Retrieved from https://napas.org.ng/index.php/napas/article/view/344