Open AccessAnalysis of a Chlamydia epidemic model with pulse vaccination strategy in a random environment
Author(s) -
G. P. Samanta,
Shyam Pada Pada Bera
Publication year - 2018
Publication title -
nonlinear analysis modelling and control
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.734
H-Index - 32
eISSN - 2335-8963
pISSN - 1392-5113
DOI - 10.15388/na.2018.4.1
Subject(s) - epidemic model , chlamydia , population , vaccination , mathematics , reliability (semiconductor) , disease , demography , pulse (music) , statistics , virology , medicine , immunology , computer science , physics , telecommunications , power (physics) , quantum mechanics , sociology , detector
. In this paper, we have considered a dynamical model of Chlamydia disease with varying total population size, bilinear incidence rate, and pulse vaccination strategy in a random environment. It has been shown that the Chlamydia epidemic model has global positive solutions and, under some conditions, it admits a unique positive periodic disease-free solution, which is globally exponentially stable in mean square. We have defined two positive numbers R1 and R2 (< R1). It is proved that the susceptible population will be persistent in the mean and the disease will be going to extinct if R1 < 1 and the susceptible population as well as the disease will be weakly persistent in the mean if R2 > 1. Our analytical findings are explained through numerical simulation, which show the reliability of our model from the epidemiological point of view.
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