Open AccessGlobal Stability Analysis of Dengue Transmission Model with Awareness, Vector Control and Time Delays
Author(s) -
Elvira P. de Lara-Tuprio,
Timothy Robin Y. Teng,
Jay Michael R. Macalalag
Publication year - 2021
Publication title -
journal of physics. conference series
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.21
H-Index - 85
eISSN - 1742-6596
pISSN - 1742-6588
DOI - 10.1088/1742-6596/1899/1/012104
Subject(s) - stability theory , invariance principle , lyapunov function , dengue fever , basic reproduction number , stability (learning theory) , equilibrium point , mathematics , lyapunov stability , transmission (telecommunications) , control theory (sociology) , control (management) , mathematical economics , computer science , virology , mathematical analysis , biology , physics , medicine , nonlinear system , epistemology , artificial intelligence , differential equation , philosophy , population , telecommunications , quantum mechanics , machine learning , environmental health
In this paper, a mathematical model for a single-strain dengue virus transmission, incorporating vector control, disease awareness of susceptible humans, and both the latent delays for human and mosquitoes, is proposed and studied. The global stability properties of disease-free equilibrium and endemic equilibrium are completely established through Lyapunov functionals and LaSalle’s invariance principle. The global dynamics of the equilibrium points are characterized by the value of basic reproductive number R 0 . If R 0 < 1, then the disease-free equilibrium is globally asymptotically stable. If R 0 > 1 , then the disease-free equilibrium is unstable, and the endemic equilibrium exists which is globally asymptotically stable. Lastly, this paper presents numerical simulations and possible recommendations for future works.