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Mathematical Analysis and Numerical Solution of a Model of HIV with a Discrete Time Delay

Abraham J. Arenas, Gilberto González‐Parra, Jhon J. Naranjo, Myladis Cogollo, Nicolás De La Espriella

2021Mathematics21 citationsDOIOpen Access PDF

Abstract

We propose a mathematical model based on a set of delay differential equations that describe intracellular HIV infection. The model includes three different subpopulations of cells and the HIV virus. The mathematical model is formulated in such a way that takes into account the time between viral entry into a target cell and the production of new virions. We study the local stability of the infection-free and endemic equilibrium states. Moreover, by using a suitable Lyapunov functional and the LaSalle invariant principle, it is proved that if the basic reproduction ratio is less than unity, the infection-free equilibrium is globally asymptotically stable. In addition, we designed a non-standard difference scheme that preserves some relevant properties of the continuous mathematical model.

Topics & Concepts

Stability theoryBasic reproduction numberMathematicsInvariance principleStability (learning theory)Invariant (physics)Lyapunov functionApplied mathematicsHuman immunodeficiency virus (HIV)Differential equationSet (abstract data type)Computer scienceMathematical analysisVirologyBiologyPhysicsNonlinear systemPopulationMathematical physicsProgramming languageQuantum mechanicsPhilosophyDemographyLinguisticsMachine learningSociologyMathematical and Theoretical Epidemiology and Ecology ModelsCOVID-19 epidemiological studiesEvolution and Genetic Dynamics
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