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Stochastic Delay Differential Equations: A Comprehensive Approach for Understanding Biosystems with Application to Disease Modelling

Oluwatosin Babasola, Evans Otieno Omondi, Kayode Oshinubi, Nancy Matendechere Imbusi

2023AppliedMath15 citationsDOIOpen Access PDF

Abstract

Mathematical models have been of great importance in various fields, especially for understanding the dynamical behaviour of biosystems. Several models, based on classical ordinary differential equations, delay differential equations, and stochastic processes are commonly employed to gain insights into these systems. However, there is potential to extend such models further by combining the features from the classical approaches. This work investigates stochastic delay differential equations (SDDEs)-based models to understand the behaviour of biosystems. Numerical techniques for solving these models that demonstrate a more robust representation of real-life scenarios are presented. Additionally, quantitative roles of delay and noise to gain a deeper understanding of their influence on the system’s overall behaviour are analysed. Subsequently, numerical simulations that illustrate the model’s robustness are provided and the results suggest that SDDEs provide a more comprehensive representation of many biological systems, effectively accounting for the uncertainties that arise in real-life situations.

Topics & Concepts

Robustness (evolution)Delay differential equationStochastic differential equationRepresentation (politics)Ordinary differential equationComputer scienceDynamical systems theoryDifferential equationApplied mathematicsStochastic modellingStochastic partial differential equationMathematicsMathematical optimizationPhysicsChemistryPoliticsBiochemistryPolitical scienceMathematical analysisGeneStatisticsLawQuantum mechanicsMathematical and Theoretical Epidemiology and Ecology ModelsEvolution and Genetic DynamicsNonlinear Dynamics and Pattern Formation