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Distributed Delay Differential Equation Representations of Cyclic Differential Equations

Tyler Cassidy

2021SIAM Journal on Applied Mathematics12 citationsDOIOpen Access PDF

Abstract

Compartmental ordinary differential equation (ODE) models are used extensively in mathematical biology. When transit between compartments occurs at a constant rate, the well-known linear chain trick can be used to show that the ODE model is equivalent to an Erlang distributed delay differential equation (DDE). Here, we demonstrate that compartmental models with non-linear transit rates and possibly delayed arguments are also equivalent to a scalar distributed delay differential equation. To illustrate the utility of these equivalences, we calculate the equilibria of the scalar DDE, and compute the characteristic function-- without calculating a determinant. We derive the equivalent scalar DDE for two examples of models in mathematical biology and use the DDE formulation to identify physiological processes that were otherwise hidden by the compartmental structure of the ODE model.

Topics & Concepts

OdeMathematicsDelay differential equationScalar (mathematics)Ordinary differential equationApplied mathematicsDifferential equationDistributed parameter systemErlang (programming language)Constant (computer programming)Linear differential equationExact differential equationMathematical analysisUniversal differential equationPartial differential equationBernoulli differential equationMathematical modelDifferential (mechanical device)First-order partial differential equationIntegrating factorChain (unit)Functional differential equationGene Regulatory Network AnalysisMathematical and Theoretical Epidemiology and Ecology ModelsMicrobial Metabolic Engineering and Bioproduction
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