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Bifurcation insight for a fractional‐order stage‐structured predator–prey system incorporating mixed time delays

Changjin Xu, Wei Zhang, Chaouki Aouiti, Zixin Liu, Lingyun Yao

2023Mathematical Methods in the Applied Sciences66 citationsDOI

Abstract

In this study, we principally investigate a fractional‐order stage‐structured predator–prey system including distributed time delays and discrete time delays. Taking advantage of transformation of the variable, we obtain an isovalent version of the considered fractional‐order stage‐structured predator–prey system including distributed time delays and discrete time delays. The isovalent version includes fractional‐order and integer‐order equations. Utilizing the stability criterion and bifurcation theory of fractional‐order differential equation, a novel delay‐independent bifurcation condition to ensure the appearance of Hopf bifurcation for the fractional‐order stage‐structured predator–prey system is set up. The impact of time delay on the stability and bifurcation is clearly revealed. Numerical simulation figures are presented to sustain the rationality of the derived key conclusions.

Topics & Concepts

MathematicsBifurcationApplied mathematicsSaddle-node bifurcationHopf bifurcationStability (learning theory)Control theory (sociology)Transformation (genetics)Discrete time and continuous timeBifurcation diagramOrder (exchange)Mathematical analysisNonlinear systemComputer scienceStatisticsControl (management)ChemistryBiochemistryArtificial intelligenceFinanceEconomicsGeneQuantum mechanicsMachine learningPhysicsMathematical and Theoretical Epidemiology and Ecology ModelsFractional Differential Equations SolutionsNonlinear Dynamics and Pattern Formation
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