Hopf bifurcation analysis for a diabetic population model with two delays and saturated treatment

This paper constructs a scale-free chemical network based on the Gierer-Meinhardt (GM) system and investigates its Turing instability. We establish a fractional-order single-node GM system with delay and design a fractional-order proportional derivative (PD) control strategy for the issue of bifurcation control. Using delay as bifurcation parameter, the existence of Hopf bifurcation is proven, and control over bifurcation threshold points is achieved through a fractional-order PD control strategy. For the scale-free chemical network based on the GM system, we obtain the condition of how the Turing instability occurs. We derive how the number of edges for the new nodes changes the stability of the network-organized system and investigate the relationship between degrees of nodes and eigenvalues of the network matrix. We give the instability condition caused by diffusion in the network-organized system. Finally, the numerical simulations verify analytical results.

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Hopf bifurcation analysis for a diabetic population model with two delays and saturated treatment

Cited by 3 publications

References 17 publications

Dynamic analysis of a diabetes mathematical model including heredity parameter and multiple time delays

Dynamic analysis of a diabetes mathematical model including heredity parameter and multiple time delays

On the dynamics of a diabetic population model with two delays and a general recovery rate of complications

A new chemical networked system: spatial-temporal evolution and control

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