Mode-locked orbits, doubling of invariant curves in discrete Hindmarsh-Rose neuron model

Muni, Sishu Shankar

doi:10.1088/1402-4896/ace0df

Cited by 16 publications

(3 citation statements)

References 33 publications

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“…In order to have a deeper understanding of neuronal networks, researchers in various fields have explored the characteristics and dynamical behavior of neuron models from the perspective of different mathematical functions and analyses. [1][2][3][4][5][6][7][8][9][10] Memristors are the fourth basic passive circuit element after resistors, inductors and capacitors. It can be seen from Ref.…”

Section: Introductionmentioning

confidence: 99%

Dynamical behaviors in discrete memristor-coupled small-world neuronal networks

Lu 鲁,

Xie 谢,

Lu 卢

et al. 2024

Chinese Phys. B

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Brain is a complex network system in which a large number of neurons are widely connected to each other and transmit signals to each other. The memory characteristic of memristors makes them suitable for simulating neuronal synapses with plasticity. In this paper, a memristor is used to simulate synapse, and a discrete small-world neuronal network is constructed based on Rulkov neurons and its dynamical behavior is explored. We explore the influence of system parameter on the dynamical behaviors of the discrete small-world network, and the system shows a variety of firing patterns such as spiking firing and triangular bursting firing when the neuronal parameter α is changed. The numerical simulation results based on Matlab show that the network topology can affect the synchronous firing behavior of the neuronal network, and the higher the reconnection probability, the number of nearest neurons, and the more significant the synchronization state of neurons. In addition, by increasing the coupling strength of memristor synapses, synchronization performance is promoted. The results of this paper can boost the research process of complex neuronal networks coupled with memristor synapse and further promote the development of neuroscience.

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Section: Introductionmentioning

confidence: 99%

Dynamical behaviors in discrete memristor-coupled small-world neuronal networks

Lu 鲁,

Xie 谢,

Lu 卢

et al. 2024

Chinese Phys. B

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“…This study helps advance our understanding of complex networks and the process of neuron firing. Muni et al 2022 considered nodal and network behaviours considering electromagnetic flux coupling show the effect of magnetic flux on the phenomenon of bistability and the presence of periodic and chaotic attractor [23][24][25][26]. More recenlty, another authors analyzed the effects of electromagnetic flux on the discrete Chialvo neuron model, and shown that the model can exhibit rich dynamical behaviors such as multistability.…”

Section: Introductionmentioning

confidence: 99%

“…More recenlty, another authors analyzed the effects of electromagnetic flux on the discrete Chialvo neuron model, and shown that the model can exhibit rich dynamical behaviors such as multistability. The impact of magnetic flux is proved on the bifurcation diagrams, Lyapunov exponent diagram, phase portraits, basins of attraction [24][25][26][27]. Recent studies have shown that magnetic induction can destroy or accelerate enzymatic reactions based on memristors [21,28].…”

Section: Introductionmentioning

confidence: 99%

Influence of the magnetic flux on the dynamics of a self-sustaining system: analytical, numerical and analogical investigations

Dang-Ra,

Chéagé Chamgoué,

Wouapi

et al. 2024

Phys. Scr.

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This paper investigates the nonlinear dynamics of a ferroelectric enzyme-substratereaction modeled by \textcolor{red}{the} bi-rhythmic \emph{van der Pol} oscillator coupled to \textcolor{red}{the} magneticflux. We derive the equilibrium points and study their stability.We analyze some bifurcation structures and the variation of the Lyapunov exponents.The phenomena of symmetric attractors and the anti-monotonicity are observed. \textcolor{red}{By} increasing the magnetic flux, \textcolor{red}{we find that the equilibrium points are stable}, tends to control chaotic regimes, and affects regular and quasi-regular ones. As the magnetic flux increases, the amplitude of the oscillations around the equilibrium points decreases and the \textcolor{red}{amplitude of the} limit cycles at the Hopf bifurcation \textcolor{red}{tends} to disappear. Further \textcolor{red}{increasing the magnetic flux gives} rise to chaotic dynamics. The electrical circuit and analogical simulations are \textcolor{red}{derived} using the PSpice software.\textcolor{red}{The agreement between analogical and numerical results is acceptable}.

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Ergodic and resonant torus doubling bifurcation in a three-dimensional quadratic map

Muni

2024

Nonlinear Dyn

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Mode-locked orbits, doubling of invariant curves in discrete Hindmarsh-Rose neuron model

Cited by 16 publications

References 33 publications

Dynamical behaviors in discrete memristor-coupled small-world neuronal networks

Dynamical behaviors in discrete memristor-coupled small-world neuronal networks

Influence of the magnetic flux on the dynamics of a self-sustaining system: analytical, numerical and analogical investigations

Ergodic and resonant torus doubling bifurcation in a three-dimensional quadratic map

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