2022
DOI: 10.1007/s11071-021-07150-3
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Chaotic resonance in Izhikevich neural network motifs under electromagnetic induction

Abstract: Chaotic resonance (CR) is the response of a nonlinear system to weak signals enhanced by internal or external chaotic activity (such as the signal derived from Lorenz system). In this paper, the triple-neuron feed-forward loop (FFL) Izhikevich neural network motifs with eight types are constructed as the nonlinear systems, and the effects of EMI on CR phenomenon in FFL neuronal network motifs are studied. It is found that both the single Izhikevich neural model under electromagnetic induction (EMI) and its net… Show more

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Cited by 44 publications
(1 citation statement)
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“…The noise has a tremendous effect as amplification of the weak neuronal signal and therefore enhances the detection of useful information in the signal [ 64 ]. The addition of noise in such networks/systems has unveiled hidden facts such as the development of the stochastic methodology to understand respective resonance [ 66 ], noise sustained synchronization [ 67 ], vibrational resonance [ 68 , 69 ], chaotic resonance [ 70 ], and coherent-resonance [ 71 ] in nonlinear dynamical systems. The presence of noise in neuronal networks enforces the neurons to optimize their firing patterns which are essentially required for communications [ 72 ].…”
Section: Introductionmentioning
confidence: 99%
“…The noise has a tremendous effect as amplification of the weak neuronal signal and therefore enhances the detection of useful information in the signal [ 64 ]. The addition of noise in such networks/systems has unveiled hidden facts such as the development of the stochastic methodology to understand respective resonance [ 66 ], noise sustained synchronization [ 67 ], vibrational resonance [ 68 , 69 ], chaotic resonance [ 70 ], and coherent-resonance [ 71 ] in nonlinear dynamical systems. The presence of noise in neuronal networks enforces the neurons to optimize their firing patterns which are essentially required for communications [ 72 ].…”
Section: Introductionmentioning
confidence: 99%