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Hamiltonian energy computation and complex behavior of a small heterogeneous network of three neurons: circuit implementation

Zeric Tabekoueng Njitacke, Jan Awrejcewicz, Balamurali Ramakrishnan, Karthikeyan Rajagopal, Jacques Kengne

2021Nonlinear Dynamics44 citationsDOIOpen Access PDF

Abstract

Abstract Brain functions are sometimes emulated using some analog integrated circuits based on the organizational principle of natural neural networks. Neuromorphic engineering is the research branch devoted to the study and realization of such circuits with striking features. In this contribution, a novel small network of three neurons is introduced and investigated. The model is built from the coupling between two 2D Hindmarsh–Rose neurons through a 2D FitzHugh–Nagumo neuron. Thus, a heterogeneous coupled network is obtained. The biophysical energy released by the network during each electrical activity is evaluated. In addition, nonlinear analysis tools such as two-parameter Lyapunov exponent, bifurcation diagrams, the graph of the largest Lyapunov exponent, phase portraits, time series, as well as the basin of attractions are used to numerically investigate the network. It is found that the model can experience hysteresis justified by the simultaneous existence of three distinct electrical activities using the same set of parameters. Finally, the circuit implementation of the network is addressed in PSPICE to further support the obtained results.

Topics & Concepts

Lyapunov exponentPhase portraitMultistabilityNonlinear systemComputer scienceNeuromorphic engineeringTopology (electrical circuits)Electronic circuitElectrical networkArtificial neural networkGraphComputationBifurcationBistabilityControl theory (sociology)MathematicsTheoretical computer scienceAlgorithmPhysicsChaoticArtificial intelligenceControl (management)Quantum mechanicsCombinatoricsAdvanced Memory and Neural Computingstochastic dynamics and bifurcationNeural dynamics and brain function