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Complex dynamics in a Hopfield neural network under electromagnetic induction and electromagnetic radiation

Qiuzhen Wan, Zidie Yan, Fei Li, Simiao Chen, Jiong Liu

2022Chaos An Interdisciplinary Journal of Nonlinear Science73 citationsDOI

Abstract

Due to the potential difference between two neurons and that between the inner and outer membranes of an individual neuron, the neural network is always exposed to complex electromagnetic environments. In this paper, we utilize a hyperbolic-type memristor and a quadratic nonlinear memristor to emulate the effects of electromagnetic induction and electromagnetic radiation on a simple Hopfield neural network (HNN), respectively. The investigations show that the system possesses an origin equilibrium point, which is always unstable. Numerical results uncover that the HNN can present complex dynamic behaviors, evolving from regular motions to chaotic motions and finally to regular motions, as the memristors' coupling strength changes. In particular, coexisting bifurcations will appear with respect to synaptic weights, which means bi-stable patterns. In addition, some physical results obtained from breadboard experiments confirm Matlab analyses and Multisim simulations.

Topics & Concepts

MemristorChaoticBreadboardArtificial neural networkNonlinear systemEquilibrium pointElectromagnetic inductionControl theory (sociology)PhysicsCoupling (piping)VibrationComputer scienceAttractorBiological systemClassical mechanicsTopology (electrical circuits)MathematicsArtificial intelligenceMathematical analysisElectronic engineeringEngineeringAcousticsQuantum mechanicsElectromagnetic coilMechanical engineeringControl (management)BiologyCombinatoricsAdvanced Memory and Neural ComputingNeural Networks Stability and Synchronizationstochastic dynamics and bifurcation
Complex dynamics in a Hopfield neural network under electromagnetic induction and electromagnetic radiation | Litcius