Initial offset boosting coexisting attractors in memristive multi-double-scroll Hopfield neural network

Memristors are widely considered to be promising candidates to mimic biological synapses. In this paper, by introducing a non-ideal flux-controlled memristor model into a Hopfield neural network (HNN), a novel memristive HNN model with multi-double-scroll attractors is constructed. The parity of the...

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Veröffentlicht in:	Nonlinear dynamics 2020-12, Vol.102 (4), p.2821-2841
Hauptverfasser:	Zhang, Sen, Zheng, Jiahao, Wang, Xiaoping, Zeng, Zhigang, He, Shaobo
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Schlagworte:	Automotive Engineering Circuit design Classical Mechanics Computer simulation Control Dynamical Systems Encryption Engineering Mathematical models Mechanical Engineering Memristors Neural networks Original Paper Synapses Vibration
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creator	Zhang, Sen Zheng, Jiahao Wang, Xiaoping Zeng, Zhigang He, Shaobo
description	Memristors are widely considered to be promising candidates to mimic biological synapses. In this paper, by introducing a non-ideal flux-controlled memristor model into a Hopfield neural network (HNN), a novel memristive HNN model with multi-double-scroll attractors is constructed. The parity of the number of double scrolls can be flexibly controlled by the internal parameters of the memristor. Through theoretical analysis and numerical simulation, various coexisting attractors and amplitude control are observed. Particularly, the interesting and rare phenomenon of the memristor initial offset boosting coexisting dynamics is discovered, in which the initial offset boosting coexisting double-scroll attractors with banded attraction basins are distributed in a line along the boosting route with the variation of the memristor initial condition. In addition, it is also found that the number of the initial offset boosting coexisting double-scroll attractors is closely related to the total number of scrolls and ultimately tends to infinity with increasing the total number of scrolls, meaning the emergence of extreme multistability. Then, the random performance of the initial offset boosting coexisting double-scroll attractors is tested by the NIST test suite. Moreover, an encryption scheme based on them is also proposed. The obtained results show that they have excellent randomness and are suitable for image encryption application. Finally, numerical simulation results are well demonstrated by circuit experiments, showing the feasibility of the designed memristive multi-double-scroll HNN model.
doi_str_mv	10.1007/s11071-020-06072-w
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In this paper, by introducing a non-ideal flux-controlled memristor model into a Hopfield neural network (HNN), a novel memristive HNN model with multi-double-scroll attractors is constructed. The parity of the number of double scrolls can be flexibly controlled by the internal parameters of the memristor. Through theoretical analysis and numerical simulation, various coexisting attractors and amplitude control are observed. Particularly, the interesting and rare phenomenon of the memristor initial offset boosting coexisting dynamics is discovered, in which the initial offset boosting coexisting double-scroll attractors with banded attraction basins are distributed in a line along the boosting route with the variation of the memristor initial condition. In addition, it is also found that the number of the initial offset boosting coexisting double-scroll attractors is closely related to the total number of scrolls and ultimately tends to infinity with increasing the total number of scrolls, meaning the emergence of extreme multistability. Then, the random performance of the initial offset boosting coexisting double-scroll attractors is tested by the NIST test suite. Moreover, an encryption scheme based on them is also proposed. The obtained results show that they have excellent randomness and are suitable for image encryption application. 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subjects	Automotive Engineering Circuit design Classical Mechanics Computer simulation Control Dynamical Systems Encryption Engineering Mathematical models Mechanical Engineering Memristors Neural networks Original Paper Synapses Vibration
title	Initial offset boosting coexisting attractors in memristive multi-double-scroll Hopfield neural network
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