Dynamical analysis of a new chaotic system: asymmetric multistability, offset boosting control and circuit realization

Dynamical analysis of a new chaotic system: asymmetric multistability, offset boosting control and circuit realization

In this paper, a new four-dimensional dissipative chaotic system which can produce multiple asymmetric attractors is designed and its dynamical behaviors are analyzed. The basin of attraction reveals the asymmetric multistability of the system. In addition, it is very interesting to observe differen...

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Bibliographic Details
Published in:Nonlinear dynamics Vol. 103; no. 3; pp. 2867 - 2880
Main Authors: Ma, Chenguang, Mou, Jun, Xiong, Li, Banerjee, Santo, Liu, Tianming, Han, Xintong
Format: Journal Article
Language:English
Published: Dordrecht Springer Netherlands 01-02-2021
Springer Nature B.V
Subjects:
Analog circuits
Asymmetry
Automotive Engineering
Bifurcations
Chaos theory
Circuit design
Classical Mechanics
Complexity
Control
Digital electronics
Dynamical Systems
Engineering
Mechanical Engineering
Original Paper
Parameters
Vibration
Circuit implementation
Offset boosting
SE complexity
Asymmetric coexisting attractors
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Summary:In this paper, a new four-dimensional dissipative chaotic system which can produce multiple asymmetric attractors is designed and its dynamical behaviors are analyzed. The basin of attraction reveals the asymmetric multistability of the system. In addition, it is very interesting to observe different types of asymmetric coexisting attractors as the bifurcation parameters change. The spectral entropy complexity chaotic diagrams are used to observe the changes in the sequence complexity when the two bifurcation parameters change simultaneously. Moreover, the difference of the system complexity between the two different initial values is analyzed. In order to facilitate engineering applications, the offset boosting control is introduced to the state variable, and the numerical simulation shows that the offset boosting control scheme can flexibly change the polarity of the chaotic signal. Finally, an analog circuit and a digital circuit were designed to verify the new chaotic system. The new research results will enrich the theoretical basis of multistability, offset boosting control and circuit implementation of chaos.
ISSN:0924-090X
1573-269X
DOI:10.1007/s11071-021-06276-8