A multi‐wing butterfly chaotic system and its implementation

Ma, Junpeng; Wang, Lidan; Duan, Shukai; Xu, Yaming

doi:10.1002/cta.2357

Cited by 15 publications

(7 citation statements)

References 31 publications

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“…Furthermore, this paper consistently uses the smooth cubic monotone-increasing continuous nonlinearity described as follows [20][21][22]33].…”

Section: Analysis Of a New Memristor-based Hyperchaotic Systemmentioning

confidence: 99%

“…Therefore, the paper analyzes a new memristorbased hyperchaotic system and develops a circuit physical implementation method by using the modularized design method. This method is used to design the circuit without dimensions for chaotic circuit designs and is easy to be implemented in the circuit by using less circuit parts [33][34][35][36][37][38].…”

Section: Introductionmentioning

confidence: 99%

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A New Memristor‐Based 5D Chaotic System and Circuit Implementation

Wang

Li²,

Gao

et al. 2018

Complexity

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This paper proposes a new 5D chaotic system with the flux-controlled memristor. The dynamics analysis of the new system can also demonstrate the hyperchaotic characteristics. The design and analysis of adaptive synchronization for the new memristor-based chaotic system and its slave system are carried out. Furthermore, the modularized circuit designs method is used in the new chaotic system circuit implementation. The Multisim simulation and the physical experiments are conducted, compared, and matched with each other which can demonstrate the existence of the attractor for the new system.

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“…Furthermore, this paper consistently uses the smooth cubic monotone-increasing continuous nonlinearity described as follows [20][21][22]33].…”

Section: Analysis Of a New Memristor-based Hyperchaotic Systemmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A New Memristor‐Based 5D Chaotic System and Circuit Implementation

Wang

Li²,

Gao

et al. 2018

Complexity

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“…One year later, Chen and Liu [16] obtained another four-wing butterfly attractor from a new Lorenz-like system. From then on, the realization of MWCSs has greatly stimulated the researcher's interest, and a large number of different types of MWCSs have been proposed [17][18]. During this period, Yu et al presented many important theories on the construction of MWCSs and successively put forward a series of nonlinear polynomial function control methods including a multisegment quadratic function method [19], symmetric piecewise-linear function method [20], and switching control function method [21].…”

Section: Introductionmentioning

confidence: 99%

An Extremely Simple Multiwing Chaotic System: Dynamics Analysis, Encryption Application, and Hardware Implementation

Lin

Wang

et al. 2021

IEEE Trans. Ind. Electron.

100

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Polynomial functions have been the main barrier restricting the circuit realization and engineering application of multi-wing chaotic systems (MWCSs). To eliminate this bottleneck, we construct a simple MWCS without polynomial functions by introducing a sinusoidal function in a Sprott C system. Theoretical analysis and numerical simulations show that the MWCS can not only generate multi-butterfly attractors with an arbitrary number of butterflies, but also adjust the number of the butterflies by multiple ways including self-oscillating time, control parameters, and initial states. To further explore the advantage of the proposed MWCS, we realize its analog circuit using commercially available electronic elements. The results demonstrate that in comparison to traditional MWCSs, our circuit implementation greatly reduces the consumption of electronic components. This makes the MWCS more suitable for many chaos-based engineering applications. Furthermore, we propose an application of the MWCS to chaotic image encryption. Histogram, correlation, information entropy, and key sensitivity show that the simple image encryption scheme has high security and reliable encryption performance. Finally, we develop a field-programmable gate array (FPGA) test platform to implement the MWCS-based image cryptosystem. Both theoretical analysis and experimental results verify the feasibility and availability of the proposed MWCS.

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“…Now, it is the right time to recall a few interesting chaotic oscillators that utilize the method mentioned above and provide some unique features. Circuitry realization of the complex butterfly chaotic attractors having multiple wings can be found in [ 29 , 30 ], and a multiscroll strange attractor is implemented in an overview paper [ 31 ]. Here, curious reader can compare several design methods from different perspectives.…”

Section: Introductionmentioning

confidence: 99%

New Nonlinear Active Element Dedicated to Modeling Chaotic Dynamics with Complex Polynomial Vector Fields

Petržela

Šotner

2019

Entropy

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This paper describes evolution of new active element that is able to significantly simplify the design process of lumped chaotic oscillator, especially if the concept of analog computer or state space description is adopted. The major advantage of the proposed active device lies in the incorporation of two fundamental mathematical operations into a single five-port voltage-input current-output element: namely, differentiation and multiplication. The developed active device is verified inside three different synthesis scenarios: circuitry realization of a third-order cyclically symmetrical vector field, hyperchaotic system based on the Lorenz equations and fourth- and fifth-order hyperjerk function. Mentioned cases represent complicated vector fields that cannot be implemented without the necessity of utilizing many active elements. The captured oscilloscope screenshots are compared with numerically integrated trajectories to demonstrate good agreement between theory and measurement.

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A multi‐wing butterfly chaotic system and its implementation

Cited by 15 publications

References 31 publications

A New Memristor‐Based 5D Chaotic System and Circuit Implementation

A New Memristor‐Based 5D Chaotic System and Circuit Implementation

An Extremely Simple Multiwing Chaotic System: Dynamics Analysis, Encryption Application, and Hardware Implementation

New Nonlinear Active Element Dedicated to Modeling Chaotic Dynamics with Complex Polynomial Vector Fields

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