Numerical analysis of a simplest fractional-order hyperchaotic system

Numerical analysis of a simplest fractional-order hyperchaotic system

In this paper, a simplest fractional-order hyperchaotic (SFOH) system is obtained when the fractional calculus is applied to the piecewise-linear hyperchaotic system, which possesses seven terms without any quadratic or higher-order polynomials. The numerical solution of the SFOH system is investiga...

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Main Authors: Dong Peng, Kehui Sun, Shaobo He, Limin Zhang, Abdulaziz O.A. Alamodi
Format: Article
Language:English
Published: Elsevier 2019-07-01
Series:Theoretical and Applied Mechanics Letters
Online Access:http://www.sciencedirect.com/science/article/pii/S209503491930039X
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spelling doaj-0d599535e4fd4614923b4eb8949f55012020-11-25T02:06:30ZengElsevierTheoretical and Applied Mechanics Letters2095-03492019-07-0194220228Numerical analysis of a simplest fractional-order hyperchaotic systemDong Peng0Kehui Sun1Shaobo He2Limin Zhang3Abdulaziz O.A. Alamodi4School of Physics and Electronics, Central South University, Changsha, Hunan 410083, ChinaCorresponding author; School of Physics and Electronics, Central South University, Changsha, Hunan 410083, ChinaSchool of Physics and Electronics, Central South University, Changsha, Hunan 410083, ChinaSchool of Physics and Electronics, Central South University, Changsha, Hunan 410083, ChinaSchool of Physics and Electronics, Central South University, Changsha, Hunan 410083, ChinaIn this paper, a simplest fractional-order hyperchaotic (SFOH) system is obtained when the fractional calculus is applied to the piecewise-linear hyperchaotic system, which possesses seven terms without any quadratic or higher-order polynomials. The numerical solution of the SFOH system is investigated based on the Adomian decomposition method (ADM). The methods of segmentation and replacement function are proposed to solve this system and analyze the dynamics. Dynamics of this system are demonstrated by means of phase portraits, bifurcation diagrams, Lyapunov exponent spectrum (LEs) and Poincaré section. The results show that the system has a wide chaotic range with order change, and large Lyapunov exponent when the order is very small, which indicates that the system has a good application prospect. Besides, the parameter a is a partial amplitude controller for the SFOH system. Finally, the system is successfully implemented by digital signal processor (DSP). It lays a foundation for the application of the SFOH system. Keywords: Chaos, Fractional calculus, Simplest fractional-order hyperchaotic system, Adomian decomposition method DSP implementationhttp://www.sciencedirect.com/science/article/pii/S209503491930039X
collection DOAJ
language English
format Article
sources DOAJ
author Dong Peng
Kehui Sun
Shaobo He
Limin Zhang
Abdulaziz O.A. Alamodi
spellingShingle Dong Peng
Kehui Sun
Shaobo He
Limin Zhang
Abdulaziz O.A. Alamodi
Numerical analysis of a simplest fractional-order hyperchaotic system
Theoretical and Applied Mechanics Letters
author_facet Dong Peng
Kehui Sun
Shaobo He
Limin Zhang
Abdulaziz O.A. Alamodi
author_sort Dong Peng
title Numerical analysis of a simplest fractional-order hyperchaotic system
title_short Numerical analysis of a simplest fractional-order hyperchaotic system
title_full Numerical analysis of a simplest fractional-order hyperchaotic system
title_fullStr Numerical analysis of a simplest fractional-order hyperchaotic system
title_full_unstemmed Numerical analysis of a simplest fractional-order hyperchaotic system
title_sort numerical analysis of a simplest fractional-order hyperchaotic system
publisher Elsevier
series Theoretical and Applied Mechanics Letters
issn 2095-0349
publishDate 2019-07-01
description In this paper, a simplest fractional-order hyperchaotic (SFOH) system is obtained when the fractional calculus is applied to the piecewise-linear hyperchaotic system, which possesses seven terms without any quadratic or higher-order polynomials. The numerical solution of the SFOH system is investigated based on the Adomian decomposition method (ADM). The methods of segmentation and replacement function are proposed to solve this system and analyze the dynamics. Dynamics of this system are demonstrated by means of phase portraits, bifurcation diagrams, Lyapunov exponent spectrum (LEs) and Poincaré section. The results show that the system has a wide chaotic range with order change, and large Lyapunov exponent when the order is very small, which indicates that the system has a good application prospect. Besides, the parameter a is a partial amplitude controller for the SFOH system. Finally, the system is successfully implemented by digital signal processor (DSP). It lays a foundation for the application of the SFOH system. Keywords: Chaos, Fractional calculus, Simplest fractional-order hyperchaotic system, Adomian decomposition method DSP implementation
url http://www.sciencedirect.com/science/article/pii/S209503491930039X
work_keys_str_mv AT dongpeng numericalanalysisofasimplestfractionalorderhyperchaoticsystem
AT kehuisun numericalanalysisofasimplestfractionalorderhyperchaoticsystem
AT shaobohe numericalanalysisofasimplestfractionalorderhyperchaoticsystem
AT liminzhang numericalanalysisofasimplestfractionalorderhyperchaoticsystem
AT abdulazizoaalamodi numericalanalysisofasimplestfractionalorderhyperchaoticsystem
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