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级联混沌及其动力学特性研究

王光义 袁方

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级联混沌及其动力学特性研究

王光义, 袁方

Cascade chaos and its dynamic characteristics

Wang Guang-Yi, Yuan Fang
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  • 初值敏感性是混沌的本质,混沌的随机性来源于其对初始条件的高度敏感性, 而Lyapunov指数又是这种初值敏感性的一种度量.本文的研究发现, 混沌系统的级联可明显提高级联混沌的Lyapunov指数,改善其动力学特性. 因此,本文研究了混沌系统的级联和级联混沌对动力学特性的影响, 提出了混沌系统级联的定义及条件,从理论上证明了级联混沌的Lyapunov指数为 各个级联子系统Lyapunov指数之和;适当的级联可增加系统参数、扩展混沌映射和满映射的参数区间, 由此可提高混沌映射的初值敏感性和混沌伪随机序列的安全性. 以Logistic映射、Cubic映射和Tent映射为例,研究了Logistic-Logistic级联、 Logistic-Cubic级联和Logistic-Tent级联的动力学特性,验证了级联混沌动力学性能的改善. 级联混沌可作为伪随机数发生器的随机信号源,用以产生初值敏感性更高、安全性更好的伪随机序列.
    The dependence of sensitivity on initial conditions is the essence of chaos. And the randomness of chaos originates from the high sensitivity to initial values, which is measured by the Lyapunov exponents. It is found in this paper that the cascade of chaotic systems can considerably improve the Lyapunov exponents of cascade chaos and other dynamic properties. Therefore, in this paper, we study the cascade of chaotic systems and the influence on dynamic performances of the cascade chaos, and we present the definition and conditions of chaotic system cascade. It is proved in theory that the Lyapunov exponent of cascade chaos system is a sum of Lyapunov exponents of cascade subsystems. Appropriate cascade for chaotic systems can increase system parameters and expand parameter regions of chaos mapping and full mapping, thereby enhancing initial condition sensitivity of chaotic map and security of chaotic pseudo-random sequences. For logistic map, cubic map and tent map, the dynamic characteristics of logistic-logistic, logistic-cubic and logistic-tent cascade are investigated in detail, verifying the improvements on dynamic characteristics of cascade chaos systems. The proposed chaotic cascade system can be used to generate better pseudo-random sequences for initial condition sensitivity and security.
    • 基金项目: 国家自然科学基金(批准号: 60971046)资助的课题.
    • Funds: Project supported by the National Natural Science Foundation of China (Grant No. 60971046).
    [1]

    Lorenz E N 1993 The Essence of Chaos (Washington: The University of Washington Press) p25

    [2]

    Persohn K J, Povinelli R J 2012 Chaos, Solitons & Fractals 45 238

    [3]

    Chen S L, Hwang T T, Lin W W 2010 IEEE Trans. Circ. Syst.-II: Express Briefs 57 996

    [4]

    Jongsig Bae, Changha Hwang, Doobae Jun 2012 Statistics and Probability Letters 82 1021

    [5]

    Maier M P S, Peacock-López E 2010 Physics Letters A 374 1028

    [6]

    Sun K H, He S B, Yin L Z, A Di Li D L K 2012 Acta Phys. Sin. 61 130507 (in Chinese) [孙克辉, 贺少波, 尹林子, 阿地力·多力坤 2012 61 130507]

    [7]

    Narendra Singh, Aloka Sinha 2010 Optics and Lasers in Engineering 48 398

    [8]

    Martínez-Ñonthe J A, Castañeda-Solís A, Díaz-Méndez A, Cruz-Irisson M, Vázquez-Medina R 2012 Microelectronic Engineering 90 168

    [9]

    Jovic B, Unsworth C P 2010 Electronics Letters 46 1

    [10]

    Feng C F, Xu X J, Wu Z X Wang Y H 2008 Chinese Physics B 17 1674

    [11]

    Young R M B, Read P L 2008 Physica D 237 2251

    [12]

    Thomas Curtright, Andrzej Veitia 2011 Physics Letters A 375 276

    [13]

    Levinsohn E A, Mendoza S A, Peacock-López E 2012 Chaos, Solitons & Fractals 45 426

    [14]

    Wang X Y, Wang M J 2008 Acta Phys. Sin. 57 731 [王兴元, 王明军 2008 57 731]

    [15]

    Meng J D, Bao B C, Xu Q 2011 Acta Phys. Sin. 60 10504 [孟继德, 包伯成, 徐强 2011 60 10504]

    [16]

    Wang G Y, Yu J B, Gu T X 2011 Acta Phys. Sin. 50 2307 [王改云, 虞厥邦, 古天祥 2001 50 2307]

    [17]

    Bao B C, Kang Z S, Xu J P 2009 Acta Phys. Sin. 58 1420 [包伯成, 康祝圣, 许建平, 胡文 2009 58 1420]

    [18]

    Wei Y, Nan J, Tang G 2011 Czechoslovak Mathematical Journal 61 1023

    [19]

    Ben Futter, Viktor Avrutin, Michael Schanz 2012 Chaos, Solitons & Fractals 45 465

  • [1]

    Lorenz E N 1993 The Essence of Chaos (Washington: The University of Washington Press) p25

    [2]

    Persohn K J, Povinelli R J 2012 Chaos, Solitons & Fractals 45 238

    [3]

    Chen S L, Hwang T T, Lin W W 2010 IEEE Trans. Circ. Syst.-II: Express Briefs 57 996

    [4]

    Jongsig Bae, Changha Hwang, Doobae Jun 2012 Statistics and Probability Letters 82 1021

    [5]

    Maier M P S, Peacock-López E 2010 Physics Letters A 374 1028

    [6]

    Sun K H, He S B, Yin L Z, A Di Li D L K 2012 Acta Phys. Sin. 61 130507 (in Chinese) [孙克辉, 贺少波, 尹林子, 阿地力·多力坤 2012 61 130507]

    [7]

    Narendra Singh, Aloka Sinha 2010 Optics and Lasers in Engineering 48 398

    [8]

    Martínez-Ñonthe J A, Castañeda-Solís A, Díaz-Méndez A, Cruz-Irisson M, Vázquez-Medina R 2012 Microelectronic Engineering 90 168

    [9]

    Jovic B, Unsworth C P 2010 Electronics Letters 46 1

    [10]

    Feng C F, Xu X J, Wu Z X Wang Y H 2008 Chinese Physics B 17 1674

    [11]

    Young R M B, Read P L 2008 Physica D 237 2251

    [12]

    Thomas Curtright, Andrzej Veitia 2011 Physics Letters A 375 276

    [13]

    Levinsohn E A, Mendoza S A, Peacock-López E 2012 Chaos, Solitons & Fractals 45 426

    [14]

    Wang X Y, Wang M J 2008 Acta Phys. Sin. 57 731 [王兴元, 王明军 2008 57 731]

    [15]

    Meng J D, Bao B C, Xu Q 2011 Acta Phys. Sin. 60 10504 [孟继德, 包伯成, 徐强 2011 60 10504]

    [16]

    Wang G Y, Yu J B, Gu T X 2011 Acta Phys. Sin. 50 2307 [王改云, 虞厥邦, 古天祥 2001 50 2307]

    [17]

    Bao B C, Kang Z S, Xu J P 2009 Acta Phys. Sin. 58 1420 [包伯成, 康祝圣, 许建平, 胡文 2009 58 1420]

    [18]

    Wei Y, Nan J, Tang G 2011 Czechoslovak Mathematical Journal 61 1023

    [19]

    Ben Futter, Viktor Avrutin, Michael Schanz 2012 Chaos, Solitons & Fractals 45 465

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计量
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  • PDF下载量:  846
  • 被引次数: 0
出版历程
  • 收稿日期:  2012-07-21
  • 修回日期:  2012-08-18
  • 刊出日期:  2013-01-05

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