Complexity analysis of chaotic sequence based on the intensive statistical complexity algorithm

Sun Ke-Hui; He Shao-Bo; Sheng Li-Yuan

doi:10.7498/aps.60.020505

Abstract

To analyze the complexity of the chaotic sequences, based on the intensive statistical complexity algorithm, the complexities of the discrete TD-ERCS and continuous simplified Lorenz chaotic systems were investigated respectively, and the complexities of the chaotic sequences with different system parameters were calculated. The complexities of pseudo-random sequences of the continuous chaotic systems disordered by m-series and chaotic pseudo-random sequences were analyzed. The results indicate that the intensive statistical complexity algorithm is an effective method for analyzing the complexity of the chaotic sequences, and the complexity of the discrete chaotic systems is larger than that of the continuous ones. However, after disordering by m-series or chaotic pseudo-random sequences, the complexities of the pseudo-random sequences can be increased significantly. This study provides a theoretical basis for the applications of chaotic sequences in the field of secure communication and information encryption.

Keywords:

intensive statistical complexity algorithm /
TD-ERCS /
simplified Lorenz system /
sequence disorder

Authors and contacts

1.
School of Physics Science and Technology, Central South University, Changsha 410083,China

References

[1]	Li M, Vitanyi P M B 1990 Amsterdam: Elsevier Science A 187
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[7]	Larrondo H A, González C M, Martin M T, Plastino A, Rosso O A 2005 Physica A 356 133
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Cited By

[1]	Li M, Vitanyi P M B 1990 Amsterdam: Elsevier Science A 187
[2]	Lempel A, Ziv J 1976 IEEE Trans IT-22 75
[3]	Steven M, Pincus S 1991 Mathematics 88 2297
[4]	Bandt C, Pompe B 2002 Phys. Rev. Lett. 88 174102
[5]	Sun K H, Tan G Q, Sheng L Y 2008 Acta Phys. Sin. 57 3359 (in Chinese) [孙克辉、谈国强、盛利元 2008 57 3359]
[6]	López-Ruiz R, Mancini H L, Calbet X 1995 Phys. Lett. A 209 321
[7]	Larrondo H A, González C M, Martin M T, Plastino A, Rosso O A 2005 Physica A 356 133
[8]	González C M, Larrondo H A, Rosso O A 2005 Physica A 354 281
[9]	Sheng L Y, Sun K H, Li C B 2004 Acta Phys. Sin. 53 2871 (in Chinese) [盛利元、孙克辉、李传兵 2004 53 2871]
[10]	Xiao F H, Yan G R, Han Y H 2004 Acta Phys. Sin. 53 2877 (in Chinese) [肖方红、阎桂荣、韩宇航 2004 53 2877]
[11]	Lü J H, Chen G R, Zhang S C, elikovsk Dy＇ S 2002 Int.J.Bifurc.Chaos 12 2917
[12]	Sun K H, Sprott J C 2009 J. Bifurcation and Chaos 19 1357
[13]	Wang L, Wang F P, Wang Z J 2006 Acta Phys. Sin. 55 3964 (in Chinese) [王蕾、汪芙平、王赞基 2006 55 3964]
[14]	Luo S J, Qiu S S, Chen X 2010 Journal of South China University of Technology 38 18 (in Chinese) [罗松江、丘水生、陈旭 2010 华南理工大学报 38 18] 〖15] Fan X Q 2009 Computer Engineering & Science 31 20 (in Chinese) [范雪琴 2009 计算机工程与科学 31 20]

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Catalog

Vol. 60, Issue 2 - 2011-01-20

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