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分数阶忆阻Henon映射的可控多稳定性及其视频加密应用

张红伟 付常磊 潘志翔 丁大为 王金 杨宗立 刘涛

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Citation:

分数阶忆阻Henon映射的可控多稳定性及其视频加密应用

张红伟, 付常磊, 潘志翔, 丁大为, 王金, 杨宗立, 刘涛

Controllable multistability of fractional-order memristive Henon map and its application in video encryption

Zhang Hong-Wei, Fu Chang-Lei, Pan Zhi-Xiang, Ding Da-Wei, Wang Jin, Yang Zong-Li, Liu Tao
cstr: 32037.14.aps.73.20240942
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  • 基于局部有源离散忆阻器构建一种能够产生任意数量共存吸引子的分数阶忆阻Henon映射. 该映射的不动点数量由忆阻器内部参数控制, 实现可控的同质多稳定性, 适合基于混沌的工程应用. 通过相图、分岔图、最大Lyapunov指数和吸引盆等方法揭示该映射的复杂动力学行为. 数值模拟结果表明, 该分数阶映射能够产生各种周期轨道、混沌吸引子和倍周期分岔等现象. 随后使用ARM数字平台实现该系统, 实验结果验证其物理可实现性. 最后, 基于该映射设计一种视频加密算法, 并通过安全性分析验证该加密算法能够有效保证视频的安全传输.
    In recent years, the use of discrete memristors to enhance chaotic maps has received increasing attention. The introduction of memristors increases the complexity of chaotic maps, making them suitable for engineering applications based on chaotic systems. In this work, a fractional-order discrete memristor exhibiting local activity and controllable asymptotic stability points is constructed by using multiband nonlinear functions. The locally active property of this memristor is demonstrated by using the power-off plot and DC v - i plot. It is then introduced into the Henon map to construct a fractional-order memristive Henon map that can generate any number of coexisting attractors. Simulation results show that the number of fixed points in the system is controlled by the memristor parameters and related to the number of coexisting attractors, thus achieving controllable homogeneous multistability. The complex dynamical behaviors of this map are analyzed by using phase portraits, bifurcation diagrams, maximum Lyapunov exponent (MLE), and attractor basins. Numerical simulations show that the fractional-order map can generate various periodic orbits, chaotic attractors, and period-doubling bifurcations. The system is then implemented on an ARM digital platform. The experimental results are consistent with the simulation results, confirming the accuracy of the theoretical analysis and its physical feasibility. Finally, a parallel video encryption algorithm is designed by using the chaotic sequence iteratively generated by fraction-order memory Henon mapping, which mainly includes frame pixel scrambling and diffusion. Comprehensive security analyses are conducted, proving the robustness and reliability of the proposed encryption scheme. The results show that the encryption algorithm can effectively protect video information. In the future, we will explore other methods of constructing chaotic or hyperchaotic systems with controllable multistability and study their circuit implementation, synchronization control, and chaos-based engineering applications.
      通信作者: 丁大为, dwding@ahu.edu.cn
      Corresponding author: Ding Da-Wei, dwding@ahu.edu.cn
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  • 图 1  分数阶局部有源离散忆阻器的紧磁滞回线 (a) $ H = 1.0 $; (b) $ \omega = 0.001 $

    Fig. 1.  Pinched hysteresis loops of fractional-order locally active discrete memristor: (a) $ H = 1.0 $; (b) $ \omega = 0.001 $.

    图 2  分数阶局部有源离散忆阻器的POP (a) $ {I_1} = 0 $; (b) $ {I_2} = 0 $; (c) $ {I_1} = 1 $; (d) $ {I_2} = 1 $

    Fig. 2.  POP of fractional-order locally active discrete memristor: (a) $ {I_1} = 0 $; (b) $ {I_2} = 0 $; (c) $ {I_1} = 1 $; (d) $ {I_2} = 1 $.

    图 3  分数阶局部有源离散忆阻器的DC v - i

    Fig. 3.  DC v - i plot of fractional-order locally active discrete memristor.

    图 4  忆阻Henon映射的结构图

    Fig. 4.  Structure of memristive Henon map.

    图 5  分数阶忆阻Henon映射的不动点 (a) $ {I_1} = 0 $; (b) $ {I_2} = 0 $; (c) $ {I_1} = 1 $; (d) $ {I_2} = 1 $

    Fig. 5.  Fixed points of fractional-order memristive Henon map: (a) $ {I_1} = 0 $; (b) $ {I_2} = 0 $; (c) $ {I_1} = 1 $; (d) $ {I_2} = 1 $.

    图 6  分数阶忆阻Henon映射生成的共存吸引子 (a) $ {I_1} = 0 $; (b) $ {I_2} = 0 $; (c) $ {I_1} = 1 $; (d) $ {I_2} = 1 $

    Fig. 6.  Coexisting attractors generated by fractional-order memristive Henon map: (a) $ {I_1} = 0 $; (b) $ {I_2} = 0 $; (c) $ {I_1} = 1 $; (d) $ {I_2} = 1 $

    图 7  初始值$ z(1) $的分岔图 (a) $ {I_1} = 0 $; (b) $ {I_2} = 0 $; (c) $ {I_1} = 1 $; (d) $ {I_2} = 1 $

    Fig. 7.  Bifurcation diagrams of initial value $ z(1) $: (a) $ {I_1} = 0 $; (b) $ {I_2} = 0 $; (c) $ {I_1} = 1 $; (d) $ {I_2} = 1 $.

    图 8  $ x(1){\text{-}}z(1) $平面的吸引盆 (a) $ {I_1} = 0 $; (b) $ {I_2} = 0 $; (c) $ {I_1} = 1 $; (d) $ {I_2} = 1 $

    Fig. 8.  Attraction basins in $ x(1){\text{-}}z(1) $ plane : (a) $ {I_1} = 0 $; (b) $ {I_2} = 0 $; (c) $ {I_1} = 1 $; (d) $ {I_2} = 1 $.

    图 10  当$ q $取不同值时, 分数阶忆阻Henon映射产生的吸引子 (a) $ q = 0.75 $; (b) $ q = 0.83 $; (c) $ q = 0.935 $

    Fig. 10.  When $ q $ takes different values, the attractors generated by the fractional-order memristive Henon map: (a) $ q = 0.75 $; (b) $ q = 0.83 $; (c) $ q = 0.935 $.

    图 11  当$ k \in [ - 0.59, 2.09] $时, 分数阶忆阻Henon的动力学行为 (a)分岔图; (b) MLE

    Fig. 11.  When $ k \in [ - 0.59, 2.09] $, the dynamical behaviors of fractional-order memristive Henon map: (a) Bifurcation diagram; (b) MLE.

    图 12  当$ k $取不同值时, 分数阶忆阻Henon映射产生的吸引子 (a) $ k = - 0.5 $; (b) $ k = 0.1 $; (c) $ k = 0.88 $

    Fig. 12.  When $ k $ takes different values, the attractors generated by the fractional-order memristive Henon map: (a) $ k = - 0.5 $; (b) $ k = 0.1 $; (c) $ k = 0.88 $.

    图 13  硬件实现框架

    Fig. 13.  Framework of hardware implementation.

    图 9  当$ q \in [0.728, 1.15] $时, 分数阶忆阻Henon的动力学行为 (a)分岔图; (b) MLE

    Fig. 9.  When $ q \in [0.728, 1.15] $, the dynamical behaviors of fractional-order memristive Henon map: (a) Bifurcation diagram; (b) MLE.

    图 14  阶次$ q $取不同值时的硬件实现结果 (a)硬件连接图; (b) $ q = 0.75 $; (c) $ q = 0.935 $

    Fig. 14.  Results of hardware implementation for different values of order $ q $: (a) Hardware connection diagram; (b) $ q = $$ 0.75 $; (c) $ q = 0.935 $.

    图 15  视频加密方案的流程

    Fig. 15.  Flow of video encryption scheme.

    图 16  帧图像加密的流程

    Fig. 16.  Flow of frame image encryption.

    图 17  样本视频的加密和解密结果 (a) 原始News帧图像(第1, 91, 139, 186和300帧); (b)加密帧图像; (c)解密帧图像

    Fig. 17.  Encryption and decryption results of the sample videos: (a) Original News frame images (frames 1, 91, 139, 186 and 300); (b) encrypt frame images; (c) decrypt frame images.

    图 18  原始帧图像和加密帧图像的直方图(News第91帧) (a)原始帧图像; (b)加密帧图像

    Fig. 18.  Histograms of the original and encrypted frame image (News frame 91): (a) Original frame image; (b) encrypted frame image.

    图 19  (a)—(c)原始帧图像和(d)—(f)加密帧图像(News第91帧)在3个方向上的相关性 (a), (d)水平; (b), (e)垂直; (c), (f)对角线

    Fig. 19.  Correlation of the (a)–(c) original and (d)–(f) encrypted frame image (News frame 91) in three directions: (a), (d) Horizontal; (b), (e) vertical; (c), (f) diagonal.

    图 20  密钥敏感性分析(News第91帧) (a)使用正确密钥解密的帧图像; (b)使用错误密钥解密的帧图像($ y(1) = 0.5 + {10^{ - 16}} $); (c)使用错误密钥解密的帧图像($ q = 0.95 + {10^{ - 16}} $)

    Fig. 20.  Key sensitivity analysis (News frame 91): (a) Decrypted frame image with the correct key; (b) decrypted frame image with the wrong key ($ y(1) = 0.5 + {10^{ - 16}} $); (c) decrypted frame image with the wrong key ($ q = 0.95 + {10^{ - 16}} $).

    图 21  不同强度椒盐噪声攻击下的解密帧图像(News第91帧) (a) 10%; (b) 20%; (c) 30%

    Fig. 21.  Decrypted frame image (News frame 91) under salt and pepper noise attack with different noise intensities: (a) 10%; (b) 20%; (c) 30%.

    图 22  不同数据丢失强度下的加密帧图像和解密帧图像(News第91帧) (a), (d) 1/16; (b), (e) 1/4; (c), (f) 1/2

    Fig. 22.  Encrypted and decrypted frame image (News frame 91) under different data loss intensities: (a), (d) 1/16; (b), (e) 1/4; (c), (f) 1/2.

    表 1  原始帧图像和加密帧图像(News第91帧)在3个方向上的相关系数

    Table 1.  Correlation coefficients between the original frame image and the encrypted frame image (News frame 91) in three directions.

    图像 方向 R G B
    原始帧图像 水平 0.9536 0.9338 0.9408
    垂直 0.9718 0.9618 0.9658
    对角线 0.9346 0.9077 0.9173
    加密后的帧图像 水平 0.0001 –0.0066 –0.0031
    垂直 –0.0060 0.0014 –0.0001
    对角线 –0.0004 0.0012 –0.0034
    文献[45]加密帧图像 水平 0.0001 –0.0017 –0.0004
    垂直 –0.0008 0.0009 0.0011
    对角线 0.0001 0.0004 0.0007
    下载: 导出CSV

    表 2  原始帧图像和加密帧图像(News第91帧)的信息熵

    Table 2.  Information entropy of original frame image and encrypted frame image (News frame 91).

    R G B
    原始帧图像 7.2456 7.0573 6.9584
    加密后的帧图像 7.9980 7.9986 7.9985
    下载: 导出CSV

    表 3  与其他视频加密方案密钥空间的比较结果.

    Table 3.  Comparison of key spaces with other video encryption schemes.

    文献[37][45][32][46]本文
    密钥空间21972305232023842478
    下载: 导出CSV
    Baidu
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    Pratyusha N, Mandal S 2023 Circuits Syst. Signal Process. 42 3812Google Scholar

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    [33]

    Dolati N, Beheshti A, Azadegan H 2021 Multimed. Tools Appl. 80 2319Google Scholar

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    Tabash F K, Izharuddin M 2019 Multimed. Tools Appl. 78 7365Google Scholar

    [35]

    Karmakar J, Pathak A, Nandi D, Mandal M K 2021 Digit. Signal Prog. 117 103143Google Scholar

    [36]

    Liu S C, Li Y X, Ge X Z, Li C B, Zhao Y B 2022 Phys. Scr. 97 085210Google Scholar

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    Li X D, Yu H Y, Zhang H Y, Jin X, Sun H B, Liu J 2020 Multimed. Tools Appl. 79 23995Google Scholar

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    Liu T M, Mou J, Banerjee S, Cao Y H, Han X T 2021 Nonlinear Dyn. 106 1011Google Scholar

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出版历程
  • 收稿日期:  2024-07-08
  • 修回日期:  2024-08-12
  • 上网日期:  2024-08-20
  • 刊出日期:  2024-09-20

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