Research Article
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Year 2023, Volume: 5 Issue: 2, 118 - 126, 31.07.2023
https://doi.org/10.51537/chaos.1223766

Abstract

References

  • Ablay, G., 2022 New 4d and 3d models of chaotic systems developed from the dynamic behavior of nuclear reactors. Chaos: An Interdisciplinary Journal of Nonlinear Science 32: 113108.
  • Bao, H., Z. Hua, N. Wang, L. Zhu, M. Chen, et al., 2020 Initialsboosted coexisting chaos in a 2-d sine map and its hardware implementation. IEEE Transactions on Industrial Informatics 17: 1132–1140.
  • Cetina-Denis, J. J., R. M. Lopéz-Gutiérrez, C. Cruz-Hernández, and A. Arellano-Delgado, 2022 Design of a chaotic trajectory generator algorithm for mobile robots. Applied Sciences 12: 2587.
  • Chunbiao, L., Y. Jiang, and M. Xu, 2021 On offset boosting in chaotic system. Chaos Theory and Applications 3: 47–54.
  • El-Latif, A. A. A., J. Ramadoss, B. Abd-El-Atty, H. S. Khalifa, and F. Nazarimehr, 2022 A novel chaos-based cryptography algorithm and its performance analysis. Mathematics 10: 2434.
  • Guo, H. andW. Liang, 2021 Existence of chaos for partial difference equations via tangent and cotangent functions. Advances in Difference Equations 2021: 1–15.
  • Hu, C., Q. Wang, X. Zhang, Z. Tian, and X. Wu, 2022a A new chaotic system with novel multiple shapes of two-channel attractors. Chaos, Solitons & Fractals 162: 112454.
  • Hu, X., B. Sang, and N. Wang, 2022b The chaotic mechanisms in some jerk systems. AIMS Mathematics 7: 15714–15740.
  • Hua, Z., B. Zhou, and Y. Zhou, 2018 Sine chaotification model for enhancing chaos and its hardware implementation. IEEE Transactions on Industrial Electronics 66: 1273–1284.
  • Joshi, M. and A. Ranjan, 2020 An autonomous simple chaotic jerk system with stable and unstable equilibria using reverse sine hyperbolic functions. International Journal of Bifurcation and Chaos 30: 2050070.
  • Kuate, P. D. K. and H. Fotsin, 2020 Complex dynamics induced by a sine nonlinearity in a five-term chaotic system: Fpga hardware design and synchronization. Chaos: An Interdisciplinary Journal of Nonlinear Science 30: 123107.
  • Kumar, A. and P. P. Singh, 2022 Synchronisation of unified chaotic systems using modified nonlinear active control: Circuit design, implementation, and secure communication. IETE Journal of Research pp. 1–17.
  • Lai, Q., A. Akgul, C. Li, G. Xu, and Ü. Çavu¸so˘ glu, 2017 A new chaotic system with multiple attractors: Dynamic analysis, circuit realization and s-box design. Entropy 20: 12.
  • Lai, Q., B. Bao, C. Chen, J. Kengne, and A. Akgul, 2021 Circuit application of chaotic systems: modeling, dynamical analysis and control.
  • Lai, Q., Z. Wan, and P. D. Kamdem Kuate, 2020 Modelling and circuit realisation of a new no-equilibrium chaotic system with hidden attractor and coexisting attractors. Electronics Letters 56: 1044–1046.
  • Li, L., A. El-Latif, A. Ahmed, S. Jafari, K. Rajagopal, et al., 2022a Multimedia cryptosystem for iot applications based on a novel chaotic system around a predefined manifold. Sensors 22: 334.
  • Li, S., Y. Wu, and G. Zheng, 2022b Adaptive synchronization for hyperchaotic liu system. Frontiers in Physics p. 745.
  • Lin, C.-H., G.-H. Hu, J.-S. Chen, J.-J. Yan, and K.-H. Tang, 2022 Novel design of cryptosystems for video/audio streaming via dynamic synchronized chaos-based random keys. Multimedia Systems 28: 1793–1808.
  • Liu, J., J. Clinton Sprott, S. Wang, and Y. Ma, 2018 Simplest chaotic system with a hyperbolic sine and its applications in dcsk scheme. IET Communications 12: 809–815.
  • Ma, C., J. Mou, L. Xiong, S. Banerjee, T. Liu, et al., 2021 Dynamical analysis of a new chaotic system: asymmetric multistability, offset boosting control and circuit realization. Nonlinear Dynamics 103: 2867–2880.
  • Mamia, S. B., W. Puech, and K. Bouallegue, 2022 Generation of chaotic attractors using neurons with multidentrites. International Journal of Modelling, Identification and Control 40: 92– 104.
  • Mobayen, S., C. Volos, Ü. Çavu¸so˘ glu, and S. S. Kaçar, 2020 A simple chaotic flow with hyperbolic sinusoidal function and its application to voice encryption. Symmetry 12: 2047.
  • Nwachioma, C. and J. H. Pérez-Cruz, 2021 Analysis of a new chaotic system, electronic realization and use in navigation of differential drive mobile robot. Chaos, Solitons & Fractals 144: 110684.
  • Pal, P., G. G. Jin, S. Bhakta, and V. Mukherjee, 2022 Adaptive chaos synchronization of an attitude control of satellite: A backstepping based sliding mode approach. Heliyon 8: e11730.
  • Pallav and H. Handa, 2022 Simple synchronization scheme for a class of nonlinear chaotic systems using a single input control. IETE Journal of Research pp. 1–14.
  • Rahman, Z.-A. S. and B. H. Jasim, 2022 Hidden dynamics investigation, fast adaptive synchronization, and chaos-based secure communication scheme of a new 3d fractional-order chaotic system. Inventions 7: 108.
  • Ramakrishnan, B., H. Natiq, K. Rajagopal, S. Jafari, and F. Nazarimehr, 2022 A novel megastable system: Cloud, kite, and arrow-like attractors and their dynamics. International Journal of Bifurcation and Chaos 32: 2250152.
  • Roldán-Caballero, A., J. H. Pérez-Cruz, E. Hernández-Márquez, J. R. García-Sánchez, M. Ponce-Silva, et al., 2023 Synchronization of a new chaotic system using adaptive control: Design and experimental implementation. Complexity 2023.
  • Sahoo, S. and B. K. Roy, 2022 Design of multi-wing chaotic systems with higher largest lyapunov exponent. Chaos, Solitons & Fractals 157: 111926.
  • Signing, V. F. and J. Kengne, 2018 Coexistence of hidden attractors, 2-torus and 3-torus in a new simple 4-d chaotic system with hyperbolic cosine nonlinearity. International Journal of Dynamics and Control 6: 1421–1428.
  • Signing, V. F., J. Kengne, and J. M. Pone, 2019 Antimonotonicity, chaos, quasi-periodicity and coexistence of hidden attractors in a new simple 4-d chaotic system with hyperbolic cosine nonlinearity. Chaos, Solitons & Fractals 118: 187–198.
  • Sriram, B., A. Ghaffari, K. Rajagopal, S. Jafari, and E. Tlelo-Cuautle, 2023 A chaotic map with trigonometric functions: Dynamical analysis and its application in image encryption based on sparse representation and convolutional filters. Optik 273: 170379.
  • Trujillo-Toledo, D., O. López-Bonilla, E. García-Guerrero, E. Tlelo- Cuautle, D. López-Mancilla, et al., 2021 Real-time rgb image encryption for iot applications using enhanced sequences from chaotic maps. Chaos, Solitons & Fractals 153: 111506.
  • Veeman, D., M. Mehrabbeik, H. Natiq, K. Rajagopal, S. Jafari, et al., 2022 A new chaotic system with coexisting attractors. International Journal of Bifurcation and Chaos 32: 2230007.
  • Volos, C., J.-O. Maaita, V.-T. Pham, and S. Jafari, 2021 Hidden attractors in a dynamical system with a sine function. Chaotic Systems with Multistability and Hidden Attractors pp. 459–487.
  • Wang, R., H. Sun, J.-Z. Wang, L. Wang, and Y.-C. Wang, 2015 Applications of modularized circuit designs in a new hyperchaotic system circuit implementation. Chinese Physics B 24: 020501.
  • Wen, J., Y. Feng, X. Tao, and Y. Cao, 2021 Dynamical analysis of a new chaotic system: Hidden attractor, coexisting-attractors, offset boosting, and dsp realization. Ieee Access 9: 167920–167927.
  • Yan, S., B. Gu, Y. Ren, X. Sun, and E.Wang, 2022 Dynamical analysis of four-dimensional chaotic system and its application in image encryption. Multimedia Tools and Applications pp. 1–26.
  • Yang, Y., L. Huang, J. Xiang, and Q. Guo, 2021 Three-dimensional sine chaotic system with multistability and multi-scroll attractor. IEEE Transactions on Circuits and Systems II: Express Briefs 69: 1792–1796.
  • Yu,W. and S. Gong, 2022 Chaotic system constructed by product trigonometric function and polynomial and applied to color image encryption. Modern Physics Letters B 36: 2150534.
  • Yu,W. and T. Yu, 2020 Analysis of chaotic characteristics of trigonometric function system. Modern Physics Letters B 34: 2050210.
  • Zhou, L. and F. Tan, 2019 A chaotic secure communication scheme based on synchronization of double-layered and multiple complex networks. Nonlinear Dynamics 96: 869–883.
  • Zhou, L., Z. You, and Y. Tang, 2021 A new chaotic system with nested coexisting multiple attractors and riddled basins. Chaos, Solitons & Fractals 148: 111057.
  • Zia, U., M. McCartney, B. Scotney, J. Martinez, M. AbuTair, et al., 2022 Survey on image encryption techniques using chaotic maps in spatial, transform and spatiotemporal domains. International Journal of Information Security 21: 917–935.

Design of a New Chaotic System with Sine Function: Dynamic Analysis and Offset Boosting Control

Year 2023, Volume: 5 Issue: 2, 118 - 126, 31.07.2023
https://doi.org/10.51537/chaos.1223766

Abstract

A new chaotic system is presented in this research work.The proposed system has three nonlinear terms and one sine term which improves the complexity of the system. The basic properties of new system such as Lyapunov exponent, equilibrium point and stability are analyzed in detail. The dynamic analysis is conducted using classic tools such as bifurcation diagram and Lyapunov exponent plot to verify the chaotic nature in the proposed system. The changes in the states of the system is verified using bifurcation diagram and Lyapunov exponent plot. The proposed system presents some special features such as two wing attractors, forward and reverse periodic doubling bifurcation, and dc offset boosting control. The dc offset boosting behavior can be used to diagnosis the multistability behaviour in the dynamical system and to reduce the number of components in the communication system. This special feature converts the bipolar signal in to unipolar signal which can be used in many engineering applications. The theoretical study and the simulation results show that the proposed system has wealthy chaotic behaviour itself. Furthermore, the adaptive synchronization of identical new system is achieved for the application of secure communication system.

References

  • Ablay, G., 2022 New 4d and 3d models of chaotic systems developed from the dynamic behavior of nuclear reactors. Chaos: An Interdisciplinary Journal of Nonlinear Science 32: 113108.
  • Bao, H., Z. Hua, N. Wang, L. Zhu, M. Chen, et al., 2020 Initialsboosted coexisting chaos in a 2-d sine map and its hardware implementation. IEEE Transactions on Industrial Informatics 17: 1132–1140.
  • Cetina-Denis, J. J., R. M. Lopéz-Gutiérrez, C. Cruz-Hernández, and A. Arellano-Delgado, 2022 Design of a chaotic trajectory generator algorithm for mobile robots. Applied Sciences 12: 2587.
  • Chunbiao, L., Y. Jiang, and M. Xu, 2021 On offset boosting in chaotic system. Chaos Theory and Applications 3: 47–54.
  • El-Latif, A. A. A., J. Ramadoss, B. Abd-El-Atty, H. S. Khalifa, and F. Nazarimehr, 2022 A novel chaos-based cryptography algorithm and its performance analysis. Mathematics 10: 2434.
  • Guo, H. andW. Liang, 2021 Existence of chaos for partial difference equations via tangent and cotangent functions. Advances in Difference Equations 2021: 1–15.
  • Hu, C., Q. Wang, X. Zhang, Z. Tian, and X. Wu, 2022a A new chaotic system with novel multiple shapes of two-channel attractors. Chaos, Solitons & Fractals 162: 112454.
  • Hu, X., B. Sang, and N. Wang, 2022b The chaotic mechanisms in some jerk systems. AIMS Mathematics 7: 15714–15740.
  • Hua, Z., B. Zhou, and Y. Zhou, 2018 Sine chaotification model for enhancing chaos and its hardware implementation. IEEE Transactions on Industrial Electronics 66: 1273–1284.
  • Joshi, M. and A. Ranjan, 2020 An autonomous simple chaotic jerk system with stable and unstable equilibria using reverse sine hyperbolic functions. International Journal of Bifurcation and Chaos 30: 2050070.
  • Kuate, P. D. K. and H. Fotsin, 2020 Complex dynamics induced by a sine nonlinearity in a five-term chaotic system: Fpga hardware design and synchronization. Chaos: An Interdisciplinary Journal of Nonlinear Science 30: 123107.
  • Kumar, A. and P. P. Singh, 2022 Synchronisation of unified chaotic systems using modified nonlinear active control: Circuit design, implementation, and secure communication. IETE Journal of Research pp. 1–17.
  • Lai, Q., A. Akgul, C. Li, G. Xu, and Ü. Çavu¸so˘ glu, 2017 A new chaotic system with multiple attractors: Dynamic analysis, circuit realization and s-box design. Entropy 20: 12.
  • Lai, Q., B. Bao, C. Chen, J. Kengne, and A. Akgul, 2021 Circuit application of chaotic systems: modeling, dynamical analysis and control.
  • Lai, Q., Z. Wan, and P. D. Kamdem Kuate, 2020 Modelling and circuit realisation of a new no-equilibrium chaotic system with hidden attractor and coexisting attractors. Electronics Letters 56: 1044–1046.
  • Li, L., A. El-Latif, A. Ahmed, S. Jafari, K. Rajagopal, et al., 2022a Multimedia cryptosystem for iot applications based on a novel chaotic system around a predefined manifold. Sensors 22: 334.
  • Li, S., Y. Wu, and G. Zheng, 2022b Adaptive synchronization for hyperchaotic liu system. Frontiers in Physics p. 745.
  • Lin, C.-H., G.-H. Hu, J.-S. Chen, J.-J. Yan, and K.-H. Tang, 2022 Novel design of cryptosystems for video/audio streaming via dynamic synchronized chaos-based random keys. Multimedia Systems 28: 1793–1808.
  • Liu, J., J. Clinton Sprott, S. Wang, and Y. Ma, 2018 Simplest chaotic system with a hyperbolic sine and its applications in dcsk scheme. IET Communications 12: 809–815.
  • Ma, C., J. Mou, L. Xiong, S. Banerjee, T. Liu, et al., 2021 Dynamical analysis of a new chaotic system: asymmetric multistability, offset boosting control and circuit realization. Nonlinear Dynamics 103: 2867–2880.
  • Mamia, S. B., W. Puech, and K. Bouallegue, 2022 Generation of chaotic attractors using neurons with multidentrites. International Journal of Modelling, Identification and Control 40: 92– 104.
  • Mobayen, S., C. Volos, Ü. Çavu¸so˘ glu, and S. S. Kaçar, 2020 A simple chaotic flow with hyperbolic sinusoidal function and its application to voice encryption. Symmetry 12: 2047.
  • Nwachioma, C. and J. H. Pérez-Cruz, 2021 Analysis of a new chaotic system, electronic realization and use in navigation of differential drive mobile robot. Chaos, Solitons & Fractals 144: 110684.
  • Pal, P., G. G. Jin, S. Bhakta, and V. Mukherjee, 2022 Adaptive chaos synchronization of an attitude control of satellite: A backstepping based sliding mode approach. Heliyon 8: e11730.
  • Pallav and H. Handa, 2022 Simple synchronization scheme for a class of nonlinear chaotic systems using a single input control. IETE Journal of Research pp. 1–14.
  • Rahman, Z.-A. S. and B. H. Jasim, 2022 Hidden dynamics investigation, fast adaptive synchronization, and chaos-based secure communication scheme of a new 3d fractional-order chaotic system. Inventions 7: 108.
  • Ramakrishnan, B., H. Natiq, K. Rajagopal, S. Jafari, and F. Nazarimehr, 2022 A novel megastable system: Cloud, kite, and arrow-like attractors and their dynamics. International Journal of Bifurcation and Chaos 32: 2250152.
  • Roldán-Caballero, A., J. H. Pérez-Cruz, E. Hernández-Márquez, J. R. García-Sánchez, M. Ponce-Silva, et al., 2023 Synchronization of a new chaotic system using adaptive control: Design and experimental implementation. Complexity 2023.
  • Sahoo, S. and B. K. Roy, 2022 Design of multi-wing chaotic systems with higher largest lyapunov exponent. Chaos, Solitons & Fractals 157: 111926.
  • Signing, V. F. and J. Kengne, 2018 Coexistence of hidden attractors, 2-torus and 3-torus in a new simple 4-d chaotic system with hyperbolic cosine nonlinearity. International Journal of Dynamics and Control 6: 1421–1428.
  • Signing, V. F., J. Kengne, and J. M. Pone, 2019 Antimonotonicity, chaos, quasi-periodicity and coexistence of hidden attractors in a new simple 4-d chaotic system with hyperbolic cosine nonlinearity. Chaos, Solitons & Fractals 118: 187–198.
  • Sriram, B., A. Ghaffari, K. Rajagopal, S. Jafari, and E. Tlelo-Cuautle, 2023 A chaotic map with trigonometric functions: Dynamical analysis and its application in image encryption based on sparse representation and convolutional filters. Optik 273: 170379.
  • Trujillo-Toledo, D., O. López-Bonilla, E. García-Guerrero, E. Tlelo- Cuautle, D. López-Mancilla, et al., 2021 Real-time rgb image encryption for iot applications using enhanced sequences from chaotic maps. Chaos, Solitons & Fractals 153: 111506.
  • Veeman, D., M. Mehrabbeik, H. Natiq, K. Rajagopal, S. Jafari, et al., 2022 A new chaotic system with coexisting attractors. International Journal of Bifurcation and Chaos 32: 2230007.
  • Volos, C., J.-O. Maaita, V.-T. Pham, and S. Jafari, 2021 Hidden attractors in a dynamical system with a sine function. Chaotic Systems with Multistability and Hidden Attractors pp. 459–487.
  • Wang, R., H. Sun, J.-Z. Wang, L. Wang, and Y.-C. Wang, 2015 Applications of modularized circuit designs in a new hyperchaotic system circuit implementation. Chinese Physics B 24: 020501.
  • Wen, J., Y. Feng, X. Tao, and Y. Cao, 2021 Dynamical analysis of a new chaotic system: Hidden attractor, coexisting-attractors, offset boosting, and dsp realization. Ieee Access 9: 167920–167927.
  • Yan, S., B. Gu, Y. Ren, X. Sun, and E.Wang, 2022 Dynamical analysis of four-dimensional chaotic system and its application in image encryption. Multimedia Tools and Applications pp. 1–26.
  • Yang, Y., L. Huang, J. Xiang, and Q. Guo, 2021 Three-dimensional sine chaotic system with multistability and multi-scroll attractor. IEEE Transactions on Circuits and Systems II: Express Briefs 69: 1792–1796.
  • Yu,W. and S. Gong, 2022 Chaotic system constructed by product trigonometric function and polynomial and applied to color image encryption. Modern Physics Letters B 36: 2150534.
  • Yu,W. and T. Yu, 2020 Analysis of chaotic characteristics of trigonometric function system. Modern Physics Letters B 34: 2050210.
  • Zhou, L. and F. Tan, 2019 A chaotic secure communication scheme based on synchronization of double-layered and multiple complex networks. Nonlinear Dynamics 96: 869–883.
  • Zhou, L., Z. You, and Y. Tang, 2021 A new chaotic system with nested coexisting multiple attractors and riddled basins. Chaos, Solitons & Fractals 148: 111057.
  • Zia, U., M. McCartney, B. Scotney, J. Martinez, M. AbuTair, et al., 2022 Survey on image encryption techniques using chaotic maps in spatial, transform and spatiotemporal domains. International Journal of Information Security 21: 917–935.
There are 44 citations in total.

Details

Primary Language English
Subjects Software Engineering (Other)
Journal Section Research Articles
Authors

Rameshbabu Ramar 0000-0002-6839-0346

Early Pub Date July 28, 2023
Publication Date July 31, 2023
Published in Issue Year 2023 Volume: 5 Issue: 2

Cite

APA Ramar, R. (2023). Design of a New Chaotic System with Sine Function: Dynamic Analysis and Offset Boosting Control. Chaos Theory and Applications, 5(2), 118-126. https://doi.org/10.51537/chaos.1223766

Chaos Theory and Applications in Applied Sciences and Engineering: An interdisciplinary journal of nonlinear science 23830 28903   

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