A new tool for energy security and secure energy communication
Year 2021,
Volume: 5 Issue: 4, 376 - 389, 31.12.2021
Erol Kurt
,
Batuhan Arpacı
Abstract
A recently proposed secure communication technique in Refs. [1,2,3] is initially applied to the energy sector. For this, especially the energy sector images which have a secret character for the companies and sectoral institutions have been ciphered and deciphered successfully. The applied tests have proven that the proposed method is fast and secure. The technique, itself, consists of a Kurt-modified Chua’s circuit (KMCC) for the generation of chaotic number sequences. The KMCC is a non-autonomous nonlinear circuit having hyper-chaotic character, thereby two positive Lyapunov exponents can easily make a strong ciphering action. The method is efficient for the images used in energy plants and networks. The algorithm created for the encryption/decryption uses a scrambling feature implemented at the bit level.
References
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Year 2021,
Volume: 5 Issue: 4, 376 - 389, 31.12.2021
Erol Kurt
,
Batuhan Arpacı
References
- [1] Arpacı, B, Kurt, E, Çelik, K. A new algorithm for the colored image encryption via the modified Chua’s circuit. Engineering Science and Technology, an International Journal 2020; 23(3): 595-604. DOI:10.1016/j.jestch.2019.09.001.
- [2] Arpacı, B, Kurt, E, Çelik, K. Ciylan, B., Colored image encryption and decryption with a new algorithm and a hyperchaotic electrical circuit. J. Electr. Eng. Technol. 2020; 15: 1413–1429. DOI: 10.1007/s42835-020-00393-x
- [3] Arpacı, B, Kurt, E. An Innovative Tool for the Chaotic Image Encryption, Decryption and Security Tests. In: ICECCE 2020 Int. Conf. Electr., Commun. Computer Engin.; 12-13 June 2020: IEEE, pp. 1-8. DOI: 10.1109/ICECCE49384.2020.9179274.
- [4] Alvarez, G, Li, S. Some basic cryptographic requirements for chaos-based cryptosystems. Int. J. Bif. Chaos 2006; 16(08): 2129-2151.
- [5] Kiraz, MS, Uzunkol, O. Efficient and verifiable algorithms for secure outsourcing of cryptographic computations. Int. J. Information Security 2016; 15(5): 519-537.
- [6] Stinson, DR. Cryptography: Theory and practice. CRC press. 2005
- [7] Zhu, ZL, Zhang, W, Wong, KW, Yu, H. A chaos-based symmetric image encryption scheme using a bit-level permutation. Information Sci. 2011; 181(6): 1171-1186.
- [8] Fu, C, Lin, BB, Miao, YS, Liu, X, Chen, JJ. A novel chaos-based bit-level permutation scheme for digital image encryption. Optics Commun.2011; 284(23): 5415-5423.
- [9] Wang, Y, Wong, KW, Liao, X, Xiang, T, Chen, G. A chaos-based image encryption algorithm with variable control parameters. Chaos, Sol. & Fractals 2009; 41(4): 1773-1783.
- [10] Guan, ZH, Huang, F, Guan, W. Chaos-based image encryption algorithm. Phys. Let. A 2005; 346(1-3): 153-157.
- [11] Xiao, D, Liao, X, Wei, P. Analysis and improvement of a chaos-based image encryption algorithm. Chaos, Sol. & Fractals 2009; 40(5): 2191-2199.
- [12] Kurt, E. Nonlinearities from a non-autonomous chaotic circuit with a non-autonomous model of Chua's diode. Physica Scripta 2006; 74(1): 22.
- [13] Liu, H, Wang, X, Kadir, A, Chaos-based color image encryption using one-time keys and Choquet fuzzy integral. Int. J. Nonlinear Sci. Numerical Sim. 2014; 15(1): 1-10.
- [14] Zhang, Y, Xiao, D. Self-adaptive permutation and combined global diffusion for chaotic color image encryption. AEU-Int. J. Electronics and Commun. 2014; 68(4): 361-368.
- [15] Seyedzadeh, S. M, Mirzakuchaki, S. A fast color image encryption algorithm based on coupled two-dimensional piecewise chaotic map. Signal Proces. 2012; 92(5): 1202-1215.
- [16] Wang, XY, Chen, F, Wang, T. A new compound mode of confusion and diffusion for block encryption of image based on chaos. Commun. Nonlinear Sci. Numerical Sim. 2021; 15(9): 2479-2485.
- [17] Mirzaei, O, Yaghoobi, M, Irani, H, A new image encryption method: parallel sub-image encryption with hyper chaos. Nonlinear Dyn. 2012; 67(1): 557-566, 2012.
- [18] Rhouma, R, Meherzi, S, Belghith, S. OCML-based colour image encryption. Chaos, Sol. & Fractals 2009; 40(1): 309-318.
- [19] Chai, X, Gan, Z, Zhang, M. A fast chaos-based image encryption scheme with a novel plain image-related swapping block permutation and block diffusion. Multimedia Tools and Applications 2017; 76(14): 15561-15585.