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Journal of Difference Equations and Applications Volume 29, 2023 - Issue 9-12: Special Issue of Journal of Difference Equations and Applications on ‘Lozi, Hénon, and other chaotic attractors, theory and applications’. Guest editors: René Lozi, Lyudmila Efremova, Mohammed-Salah Abdelouahab, Safwan El Assad and Michal Pluhacek
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Articles

K-symbol fractional order discrete-time models of Lozi system

Rabha W. IbrahimDepartment of Computer Science and Mathematics, Lebanese American University, Beirut, LebanonCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0001-9341-025X
ORCID Icon
Pages 1045-1064 | Received 27 Jul 2022, Accepted 03 Dec 2022, Published online: 21 Dec 2022

References

  • T. Abdeljawad, On Riemann and Caputo fractional differences, Comput. Math. Appl. 62(3) (2011), pp. 1602–1611.
  • I. Aldawish and R.W. Ibrahim, A new mathematical model of multi-faced COVID-19 formulated by fractional derivative chains, Adv. Contin. Discrete Models 2022(1) (2022), pp. 1–10.
  • M.H. AlSheikh, N.M. Al-Saidi, and R.W. Ibrahim, Dental X-ray identification system based on association rules extracted by k-Symbol fractional haar functions, Fractal Fract. 6(11) (2022), pp. 669.
  • F.M. Atici and P.W. Eloe, A transform method in discrete fractional calculus, Int. J. Differ. Equ. 2(2) (2007), pp. 165–176.
  • D. Baleanu, A. Jajarmi, S.S. Sajjadi, and J.H. Asad, The fractional features of a harmonic oscillator with position-dependent mass, Commun. Theor. Phys. 72(5) (2020), pp. 055002.
  • J Borcea, P. Branden, and T Liggett, Negative dependence and the geometry of polynomials, J. Am. Math. Soc. 22(2) (2009), pp. 521–567.
  • J.B. Diaz and T.J. Osler, Differences of fractional order, Math. Comput. 28(125) (1974), pp. 185–202.
  • R. Diaz and E. Pariguan, On hypergeometric functions and pochhammer K-symbol, Divulgaciones Mat. 15 (2007), pp. 179–192.
  • G.A. Dorrego and R.A. Cerutti, The k-fractional Hilfer derivative, Int. J. Math. Anal 7(11) (2013), pp. 543–550.
  • V.P. Dubey, R. Kumar, D. Kumar, I. Khan, and J. Singh, An efficient computational scheme for nonlinear time fractional systems of partial differential equations arising in physical sciences, Adv. Differ. Equ. 2020(1) (2020), pp. 1–27.
  • M.S. Fadhil, A.K. Farhan, M.N. Fadhil, and N.M.G. Al-Saidi, A new lightweight AES using a combination of chaotic systems, In 2020 1st. Information Technology to Enhance e-learning and Other Application IT-ELA, IEEE, 2020, pp. 82–88.
  • A.K. Farhan, A. Tariq, R.S. Ali, and N.M.G.. Alsaidi, A new pseudo random bits generator via 2D chaotic system, diffusion, and permeation, 2019.
  • D. Foukrach and B Meftah, Some new generalized result of Gronwall–Bellman–Bihari type inequality with some singularity, Filomat 34(10) (2020), pp. 3299–3310.
  • C. Goodrich and A.C. PetersonDiscrete Fractional Calculus, Vol.10, Springer, Cham, 2015.
  • S.B. Hadid and R.W. Ibrahim, Fractional dynamic system simulating the growth of microbe, Adv. Differ. Equ. 2021(1) (2021), pp. 1–15.
  • L.L. Huang, D. Baleanu, G.C. Wu, and S.D. Zeng, A new application of the fractional logistic map, 2016.
  • R.W. Ibrahim and D. Baleanu, Global stability of local fractional Henon–Lozi map using fixed point theory, AIMS Math. 7(6) (2022), pp. 11399–11416.
  • A. Jajarmi, M. Hajipour, E. Mohammadzadeh, and D. Baleanu, A new approach for the nonlinear fractional optimal control problems with external persistent disturbances, J. Franklin Inst. 355(9) (2018), pp. 3938–3967.
  • A.A. Khennaoui, A. Ouannas, S. Bendoukha, G. Grassi, R.P. Lozi, and V.T Pham, On fractional-order discrete-time systems: chaos, stabilization and synchronization, Chaos Soliton. Fractal. 119 (2019), pp. 150–162.
  • A.A Khennaoui, A. Ouannas, S. Bendoukha, X. Wang, and V.T. Pham, On chaos in the fractional-order discrete-time unified system and its control synchronization, Entropy 20(7) (2018), pp. 530.
  • X. Liu, F. Du, D. Anderson, and B. Jia, Monotonicity results for Nabla fractional h-difference operators, Math. Methods. Appl. Sci. 44(2) (2021), pp. 1207–1218.
  • R Lozi, A strange attractor of the Henon attractor type, J. Phys. Colloquia 39(C5) (1978), pp. C5–C9.
  • R Lyons, A note on tail triviality for determinantal point processes, Electron. Commun. Probab. 23 (2018), pp. 1–3.
  • C. Meshram, R.W. Ibrahim, A.J. Obaid, S.G. Meshram, A. Meshram, and A.M. Abd El-Latif, Fractional chaotic maps based short signature scheme under human-centered IoT environments, J. Adv. Res. 32 (2021), pp. 139–148.
  • D. Mozyrska and E. Girejko, Overview of fractional h-difference operators, In Advances in harmonic analysis and operator theory, Basel, Birkhauser, 2013, pp. 253–268.
  • S. Mubeen and G.M Habibullah, k-Fractional integrals and application, Int. J. Contemp. Math. Sci.7(2) (2012), pp. 89–94.
  • N.R. Ojeda and M.V Diaz, On fractional Laplace equation in plane polar and spherical coordinates, J. Fract. Calc. Appl. 13(2) (2022), pp. 116–125.
  • G. Rahman, K.S. Nisar, A. Ghaffar, and F. Qi, Some inequalities of the Gruss type for conformable k-fractional integral operators, Rev. La Real Acad. Ciencias Exact. Fisic. Natur. Ser. A. Mat. 114(1) (2020), pp. 1–9.
  • G. Rahman, K.S. Nisar, and S. Mubeen, On generalized k-fractional derivative operator. Preprints 2017, 2017120101 (doi:10.20944/preprints201712.0101.v1).
  • S.H. Salih and N.M. Al-Saidi, 3D-Chaotic discrete system of vector borne diseases using environment factor with deep analysis, AIMS Math. 7(3) (2022), pp. 3972–3987.
  • M.P. Velasco, D. Usero, S. Jimenez, L. Vazquez, J.L. Vazquez-Poletti, and M. Mortazavi, About some possible implementations of the fractional calculus, Mathematics 8(6) (2020), pp. 893.
  • G.C. Wu, D. Baleanu, H.P. Xie, and F.L. Chen, Chaos synchronization of fractional chaotic maps based on the stability condition, Phys. A: Stat. Mech. Appl. 460 (2016), pp. 374–383.
  • G.C. Wu and D. Baleanu, Discrete fractional logistic map and its chaos, Nonlinear. Dyn. 75(1) (2014), pp. 283–287.
  • S. Zhao, S.I. Butt, W. Nazeer, J. Nasir, M. Umar, and Y Liu, Some Hermite–Jensen–Mercer type inequalities for k-Caputo-fractional derivatives and related results, Adv. Differ. Equ. 2020(1) (2020), pp. 1–17.

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