Analysis and electronic circuit implementation of an integer-and fractional-order Shimizu-Morioka system

• F.Kapche Tagne ^[1] ; G.Honoré Kom ^[1] ; M.Motchongom Tingue ^[2] ; V.Kamdoum Tamba ^[1] ; P.Kisito Talla ^[1]
  1. [1] Universite De Dschang

     Universite De Dschang

     Camerún

     
  2. [2] University of Bamenda

     University of Bamenda

     Camerún

     
• Localización: Revista Mexicana de Física, ISSN-e 0035-001X, Vol. 67, Nº. 6, 2021, págs. 961-971
• Idioma: inglés
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• Resumen

  • The dynamics of an integer-order and fractional-order Lorenz-like system called Shimizu-Morioka system is investigated in this paper. It is shown that the integer-order Shimizu-Morioka system displays monostable and bistable chaotic attractors, as well as their coexistence. For a suitable choice of parameters, the fractional-order Shimizu-Morioka system exhibits bistable chaotic attractors, monostable chaotic attractors, metastable chaos (i.e. transient chaos) and spiking oscillations. The bifurcation structures reveal that the fractional-order derivative affects considerably the dynamics of the system. The chain fractance circuit is used to design and implement the integer- and fractional-order Shimizu-Morioka system in PSpice. A close agreement is observed between PSpice based circuit simulations and numerical simulations analysis. The results obtained in this work were not reported previously in the interger as well as in fractional-order Shimizu-Morioka system and thus represent an important contribution which may help us in better understanding of the dynamical behavior of this class of systems.