Abstract
A simple electronically tunable current-controlled chaotic Chua’s circuit using second-generation current-controlled current conveyor (CCCII) with 0.25 µm CMOS technology is presented. An electronically control behavior of nonlinear resistance (NR) produces significant change in voltage–current characteristics due to the bias current present in CCCII. The nature of the chaotic circuit in terms of different attractor can be achieved by controlling the variable resistor. The phase portraits of the proposed design are well simulated in PSPICE. The proposed circuit has several advantages viz. uses minimum number of passive components, low frequency operation, and tunable chaotic nature. Finally, a comparative study in terms of physical parameter is tabulated in this scientific literature.
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References
Vaidyanathan S, Volos C (2016) Advances and applications in Chaotic systems. Springer International Publishing Switzerland (2016)
Lorenz EN (1963) Deterministic non-periodic flow. J Atmos Sci 20:130–141
Rossler OE (1976) An equation for continuous chaos. Phy Lett 57A(5):130–141
Tamasevicius A et al (2001) Two-stage chaotic Colpitts oscillator. Electron Lett 37(9):549–551
Matsumoto T, Chua LO, Komuro M (1986) The double scroll bifurcations. Int J Circ Theory Appl 14(2):117–146
Cruz JM, Chua LO (1992) A CMOS IC nonlinear resistor for Chua’s circuit. IEEE Trans Circ Syst I Fundam Theor Appl 39(12):985–995
Kennedy M (1992) Robust Op-Amp realization of Chua’s circuit. Frequenz 46(10):66–80
Kapitaniak T, Chua LO, Zhang GQ (1994) Experimental hyperchaos in coupled chuas circuits. IEEE Tran Circ Syst 41:499–503
Senani R, Gupta SS (1998) Implementation of Chua’s chaotic circuit using current feedback op-amps. Electron Lett 34(9):829–830
Elwakil AS, Kennedy MP (2000) Improved implementation of Chua’s chaotic oscillator using current feedback op amp. IEEE Trans Circ Syst I Fundam Theor Appl 47:76–79
Torres LAB, Aguirre LA (2000) Inductorless Chua’ circuit. Electron Lett 36(23):1915–1916
Recai K (2003) A comparative study on realization of Chua’s circuit: hybrid realizations of Chua’s circuit combining the circuit topologies proposed for Chua’s diode and inductor elements. Int J Bifurcat Chaos 13(06):1475–1493
Gaurav G (2006) An improved Chua’s circuit and its use in hyperchaotic circuit. Anal Integr Circ Sig Process 46(2):173–178
Tlelo-Cuautle EA, Gaona-Hernández J (2006) Implementation of a chaotic oscillator by designing Chua’s diode with CMOS CFOAs. Analog Integr Circ Sig Process 48(2):159–162
Jothimurugan R et al (2014) Improved realization of canonical Chua’s circuit with synthetic inductor using current feedback operational amplifiers. Int J Electron Commun (AEÜ) 68:413–421
Kushwaha AK, Paul SK (2016) Chua’s oscillator using operational transresistance amplifier. Rev Roum des Sci Tech-Serie Electrotechnique et Energetique 61(3):299–303
Kushwaha AK, Paul SK (2016) Inductorless realization of Chua’s oscillator using DVCCTA. Analog Integr Circ Sig Process 8(1):137–150
Recai K, Yildirim F (2008) A survey of Wien bridge-based chaotic oscillators: design and experimental issues. Chaos Solitons Fractals 38:1394–1410
Tamaseviius A, Lindberg E, Kirvaitis R (2009) Autonomous Duffing-Holmes type Chaotic oscillator. Elektron ir Elektrotechnika 5:43–46
Tamaseviius A et al (2009) Autonomous Duffing-Holmes type chaotic oscillator. Electron Electr Eng 5(93):43–46
Piper JR, Sprott JC (2010) Simple autonomous chaotic circuits. IEEE Trans Circ Syst II Express Briefs 57:730–734
Sprott JC (2011) New chaotic jerk circuit. IEEE Trans Circ Syst II Express Briefs 58(4):240–243
Srisuchinwong B, Liou CH (2007) Improved implementation of Sprott’s chaotic oscillators based on current-feedback Op Amps. In: Proceedings of the Electrical Engineering./Electronics. Computer, telecommunications and information technology (ECTI-CON 2007), pp 38–40. ECTI-CON 2007
Joshi M, Ranjan A (2019) An autonomous chaotic and hyperchaotic oscillator using OTRA. Analog Integr Circ Signal Process 101:401–413
Joshi M, Ranjan A (2019) New simple chaotic and hyperchaotic system with an unstable node. AEU Int J Electron Commun 108:1–9
Joshi M, Ranjan A (2019) Realization of novel multi-scroll 2D chaotic oscillator using DVCC. In: Mishra S, Sood Y, Tomar A (eds) Applications of computing, automation and wireless systems in electrical engineering, vol 553. Lecture notes in electrical engineering. Springer, Singapore, pp 1093–1101
Fabre A, Saaid O, Wiest F, Baucheron C (1996) High frequency applications based on a new current controlled conveyor. IEEE Trans Circ Syst I 43(2):82–90
Ranjan A, Paul SK (2011) Nth order voltage mode active-C filter employing current controlled current conveyor. Circ Syst 2(2):85–90
Pandey N, Paul SK, Jain SB (2009) A new electronically tunable current mode universal filter using MO-CCCII. Analog Integr Circ Signal Process 58(2):171–178
Pandey N, Paul SK (2008) A novel electronically tunable sinusoidal oscillator based on CCCII (-IR). J Active Passive Electron Devices 3(2):135–141
Faseehuddin M, Sampe J, Islam S (2016) Schmitt Trigger based on dual output current controlled current conveyor in 16 nm CMOS technology for digital applications. In: Proceedings of IEEE-ICSE 2016, Kuala Lumpur, Malaysia
Joshi M, Ranjan A (2017) Realization of Colpitts oscillator using second generation current controlled current conveyor. In: Proceedings of the second international conference on research in intelligent and computing in engineering, vol 10, pp 49–52
Agrawal D, Maheshwari S (2017) Current mode filters with reduced complexity using a single EX-CCCII. Int J Electron Commun 1–19)
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Joshi, M., Ranjan, A. (2021). Current-Controlled Chaotic Chua’s Circuit Using CCCII. In: Hura, G.S., Singh, A.K., Siong Hoe, L. (eds) Advances in Communication and Computational Technology. ICACCT 2019. Lecture Notes in Electrical Engineering, vol 668. Springer, Singapore. https://doi.org/10.1007/978-981-15-5341-7_41
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DOI: https://doi.org/10.1007/978-981-15-5341-7_41
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