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Erschienen in:
Bifurcation Analysis and Chaotic Behaviors of Fractional-Order Singular Biological Systems Kapitel lesen Erstes Kapitel lesen

2018 | OriginalPaper | Buchkapitel

Synchronization Phenomena in Coupled Dynamical Systems with Hidden Attractors

verfasst von : C. K. Volos, Viet-Thanh Pham, Ahmad Taher Azar, I. N. Stouboulos, I. M. Kyprianidis

Erschienen in: Nonlinear Dynamical Systems with Self-Excited and Hidden Attractors

Verlag: Springer International Publishing

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Abstract

Recently, Leonov and Kuznetsov introduced a new class of nonlinear dynamical systems, which is called systems with hidden attractors, in contrary to the well-known class of systems with self-excited attractors. In this class, dynamical systems with infinite number of equilibrium points, with stable equilibria, or without equilibrium are classified. Since then, the study of chaotic systems with hidden attractors has become an attractive research topic because this new class of dynamical systems could play an important role not only in theoretical problems but also in engineering applications. In this direction, the proposed chapter presents the bidirectional and unidirectional coupling schemes between two identical dynamical chaotic systems with no-equilibrium points. As it is observed, when the value of the coupling coefficient is increased in both coupling schemes, the coupled systems undergo a transition from desynchronization mode to complete synchronization. Also, the simulation results reveal the richness of the coupled system’s dynamical behavior, especially in the bidirectional case, showing interesting nonlinear dynamics, with a transition between periodic, quasiperiodic and chaotic behavior as the coupling coefficient increases, as well as synchronization phenomena, such as complete and anti-phase synchronization. Various tools of nonlinear theory for the study of the proposed coupling method, such as bifurcation diagrams, phase portraits and Lyapunov exponents have been used.

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Vorheriges Kapitel A Six-Term Novel Chaotic System with Hidden Attractor and Its Circuit Design
Nächstes Kapitel 4-D Memristive Chaotic System with Different Families of Hidden Attractors
Literatur
Alvarez G, Li S (2006) Some basic cryptographic requirements for chaos-based cryptosystems. Int J Bifurcat Chaos 16(08):2129–2151MathSciNetMATHCrossRef
Annovazzi-Lodi V, Donati S, Sciré A (1997) Synchronization of chaotic lasers by optical feedback for cryptographic applications. IEEE J Quant Electron 33(9):1449–1454CrossRef
Astakhov V, Hasler M, Kapitaniak T, Shabunin A, Anishchenko V (1998) Effect of parameter mismatch on the mechanisms of chaos synchronization loss in coupled systems. Phys Rev E 58:5620–5628CrossRef
Astakhov V, Shabunin A, Anishchenko V (2000) Antiphase synchronization in symmetrically coupled self-oscillators. Int J Bifurcat Chaos 10:849–857
Azar AT, Vaidyanathan S (2015a) Chaos modeling and control systems design, studies in computational intelligence, vol 581. Springer, GermanyMATH
Azar AT, Vaidyanathan S (2015b) Handbook of research on advanced intelligent control engineering and automation. Advances in computational intelligence and robotics (ACIR), Book Series. IGI Global, USA
Azar AT, Vaidyanathan S (2015c) Computational intelligence applications in modeling and control. In: Studies in computational intelligence, vol 575. Springer, Germany
Azar AT, Vaidyanathan S (2016) Advances in chaos theory and intelligent control. In: Studies in fuzziness and soft computing, vol 337. Springer, Germany
Azar AT, Vaidyanathan S, Ouannas A (2017a) Fractional order control and synchronization of chaotic systems. In: Studies in computational intelligence, vol 688. Springer, Germany
Azar AT, Volos C, Gerodimos NA, Tombras GS, Pham VT, Radwan AG, Vaidyanathan S, Ouannas A, Munoz-Pacheco JM (2017b) A novel chaotic system without equilibrium: dynamics, synchronization and circuit realization. Complexity, 2017: Article ID 7871467, 11 pages. https://​doi.​org/​10.​1155/​2017/​7871467
Banerjee S (2010) Chaos synchronization and cryptography for secure communications: applications for encryption: applications for encryption. IGI Global, USA
Bautin NN (1939) On the number of limit cycles generated on varying the coefficients from a focus or centre type equilibrium state. Dokl Akad Nauk SSSR 24:668–671MathSciNet
Bautin NN (1952) On the number of limit cycles appearing on varying the coefficients from a focus or centre type of equilibrium state. Mat Sb (N.S.) 30:181–196
Bernat J, Llibre J (1996) Counter example to Kalman and Markus-Yamabe conjectures in dimension larger than 3. Dyn Contin Discret Impul Syst 2:337–379MATH
Blazejczuk-Okolewska B, Brindley J, Czolczynski K, Kapitaniak T (2001) Antiphase synchronization of chaos by noncontinuous coupling: two impacting oscillators. Chaos Solit Fract 2:1823–1826MATHCrossRef
Boulkroune A, Bouzeriba A, Bouden T, Azar AT (2016a). Fuzzy adaptive synchronization of uncertain fractional-order chaotic systems. In: Studies in fuzziness and soft computing, vol 337, pp 681–697. Springer, Germany
Boulkroune A, Hamel S, Azar AT (2016b). Fuzzy control-based function synchronization of unknown chaotic systems with dead-zone input. In: Studies in fuzziness and soft computing, vol 337, pp 699–718. Springer, Germany
Cao LY, Lai YC (1998) Antiphase synchronism in chaotic system. Phys Rev 58:382–386
Chua LO, Kocarev L, Eckert K, Itoh M (1992) Experimental chaos synchronization in Chua’s crcuit. Int J Bifurcat Chaos 2:705–708MATHCrossRef
Cuomo KM, Oppenheim AV, Strogatz SH (1993) Synchronization of Lorenz-based chaotic circuits with applications to communications. IEEE Trans Circuits Syst II Analog Digit Signal 40(10):626–633CrossRef
Dachselt F, Schwarz W (2001) Chaos and cryptography. IEEE Trans Circuits Syst I Fundam Theory, 48(12):1498–1509
Dimitriev AS, Kletsovi AV, Laktushkin AM, Panas AI, Starkov SO (2006) Ultrawideband wireless communications based on dynamic chaos. J Commun Technol Electron 51:1126–1140CrossRef
Dykman GI, Landa PS, Neymark YI (1991) Synchronizing the chaotic oscillations by external force. Chaos Solit Fract 1:339–353MATHCrossRef
Feki M, Robert B, Gelle G, Colas M (2003) Secure digital communication using discrete-time chaos synchronization. Chaos Solit Fract 18(4):881–890MathSciNetMATHCrossRef
Fitts RE (1966) Two counter examples to Aizerman’s conjecture. Trans IEEE, AC-11:553–556
Fujisaka H, Yamada T (1983) Stability theory of synchronized motion in coupled-oscillator systems. Prog Theor Phys 69:32–47MathSciNetMATHCrossRef
Gonzalez-Miranda JM (2004) Synchronization and control of chaos. Imperial College Press, LondonCrossRef
Gotthans T, Petržela J (2015) New class of chaotic systems with circular equilibrium. Nonlinear Dyn 73:429–436MathSciNet
Gotthans T, Sportt JC, Petržela J (2016) Simple chaotic flow with circle and square equilibrium. Int J Bifurcat Chaos 26(1650):137–138MathSciNetMATH
Grassi G, Mascolo S (1999) Synchronization of high-order oscillators by observer design with application to hyperchaos-based cryptography. Int J Circuit Theor Appl 27:543–553MATHCrossRef
Gubar’ NA (1961) Investigation of a piecewise linear dynamical system with three parameters. J Appl Math Mech, 25:1011–1023
Holstein-Rathlou NH, Yip KP, Sosnovtseva OV, Mosekilde E (2001) Synchronization phenomena in nephron-nephron interaction. Chaos 11:417–426MATHCrossRef
Hoover W (1985) Canonical dynamics: equilibrium phase-space distributions. Phys Rev A 31:1695CrossRef
Jafari S, Haeri M, Tavazoei MS (2010) Experimental study of a chaos-based communication system in the presence of unknown transmission delay. Int J Circuit Theor Appl 38:1013–1025MATHCrossRef
Jafari S, Sprott J, Golpayegani SMRH (2013) Elementary quadratic chaotic flows with no equilibria. Phys Lett A 377:699–702MathSciNetCrossRef
Kalman RE (1957) Physical and mathematical mechanisms of instability in nonlinear automatic control systems. Trans ASME 79:553–566MathSciNet
Kapranov M (1956) Locking band for phase-locked loop. Radiofizika 2:37–52
Kingni ST, Jafari S, Simo H, Woafo P (2014) Three-dimensional chaotic autonomous system with only one stable equilibrium: Analysis, circuit design, parameter estimation, control, synchronization and its fractional-order form. Eur Phys J Plus 129:76CrossRef
Klein E, Mislovaty R, Kanter I, Kinzel W (2005) Public-channel cryptography using chaos synchronization. Phys Rev E 72(1):016214CrossRef
Kocarev L, Halle KS, Eckert K, Chua LO, Parlitz U (1992) Experimental demonstration of secure communications via chaotic synchronization. Int J Bifurcat Chaos 2(03):709–713MATHCrossRef
Kuznetsov NV, Leonov GA, Vagaitsev VI (2010) Analytical-numerical method for attractor localization of generalized Chua’s system. IFAC Proc 4(1):29–33CrossRef
Kyprianidis IM, Stouboulos IN (2003a) Synchronization of two resistively coupled nonautonomous and hyperchaotic oscillators. Chaos Solit Fract 17:314–325MATH
Kyprianidis IM, Stouboulos IN (2003b) Synchronization of three coupled oscillators with ring connection. Chaos Solit Fract 17:327–336MATHCrossRef
Kyprianidis IM, Volos ChK, Stouboulos IN (2005) Suppression of chaos by linear resistive coupling. WSEAS Trans Circuits Syst 4:527–534
Kyprianidis IM, Volos ChK, Stouboulos IN, Hadjidemetriou J (2006a) Dynamics of two resistively coupled Duffing-type electrical oscillators. Int J Bifurcat Chaos 16:1765–1775MathSciNetMATHCrossRef
Kyprianidis IM, Bogiatzi AN, Papadopoulou M, Stouboulos IN, Bogiatzis GN, Bountis T (2006b) Synchronizing chaotic attractors of Chua’s canonical circuit. The case of uncertainty in chaos synchronization. Int J Bifurcat Chaos 16:1961–1976MATHCrossRef
Kyprianidis IM, Volos CK, Stouboulos IN (2008) Experimental synchronization of two resistively coupled Duffing-type circuits. Nonlin Phenom Complex Syst 11:187–192
Lauvdal T, Murray R, Fossen T (1997) Stabilization of integrator chains in the presence of magnitude and rate saturations: a gain scheduling approach. IEEE Control Decis Conf, 4004–4005
Lao SK, Shekofteh Y, Jafari S, Sprott JC (2014) Cost function based on Gaussian mixture model for parameter estimation of a chaotic circuit with a hidden attractor. Int J Bifurcat Chaos 24(1450):010MathSciNetMATH
Leonov G, Kuznetsov N, Kuznetsova O, Seldedzhi S, Vagaitsev V (2011b) Hidden oscillations in dynamical systems. Trans Syst Control 6:54–67
Leonov G, Kuznetsov NV (2013) Analytical-numerical methods for hidden attractors’ localization: the 16th Hilbert problem, Aizerman and Kalman conjectures, and Chua circuits. In: Numerical methods for differential equations, optimization, and technological problems, computational methods in applied sciences, vol 27, pp 41–64. Springer
Li GH (2009) Inverse lag synchronization in chaotic systems. Chaos Solit Fract 40:1076–1080MATHCrossRef
Liu W, Qian X, Yang J, Xiao J (2006) Antisynchronization in coupled chaotic oscillators. Phys Lett A 354:119–125CrossRef
Liu X, Chen T (2010) Synchronization of identical neural networks and other systems with an adaptive coupling strength. Int J Circ Theor Appl 38:631–648MATH
Maaita JO, Volos CK, Stouboulos IN, Kyprianidis IM (2015) The dynamics of a cubic nonlinear system with no equilibrium point. J Nonlinear Dyn 2015:257923MATH
Mainieri R, Rehacek J (1999) Projective synchronization in three-dimensional chaotic system. Phys Rev Lett 82:3042–3045CrossRef
Maritan A, Banavar J (1994) Chaos noise and synchronization. Phys Rev Lett 72:1451–1454CrossRef
Markus L, Yamabe H (1960) Global stability criteria for differential systems. Osaka Math J 12:305–317MathSciNetMATH
Molaie M, Jafari S, Sprott JC, Golpayegani SMRH (2013) Simple chaotic flows with one stable equilibrium. Int J Bifurcat Chaos 23:1350MathSciNetMATHCrossRef
Mosekilde E, Maistrenko Y, Postnov D (2002) Chaotic synchronization: applications to living systems. World Scientific, SingaporeMATHCrossRef
Nosé S (1984) A molecular dynamics method for simulations in the canonical ensemble. Mol Phys 52:255–268CrossRef
Ouannas A, Azar AT, Radwan AG (2016b) On inverse problem of generalized synchronization between different dimensional integer-order and fractional-order chaotic systems. In: The 28th International Conference on Microelectronics, December 17–20, 2016. Cairo, Egypt
Ouannas A, Azar AT, Vaidyanathan S (2017a) On a simple approach for Q-S synchronization of chaotic dynamical systems in continuous-time. Int J Comput Sci Math 8(1):20–27MathSciNetCrossRef
Ouannas A, Azar AT, Vaidyanathan S (2017b) New hybrid synchronization schemes based on coexistence of various types of synchronization between master-slave hyperchaotic systems. Int J Comput Appl Technol 55(2):112–120CrossRef
Ouannas A, Azar AT, Ziar T, Vaidyanathan S (2017d) On new fractional inverse matrix projective synchronization schemes. In: Studies in computational intelligence, vol 688, pp 497–524. Springer, Germany
Ouannas A, Azar AT, Ziar T, Vaidyanathan S (2017e) Fractional inverse generalized chaos synchronization between different dimensional systems. In: Studies in computational intelligence, vol 688, pp 525–551. Springer, Germany
Ouannas A, Azar AT, Ziar T, Vaidyanathan S (2017f) A new method to synchronize fractional chaotic systems with different dimensions. In: Studies in computational intelligence, vol 688, pp 581–611. Springer, Germany
Ouannas A, Azar AT, Ziar T, Radwan AG (2017g) Study on coexistence of different types of synchronization between different dimensional fractional chaotic systems. In: Studies in computational intelligence, vol 688, pp 637–669. Springer, Germany
Ouannas A, Azar AT, Ziar T, Radwan AG (2017h) Generalized synchronization of different dimensional integer-order and fractional order chaotic systems. In: Studies in computational intelligence, vol 688, pp 671–697. Springer, Germany
Ouannas A, Azar AT, Vaidyanathan S (2017i) A robust method for new fractional hybrid chaos synchronization. Math Methods Appl Sci 40(5):1804–1812MathSciNetMATHCrossRef
Ouannas A, Azar AT, Vaidyanathan S (2017k) A new fractional hybrid chaos synchronization. Int J Model Identif Control, 27(4):314–322
Parlitz U, Junge L, Lauterborn W, Kocarev L (1996) Experimental observation of phase synchronization. Phys Rev E 54:2115–2217CrossRef
Pham V-T, Volos CK, Jafari S, Wang X, Vaidyanathan S (2014a) Hidden hyperchaotic attractor in a novel simple memristive neural network. J Optoelectron Adv Mater Rapid Commun 8(11–12):1157–1163
Pham V-T, Jafari S, Volos CK, Wang X, Syed Golpayegani MRH (2014b) Is that really hidden? The presence of complex fixed-points in chaotic flows with no equilibria. Int J Bifurcat Chaos, 24(11):1450146
Pham VT, Volos C, Jafari S, Wei Z, Wang X (2014c) Constructing a novel no-equilibrium chaotic system. Int J Bifurcat Chaos 24(05):1450073MathSciNetMATHCrossRef
Pham V-T, Vaidyanathan S, Volos CK, Jafari S (2016a) A no-equilibrium hyperchaotic system with a cubic nonlinear term. Optik 127:3259–3265CrossRef
Pham V-T, Vaidyanathan S, Volos CK, Jafari S, Kuznetsov NV, Hoang TM (2016b) A novel memristive time-delay chaotic system without equilibrium points. Eur Phys J Special Topics 225:127–136CrossRef
Pham VT, Jafari S, Wang X, Ma J (2016c) A chaotic system with different shapes of equilibria. Int J Bifurcat Chaos 26:1650069MathSciNetMATHCrossRef
Pham V-T, Jafari S, Volos C, Giakoumis A, Vaidyanathan S, Kapitaniak T (2016d) A chaotic system with equilibria located on the rounded square loop and its circuit implementation. IEEE Trans Circuits Syst II Express Briefs 63(9):878–882CrossRef
Pham V-T, Jafari S, Volos C, Vaidyanathan S, Kapitaniak T (2016e) A chaotic system with infinite equilibria located on a piecewise linear curve. Optik 127:9111–9117CrossRef
Pham V-T, Volos C, Kapitaniak T (2017a) Systems with hidden attractors: from theory to realization in circuits. Springer, SwitzerlandMATHCrossRef
Pham V-T, Jafari S, Kapitaniak T, Volos C, Kingni ST (2017b) Generating a chaotic system with one stable equilibrium. Int J Bifurcat Chaos 27(4):1750053MathSciNetMATHCrossRef
Pham VT, Vaidyanathan S, Volos CK, Azar AT, Hoang TM, Yem VV (2017c) A three-dimensional no-equilibrium chaotic system: analysis, synchronization and its fractional order form. In: Studies in computational intelligence, vol 688, pp 449–470. Springer, Germany
Pham VT, Volos CK, Vaidyanathan S, Azar AT (2017d) Dynamics, synchronization and fractional order form of a chaotic system without equilibrium. In: Volos CK (ed) Nonlinear systems: design, applications and analysis
Pikovsky AS, Rosenblum M, Kurths J (2003) Synchronization: a universal concept in nonlinear sciences. Cambridge University Press, CambridgeMATH
Rosenblum MG, Pikovsky AS, Kurths J (1997) From phase to lag synchronization in coupled chaotic oscillators. Phys Rev Lett 78:4193–4196MATHCrossRef
Rulkov NF, Sushchik MM, Tsimring LS, Abarbanel HDI (1995) Generalized synchronization of chaos in directionally coupled chaotic systems. Phys Rev E 51:980–994CrossRef
Sheng-Hai Z, Ke S (2004) Synchronization of chaotic erbium-doped fibre lasers and its application in secure communication. Chin Phys 13(8):1215CrossRef
Szatmári I, Chua LO (2008) Awakening dynamics via passive coupling and synchronization mechanism in oscillatory cellular neural/nonlinear networks. Int J Circuit Theor Appl 36:525–553MATHCrossRef
Taherion S, Lai YC (1999) Observability of lag synchronization of coupled chaotic oscillators. Phys Rev E 59:R6247–R6250CrossRef
Tahir FR, Jafari S, Pham V-T, Volos CK, Wang X (2015) A novel no-equilibrium chaotic system with multiwing butterfly attractors. Int J Bifurcat Chaos 25(4):1550056MathSciNetCrossRef
Tognoli E, Kelso JAS (2009) Brain coordination dynamics: True and false faces of phase synchrony and metastability. Prog Neurobiol 87:31–40CrossRef
Tolba MF, Abdelaty AM, Soliman NS, Said LA, Madian AH, Azar AT, Radwan AG (2017) FPGA implementation of two fractional order chaotic systems. Int J Electron Commun 28(2017):162–172CrossRef
Tsuji S, Ueta T, Kawakami H (2007) Bifurcation analysis of current coupled BVP oscillators. Int J Bifurcat Chaos 17:837–850MathSciNetMATHCrossRef
Vaidyanathan S, Sampath S, Azar AT (2015a) Global chaos synchronisation of identical chaotic systems via novel sliding mode control method and its application to Zhu system. Int J Model Ident Control 23(1):92–100CrossRef
Vaidyanathan S, Azar AT, Rajagopal K, Alexander P (2015b) Design and SPICE implementation of a 12-term novel hyperchaotic system and its synchronization via active control (2015). Int J Model Ident Control 23(3):267–277CrossRef
Vaidyanathan S, Idowu BA, Azar AT (2015c) Backstepping controller design for the global chaos synchronization of Sprott’s jerk systems. In: Azar AT, Vaidyanathan S (eds), Chaos modeling and control systems design, studies in computational intelligence, vol 581, pp 39–58. Springer, GmbH Berlin, Heidelberg
Vaidyanathan S, Azar AT (2015a) Anti-synchronization of identical chaotic systems using sliding mode control and an application to Vaidyanathan-Madhavan chaotic systems. In: Azar AT, Zhu Q (eds), Advances and applications in sliding mode control systems, studies in computational intelligence book Series, vol 576, pp 527–547. Springer, GmbH Berlin, Heidelberg
Vaidyanathan S, Azar AT (2015b) Hybrid synchronization of identical chaotic systems using sliding mode control and an application to Vaidyanathan chaotic systems. In: Azar AT, Zhu Q (eds), Advances and applications in sliding mode control systems, studies in computational intelligence book series, vol 576, pp 549–569. Springer, GmbH Berlin, Heidelberg
Vaidyanathan S, Azar AT (2015c) Analysis, control and synchronization of a nine-term 3-D novel chaotic system. In: Vaidyanathan S, Azar AT (eds), Chaos modeling and control systems design, studies in computational intelligence, vol 581, pp 3–17. Springer, GmbH Berlin, Heidelberg
Vaidyanathan S, Azar AT (2015d) Analysis and control of a 4-D novel hyperchaotic system. In: Vaidyanathan S, Azar AT (eds), Chaos modeling and control systems design, studies in computational intelligence, vol 581, pp 19–38. Springer, GmbH Berlin, Heidelberg
Vaidyanathan S, Azar AT (2016a) Dynamic analysis, adaptive feedback control and synchronization of an eight-term 3-D novel chaotic system with three quadratic nonlinearities. In: Studies in fuzziness and soft computing, vol 337, pp 155–178. Springer, Germany
Vaidyanathan S, Azar AT (2016b) Qualitative study and adaptive control of a novel 4-D hyperchaotic system with three quadratic nonlinearities. In: Studies in fuzziness and soft computing, vol 337, pp 179–202. Springer, Germany
Vaidyanathan S, Azar AT (2016c) A novel 4-D four-wing chaotic system with four quadratic nonlinearities and its synchronization via adaptive control method. In: Advances in chaos theory and intelligent control. Studies in fuzziness and soft computing, vol 337, pp 203–224. Springer, Germany
Vaidyanathan S, Azar AT (2016d) Adaptive control and synchronization of halvorsen circulant chaotic systems. In: Advances in chaos theory and intelligent control. Studies in fuzziness and soft computing, vol 337, pp 225–247. Springer, Germany
Vaidyanathan S, Azar AT (2016e) Adaptive backstepping control and synchronization of a novel 3-D jerk system with an exponential nonlinearity. In: Advances in chaos theory and intelligent control. Studies in fuzziness and soft computing, vol 337, pp 249–274. Springer, Germany
Vaidyanathan S, Azar AT (2016f) Generalized projective synchronization of a novel hyperchaotic four-wing system via adaptive control method. In: Advances in chaos theory and intelligent control. Studies in fuzziness and soft computing, vol 337, pp 275–296. Springer, Germany
Vaidyanathan S, Azar AT, Ouannas A (2017a) An eight-term 3-D novel chaotic system with three quadratic nonlinearities, its adaptive feedback control and synchronization. In: Studies in computational intelligence, vol 688, pp 719–746. Springer, Germany
Vaidyanathan S, Zhu Q, Azar AT (2017b) Adaptive control of a novel nonlinear double convection chaotic system. In: Studies in computational intelligence, vol 688, pp 357–385. Springer, Germany
Vaidyanathan S, Azar AT, Ouannas A (2017c) Hyperchaos and adaptive control of a novel hyperchaotic system with two quadratic nonlinearities. In: Studies in computational intelligence, vol 688, pp 773–803. Springer, Germany
Volos ChK, Kyprianidis IM, Stouboulos IN (2006a) Experimental demonstration of a chaotic cryptographic scheme. WSEAS Trans Circuit Syst 5:1654–1661
Volos ChK, Kyprianidis IM, Stouboulos IN (2006b) Designing of coupling scheme between two chaotic duffing—type electrical oscillators. WSEAS Trans Circuit Syst 5:985–992MATH
Volos ChK, Kyprianidis IM, Stouboulos IN (2013) A gallery of synchronization phenomena in resistively coupled non-autonomous chaotic circuits. J Eng Sci Technol Rev 6(4):15–23
Voss HU (2000) Anticipating chaotic synchronization. Phys Rev E 61:5115–5119CrossRef
Wang J, Che YQ, Zhou SS, Deng B (2009) Unidirectional synchronization of Hodgkin-Huxley neurons exposed to ELF electric field. Chaos Solit Fract 39:1335–1345MathSciNetMATHCrossRef
Wang X, Chen G (2012) A chaotic system with only one stable equilibrium. Commun Nonlinear Sci Numer Simul 17:1264–1272MathSciNetCrossRef
Wang X, Chen G (2013) Constructing a chaotic system with any number of equilibria. Nonlinear Dyn 71:429–436MathSciNetCrossRef
Wang Z, Ma J, Cang S, Wang Z, Chen Z (2016) Simplified hyper-chaotic systems generating multi-wing non-equilibrium attractors. Optik 127:2424–2431CrossRef
Wang Z, Volos C, Kingni ST, Azar AT, Pham VT (2017) Four-wing attractors in a novel chaotic system with hyperbolic sine nonlinearity. Optik Int J Light Electron Opt 131(2017):1071–1078CrossRef
Wei Z, Wang Z (2013) Chaotic behavior and modified function projective synchronization of a simple system with one stable equilibrium. Kybernetika 49:359–374MathSciNetMATH
Wei Z, Wang R, Liu A (2014) A new finding of the existence of hidden hyperchaotic attractors with no equilibria. Math Comput Simul 100:13–23MathSciNetCrossRef
Woafo P, Enjieu Kadji HG (2004) Synchronized states in a ring of mutually coupled self sustained electrical oscillators. Phys Rev E 69:046206CrossRef
Wu CW, Chua LO (1993) A simple way to synchronize chaotic systems with applications to secure communication systems. Int J Bifurcat Chaos 3(06):1619–1627MATHCrossRef
Zhong GQ, Man KF, Ko KT (2001) Uncertainty in chaos synchronization. Int J Bifurcat Chaos 11:1723–1735CrossRef
Zuo J, Li C (2016) Multiple attractors and dynamic analysis of a no-equilibrium chaotic system. Optik 127:7952–7959CrossRef
Metadaten
Titel
Synchronization Phenomena in Coupled Dynamical Systems with Hidden Attractors
verfasst von
C. K. Volos
Viet-Thanh Pham
Ahmad Taher Azar
I. N. Stouboulos
I. M. Kyprianidis
Copyright-Jahr
2018
Buch
Nonlinear Dynamical Systems with Self-Excited and Hidden Attractors

Print ISBN: 978-3-319-71242-0

Electronic ISBN: 978-3-319-71243-7

Copyright-Jahr: 2018

DOI
https://doi.org/10.1007/978-3-319-71243-7_17