Controlling the Period-Doubling Bifurcation of Logistic Model

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ISSN 1749-3889 (print), 1749-3897 (online) International Journal of Nonlinear Science Vol.20(2015) No.3,pp.174-178 Controlling the Period-Doubling Bifurcation of Logistic Model Zhiqian Wang 1, Jiashi Tang 2, Yingshe Luo 3 1 College of Civil Engineering and Mechanics, Central South University of Forestry and Technology, Changsha, Hunan 410004, PR China 2 College of Mechanical and Vehicle Engineering, Hunan University, Changsha, Hunan 410082, PR China 3 Hunan Province Key Laboratory of Engineering Rheology, Central South University of Forestry and Technology, Changsha, Hunan 410004, PR China (Received 21 December 2014, accepted 20 March 2015) Abstract: For the Logistic system, we introduce a special controller into the system. This competitive controller keeps the equilibria of a system unchanged. Moreover, the controller can delay the time of one of the bifurcation of the period-doubling bifurcation, but it could not influence the others bifurcation. Keywords: Logistic system; period-doubling bifurcation; bifurcation control 1 Introduction With the development of the nonlinear science, chaos control and bifurcation control have been researched as a popular topic [1]. As an engineering leading research field, bifurcation control has become more and more challenging [2]. Bifurcation control means bifurcation characteristics of the system are changed with a designed controller [3, 4]. The typical applications of bifurcation controls include possible resolution for stall of compression system in jet engines, high incidence flight, voltage collapse in power systems, oscillatory behavior of tethered satellites, magnetic bearing systems, rotating chains, thermal convection loop, and cardiac alternans and heart rhythms [5]. In general, the goal of bifurcation control is to avoid the appearance of the undesired bifurcation characteristics of the system so as to make the system to be monitored [6, 7]. Bifurcation control has been designed for stationary, Hopf, period-doubling bifurcations and chaotic motions, etc [8, 9]. Many research works on chaos control and synchronization of two chaotic systems have born great fruits. However, there are fewer investigations on bifurcation control relative to chaos control [10]. For Hopf bifurcation control, Abed and Fu designed a static state feedback controller by for discrete maps [11]. Yagnoobi and Abed considered a nonlinear feedback (mainly cubic) controller for Hopf bifurcation of discrete maps. Recently, Chen et al [1, 12]. developed a dynamic state feedback control law incorporating a washout filter to control Hopf bifurcation in the Lorenz system. For period-doubling bifurcation control, few studies has been extended to this topic. Chen et al. developed the state feedback and parameter tuning control law to control period-doubling bifurcation in the Logistic system [14, 15]. The first and second bifurcation locations of Logistic mapping are precisely controlled [16]. Some investigations proposed the state feedback control law to control the bifurcation of an acoustooptic bistable system [17]. Chen et al. proposed a comprehensive survey of Logistic system. The investigation analysed the bifurcation characteristics of Logistic system and proposed some questions about bifurcation control of Logistic system [18, 19]. For the controlled system, it should have the same structure of the original system and yet the controller is easy to be implemented. Thus, we can design a effective controller which satisfy the following conditions. Firstly, this competitive controller keeps the equilibria of a system unchanged and also preserves the dimension of the system. Secondly, the controller can delay the time of the first bifurcation of the period-doubling bifurcation, but it could not control the second bifurcation or others after the first bifurcation [20]. Thus, the controller can only control one of the bifurcation locations [21]. In this paper, we introduce the time-delay τ into the controlled system. Our goal is to design a controller with time-delay to satisfy the above conditions. Corresponding author. wzq198662@163.com: your email address Copyright c World Academic Press, World Academic Union IJNS.2015.12.15/891

Z. Wang et al: Controlling the Period-Doubling Bifurcation of Logistic Model 175 2 Parametric synchronization scheme Consider a Logistic model described by x n+1 = f(x n, µ) = µx n (1 x n ), (1) where µ is a constant and satisfies µ > 0. x n satisfies x n [0, 1]. x n is the density of target insect in the given year. x n+1 is density of target insect in the next given year. The equilibrium points can be obtained The Jacobi can be given Fig.1 shows the bifurcation of the Logistic model. x = 0, x = µ 1 µ, (2) J = f(x n, µ) xn=x, (3) Figure 1: Bifurcation of the Logistic model Figure 2: The first bifurcation of the controlled system Consider the logistic model with designed controller described by x n+1 = f(x n, µ) = µx n (1 x n ) + u, (4) Design the new feedback controller using time delay u as k(x(t + τ) x(t)), b 1 < µ b (5) where τ is the time-delay. Assume x n x(t n ), t n = t + n t, (6) Let τ = m t. IJNS homepage: http://www.nonlinearscience.org.uk/

176 International Journal of Nonlinear Science, Vol.20(2015),No.3,pp. 174-178 The Jacobi can be given J = f(x n, µ) + k(x(t + τ) x(t)) xn =x, (7) When the controlled system has 1 periodic orbit, the system has 1 periodic point. The Logistic model with designed controller described by x n+1 = f(x n, µ) = µx n (1 x n ) + u, (8) where k(x(t + (n + 1) t) x(t + n t)), 2.6 < µ b (9) Because of x(t + (n + 1) t) = x(t + n t), the controller keeps the equilibria of the original system unchanged. The eigenvalue of the Jacobi should satisfy that Substitute the equilibrium points Eq. (2) into Eq. (9) where k ( 1, 0). Solve Eq. (11), we can obtain that where µ cr = 3. According to k ( 1, 0), µ x n + k(µ x n 1) xn=x < 1, (10) ( 1 k)µ + 2 + k < 1, (11) µ = µ cr + 2k 1 k, (12) 2k 1 k satisfies 2k 1 k > 0. We can obtain µ > 3, µ < b, (13) where b is the value which we want to define. Because of µ > µ cr, the controller u indeed expand the range of the first bifurcation. Fig.2 presents the bifurcation of the controlled system. From Fig.2, the controller u satisfies the first condition that keeps the equilibria of a system unchanged. Obviously, the controller delays the time of the first bifurcation from µ = 3.145 (the original system) to µ = 3.35. Moreover, the second and other bifurcation locations of controlled Logistic system are not controlled by the controller. We have achieved the goal with the controller. When the controlled system has 2 periodic orbit, the system has 2 periodic point. The logistic model with designed controller described by x n+1 = f(x n, µ) = µx n (1 x n ) + u, (14) where k(x(t + (n + 2) t) x(t + n t)), 3 < µ b (15) The eigenvalue of the Jacobi should satisfy that µ x n + k(µ 2 2(µ 2 + µ 3 )x n + 6µ 3 x 2 n 4µ 3 x 3 n) 1) xn =x < 1, (16) Substitute the equilibrium points x = 1+µ± µ 2 3 into Eq. (16) µ 2 3 1 + k(µ 2 2(µ 2 + µ 3 ) 1 + µ ± µ 2 3 + 6µ 3 ( 1 + µ ± µ 2 3 ) 2 4µ 3 1 + µ ± µ 2 3 ) 3 ) 1) < 1, (17) IJNS email for contribution: editor@nonlinearscience.org.uk

Z. Wang et al: Controlling the Period-Doubling Bifurcation of Logistic Model 177 when k = 0, µ cr should satisfy that µ2 3 < 2, (18) According to Eq. (17), we can obtain that where µ > 0. From Eq. (19), when k > 0, we can obtain µ 2 3 < (2 + k + kµ(µ 2 + 3 2 µ 1))2, (19) k + kµ(µ 2 + 3 µ 1) > 0. (20) 2 From Eq. (20), we know that µ > µ cr. Thus, the controller delays the time of the second bifurcation. Figure 3: The second bifurcation of the controlled system Figure 4: The second bifurcation of the controlled system with k = 0.1 Fig.3 is the bifurcation of the controlled system. From Fig.3, the controller u keeps the equilibria of a system unchanged. The second bifurcation begins with µ = 3.145 in Fig.3 which means the first bifurcation of the controlled system has not been controlled. We achieve the goal. Moreover, we delay the second bifurcation from µ = 3.55 (the original system) to µ = 3.58. We can modify the value of k to expand the range of µ. The second bifurcation can be delayed to µ = 3.615 with k = 0.1 (see Fig.4). That is to say that we can control one of the bifurcation locations. In this case, others bifurcation locations remain unchanged. 3 Conclusions In this paper, we introduce a competitive controller into the Logistic system. The new feedback controller is designed using time delay. It can keep the equilibria of a system unchanged and also preserve the dimension of the system. Secondly, the controller can delay the time of the first bifurcation of the period-doubling bifurcation, but it could not control the second bifurcation or others after the first bifurcation. The first and second bifurcation locations of Logistic mapping are precisely controlled by the designed controller. Acknowledgments The study was supported by National Science Foundation of China under Grant Nos. 11372102 and 11172093. IJNS homepage: http://www.nonlinearscience.org.uk/

178 International Journal of Nonlinear Science, Vol.20(2015),No.3,pp. 174-178 References [1] D. Chen et al. Anti-control of Hopf bifurcation. Ieee Trans Circuits Syst. 48(2001): 661 72. [2] J. Qiang. Adaptive control and synchronization of a new hyperchaotic system with unknow parameters. Phys Lett A. 362(2007): 424 9. [3] G. Wened. On creation of Hopf bifurcations in discrete-time nonlinear systems. Chaos. 12(2002): 350 5. [4] M. Rani and R. Agarwal. A new experimental approach to study the stability of logistic map. Chaos,Solitons Fractals. 41(2009): 2062 2066. [5] E. Shahverdiev et al. Lag synchronization in time-delayed system. Phys Lett A. 292(2002): 320 4. [6] H. Sakaguchi and K. Tomita. Bifurcations of the coupled logistic map. Prog Theor Phys. 78(1987): 305 315. [7] E. Abed and J. Fu. Local feedback stabilization and bifurcation control, II. Stationary bifurcation. Syst Contr Lett. 8(1987): 467 73. [8] J. Lu and S. Zhang. Controlling Chen s chaotic attractor using backstepping design based on parameters identification. Phys Lett A. 286(2001): 145 9. [9] T. Yang et al. Impulsive control of Lorenz system. Physica D. 110(1997): 18 24. [10] M. Bleich and J. Socolar. Stability of periodic orbits controlled by time-delay feedback. Phys Lett A. 210(1996): 87 94. [11] E. Abed et al. Stabilization of period doubling bifurcations and implications for control of chaos. Physica D. 70(1994): 154 64. [12] G. Chen et al. Bifurcation dynamics in discrete-time delayed-feedback control systems. Int J Bifurcat Chaos. 9(1999): 287 93. [13] G. Chen et al. Bifurcationcontrol:theories,methods,and applications. Int J Bifurcat Chaos. 10(2000): 511 548. [14] H. Yaghoobi and E. Abed. Local feedback control of the NeimarkCSacker bifurcation. Int J Bifurcat Chaos. 13(2003): 879 93. [15] G. Wen and D. Xu. Designing Hopf bifurcations into nonlinear discrete-time systems via feedback control. Int J Bifurcat Chaos. 14(2004): 2283 93. [16] X. Wang et al. Anticontrol of chaos in continuous-time systems via time-delay feedback. Chaos. 10(2000): 771 9. [17] T. Yang and K. Bilimgut. Experimental results of strange nonchaotic phenomenon in a second-order quasiperiodically forced electronic circuit. Phys Lett A. 236(1997): 494 9. [18] E. Ott et al. Controlling chaos. Phys Rev Lett. 64(1990): 1196 1199. [19] G. Iooss. Bifurcation of maps and applications. New York: North-Holland Pub. New York: North-Holland Pub Co. 1979. [20] B. Lakshmi. Population models with time dependent parameters. ChaosSolitons Fractals. 26(2005): 719 721. [21] M. Hu and Z. Xu. Adaptive feedback controller for projective synchronization. Nonlinear Anal. RWA. 9(2008): 1253 1256. IJNS email for contribution: editor@nonlinearscience.org.uk

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