Hybrid Synchronization of Lu and Bhalekar-Gejji Chaotic Systems Using Nonlinear Active Control

Third International Conference on Advances in Control and Optimization of Dynamical Systems March 13-15, 2014. Kanpur, India

Hybrid Synchronization of Lu and Bhalekar-Gejji Chaotic Systems Using Nonlinear Active Control Jay Prakash Singh*. Piyush Pratap Singh,** B K Roy*** 

*National Institute of Technology Silchar, Silchar, Assam India (e-mail: [email protected]). ** National Institute of Technology Silchar, Silchar, Assam India (e-mail: [email protected]). *** National Institute of Technology Silchar, Silchar, Assam India (e-mail:[email protected]). Abstract: Hybrid synchronization based on the active control theory between two different chaotic systems, i.e. Lu and Bhalekar-Gejji is reported in this paper. Lu chaotic system is taken as master and Bhalekar-Gejji chaotic system as slave. Stabilization of error dynamics is achieved by satisfying the Lyapunov stability conditions. Control is designed by using the relevant variables of master and slave systems. Simulation is presented for verification of proposed scheme. Keywords: Active Control, Asymptotic stability, Chaotic Behavior, Master-Slave System, Nonlinear Control, Synchronization. 

and Xu et al., 2007, Jian-Ping et al., 2006), Exponential synchronization (Park, 2007). In similar way, antisynchronization between master-slave systems can be studied. Two chaotic systems (master-slave) will be antisynchronize when their sum of state will be converge to zero asymptotically with time, their amplitude of the state will be same but they will have opposite sign ( Li and Zhou et al., 2007, Liu et al., 2000, Sawalh et al., 2008, Ho et at., 2002b). Hybrid synchronization is the phenomenon when complete synchronization and anti-synchronization occur together between the states of two chaotic systems.

1. INTRODUCTION The important property available in any Chaotic/Dynamical system are sensitivity to initial condition, aperiodic long time behavior, and deterministic in nature (Lorenz, 1963). When the states of any chaotic system drive the state of another system, this phenomenon is called Synchronization. Complete synchronization is the phenomenon in which the differences of the states of synchronized system converge to zero. Synchronization of two identical chaotic systems with different initial condition was first illustrated by (Pecora and Caroll, 1990).

In last decade some paper has absorbed on hybrid synchronization of different chaotic and hyperchaotic system such as; Hybrid synchronization of hyperchaotic Chen system (Sudheer et al., 2009), hybrid synchronization of hyperchaotic Lu system (Sebastian et al., 2009), hybrid synchronization of hyperchaotic Lu system (Sebastian et al., 2009), adaptive hybrid synchronization of two different chaotic system Chen and Lu system (Wei et al., 2010), hybrid synchronization of hyperchaotic Lu system based on Passive control (Xia et al., 2010), hybrid synchronization of Liu and Chen system by active nonlinear control (Sundarpandian, 2011), hybrid synchronization in hyperchaotic Lorenz, Qi system (Yaoyao, 2012), hybrid synchronization of Arneodo and Rossler chaotic system by active nonlinear control (Sundarpandian, 2012), hybrid synchronization of Chen and Lu system (Zheng et al., 2012).

Drive (master) -response (slave) scheme for synchronization of chaotic system is widely used. In this scheme the output of master (drive) system is use to control slave (slave) system. Various schemes have been developed for synchronization of chaotic system in the last two decade such as PC method (Pecora and Carroll, 1990, 1991), OGY method (Ott et al., 1990), active control method (Ho et al., 2002a, Chen, 2005, Bai et al., 1997, Vincet, 2005), adaptive control method (Liao et al., 2000, Sundarpandian, 2013, Yu, 2004), backstepping control method (Park, 2006, Tan et al., 2003), sampled data feedback method (Zhao, et al., 2008), time delay feedback method (Guo et al., 2009), sliding mode control method (Yan et al., 2006, Chen, et al., 2012, Slotine at al., 1983, Utkin, 1993) etc.

Here, we discuss the hybrid synchronization of chaotic Lu system (Lu and Chen, 2002) and chaotic Bhalekar-Gejji systems (Bhalekar et al., 2011, 2012) system, using nonlinear active control.

So many more technique are also available related to synchronization like: Complete synchronization (Fabiny et al., 1991), Lag synchronization (Rosenblum et al., 1997), Phase synchronization (Ge et al., 2004), generalized synchronization (Kocarev et al., 1996), projective synchronization (Li et al., 2001), generalized projective (Li

978-3-902823-60-1 © 2014 IFAC

This paper is organized as follows, In section (2), we discuss about the problem statement for hybrid synchronization of 292

10.3182/20140313-3-IN-3024.00069

2014 ACODS March 13-15, 2014. Kanpur, India

two different chaotic systems. In section (3) we discuss the hybrid synchronization of chaotic Lu system and chaotic Bhalekar-Gejji system. In section (4), simulation results are given for illustration and verification of theory for hybrid synchronization. Finally, conclusion is drawn in section (5).

Now, the asymptotical stabilization of the equation (6) is obtained by designing a controller for stabilizing the error dynamical system (4) at origin. By using the Lyapunov stability theory (Hahn 1976, Khalil 1996), positive definite Lyapunov function

2. PROBLEM STATEMENT FOR HYBRID SYNCHRONIZATION

∑

where, is the order of the system. Assuming that parameters of the drive and response are known and states are measurable. The continuous first partial derivative of (7) is

Consider a chaotic system as drive system: ̇

(1) ̇

where, is state vector, and is the matrix for system parameter, and is the nonlinear part of the system. Consider another chaotic system as a slave system ̇

(7)

∑

(8)

‖ is negative definite, and also as ‖ , then states and are globally asymptotically stable in large, and also the state of drive and response system are globally asymptotically hybrid-synchronized.

(2) 3. HYBRID SYNCHRONIZATION OF LU AND BHALEKAR-GEJJI CHAOTIC SYSTEM

, and

is the matrix for is the non-linear part of is the active non-linear controller to

Here, we apply nonlinear active control technique for the synchronization of Lu system (Lu and Chen, 2002) and Bhalekar-Gejji (Bhalekar et al., 2011, 2012). Master (or drive) system is Lu system dynamics is given:

Our goal is to design an appropriate controller such that state vector of the response system asymptotically approaches a given functional relationship of the state vector of the drive system. State vector and will be state of two identical chaotic system if and . State and will be state of two different chaotic system if and . For our problem functional relationship between master and slave system must include both synchronization and antisynchronization. Therefore relationship can be written as

̇ ̇

(9) ̇

where, , , are the states of system (9) and a, b, c are the parameter of system (9) which are positive. Lu attractors are given in the Fig. 1.

(3) when, , and , the complete synchronization, antisynchronization is obtained respectively, we call this scheme as hybrid synchronization. We, define hybrid synchronization error vector as

(b) 40

20

30

3

2

x state

(a) 40

x state

Having state vector system parameter and the slave system and be designed.

0

20

(4) -20 -20

Now, our aim for hybrid synchronization of chaotic system (1) and (2), we design active control , such that trajectory of system (2) with any initial condition can asymptotically approach the system (1) with initial condition , i.e.

‖

(d)

40

,

20

3

20

0 50 0 0

20

40

x 2 state

Fig. 1. Lu Chaotic attractors (a) on the plane, (c) on the plane, (d) on the

x 2 state

-50 -50

0 x 1 state

50

plane, (b) on the plane.

The slave system is described as Bhalekar-Gejji dynamics

‖ ̇

So, hybrid synchronization error can be written from (1), (3), (5) ̇

20

(c)

30

10 -20

We say that anti-synchronization of two systems (1) and (2) are achieved if the following equation holds: ‖

0 x 1 state

x state

(5)

We say that complete synchronization of two systems (1) and (2) is achieved if the following equation holds: ‖

10 -20

40

40

3

‖

20 x 1 state

40

x state

‖

0

̇

(10) ̇

(6)

Where , , , 293

,

are the states of the system (10) and , >0 are parameters of the system (10), and

2014 ACODS March 13-15, 2014. Kanpur, India

̇

, , are nonlinear active controller element which is to be designed. Bhalekar-Gejji attractors are given in the Fig. 2. (a)

30

y state

10

y state

40

-10 -20 -20

(16)

̇

(17)

is negative definite function on value is .

20

for condition as parameter

Now, we can say that according to Lyapunov stability theory (Hahn 1976, Khalil 1996) error dynamics (12) globally asymptotically stable for equilibrium state at origin i.e. error dynamics will converge to zero as t . We obtained the following result.

10 -10

0 y 1 state

10

0 -20

20

-10

0 y 1 state

10

20

(d)

(c) 40 40

y state

30

0 20

10 0 -20

Remarks. The chaotic Lu (9) and chaotic Bhalekar-Gejji (10) system are exponentially and globally hybrid synchronized for any value of initial conditions with the nonlinear controller defined by (13).

20

3

20

3

y state

̇

3

2

0

̇ +

Substituting the error dynamics (14) into (16) we obtained

(b)

20

̇ +

0 -10

0 y 2 state

10

20

y 2 state

0 y 1 state

20

4. SIMULATION RESULTS

Fig. 2. Bhalekhar-Gejji Chaotic attractors (a) on the plane, (c) on the plane, (d) on the

The hybrid-synchronization error

-20 -20

plane, (b) on the plane.

We are using fourth-order Runga-Kutta method for solving the dynamics (9), and (10) and active nonlinear controller (13) and simulating the result with time step h= .

which is defined as: (11)

where,

For chaotic behavior of Lu system the parameter is selected as follows (Lu and Chen, 2002), and the parameters of the Bhalekar-Gejji system for chaotic behavior are selected as following (Bhalekar, 2012).

̇ , and for synchronization and for anti-synchronization. Hence, (11) can be written

as:

The initial condition for plotting the synchronization of state, controller, error dynamics of the master (9) and slave system (10) are as and .

States are synchronized and anti-synchronized alternatively. The error dynamics equation is obtained as follows:

4.1 Time Response plots of Master and Slave states ̇ ̇

(12) x &y

1

20 x1

0

y1

1

̇

-20

(13)

200

300

400 500 600 t ( time in seconds ) (a)

700

800

900

20

y2

-20

3 3

x &y

̇ (14) ̇

100

200

300

400 500 600 t ( time in seconds ) (b)

700

800

900

40 20

1000

x3

0 -20

1000

x2

0 0

Substituting the controller dynamics (13) into error dynamics (12), we obtain the error dynamics as: ̇

100

2

x &y

2

We consider the active nonlinear controller for above error dynamics (12) are as follows:

0

y3 0

100

200

300

400 500 600 t ( time in seconds ) (c)

700

800

900

1000

Fig. 3. Time Response plots of hybrid synchronized states of Master and Slave. (a) Time response of first state of Master and Slave. (b) Time response of second state of Master and Slave. (c) Time response of third state of Master and Slave.

Now, considering positive definite Lyapunov function on defined by (15) Taking the continuous first partial derivative of (15), we obtained the following 294

2014 ACODS March 13-15, 2014. Kanpur, India

4.2 Control inputs for hybrid synchronization between Master-Slave

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control input u

1

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1000 0 0

100

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400 500 600 t ( time in seconds ) (a)

700

800

900

1000

0

100

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400 500 600 t ( time in seconds ) (b)

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400 500 600 t ( time in seconds ) (c)

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control input u

2

-1000

1000 0

control input u

3

-1000

1000 0 -1000

Fig. 4. Time Response plots of the Control Input states for the hybrid synchronization between each states of Master-Slave (a) First Control input. (b) Second Control input. (c) Third Control input.

4.3 Error Response between the States of Master and Slave (a)

error e

1

10 0 -10

0

1

2

3

4 5 6 t ( time in seconds ) (b)

7

8

9

10

0

1

2

3

4 5 6 t ( time in seconds ) (c)

7

8

9

10

0

1

2

3

4 5 6 t ( time in seconds )

7

8

9

10

error e

2

10 0 -10

error e

3

10 0 -10

Fig. 5. Convergence of error between the states of Master and Slave Systems. (a) between first states. (b) between second states. (c) between third states.

5. CONCLUSIONS In this paper, hybrid synchronization between two different chaotic systems, i.e. Lu and Bhalekar-Gejji system is addressed. Active control technique is used to realize the hybrid synchronization since the parameters of the systems are known. Two states of master and slave system are synchronized and one state is anti-synchronized. MATLAB simulation is done. Simulation results verify the effectiveness of the proposed scheme. Literature review suggests that hybrid synchronization involving Bhalekar-Gejji chaotic system is not reported by others. Hardware implementation is being done and will be reported soon.

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