THE ACTIVE CONTROLLER DESIGN FOR ACHIEVING GENERALIZED PROJECTIVE SYNCHRONIZATION OF HYPERCHAOTIC LÜ AND HYPERCHAOTIC CAI SYSTEMS

International Journal of Advanced Information Technology (IJAIT) Vol. 2, No.2, April 2012
DOI : 10.5121/ijait.2012.2206 75
THE ACTIVE CONTROLLER DESIGN FOR
ACHIEVING GENERALIZED PROJECTIVE
SYNCHRONIZATION OF HYPERCHAOTIC LÜ AND
HYPERCHAOTIC CAI SYSTEMS
Sarasu Pakiriswamy1
and Sundarapandian Vaidyanathan1
1
Department of Computer Science and Engineering
Vel Tech Dr. RR & Dr. SR Technical University
Avadi, Chennai-600 062, Tamil Nadu, INDIA
sarasujivat@gmail.com
2
Research and Development Centre
Vel Tech Dr. RR & Dr. SR Technical University
Avadi, Chennai-600 062, Tamil Nadu, INDIA
sundarvtu@gmail.com
ABSTRACT
This paper discusses the design of active controllers for achieving generalized projective synchronization
(GPS) of identical hyperchaotic Lü systems (Chen, Lu, Lü and Yu, 2006), identical hyperchaotic Cai
systems (Wang and Cai, 2009) and non-identical hyperchaotic Lü and hyperchaotic Cai systems. The
synchronization results (GPS) for the hyperchaotic systems have been derived using active control method
and established using Lyapunov stability theory. Since the Lyapunov exponents are not required for these
calculations, the active control method is very effective and convenient for achieving the GPS of the
hyperchaotic systems addressed in this paper. Numerical simulations are provided to illustrate the
effectiveness of the GPS synchronization results derived in this paper.
KEYWORDS
Active Control, Hyperchaos, Hyperchaotic Systems, Generalized Projective Synchronization, Hyperchaotic
Lü System, Hyperchaotic Cai System.
1. INTRODUCTION
Chaotic systems are nonlinear dynamical systems which are highly sensitive to initial conditions.
This sensitivity of chaotic systems is usually called as the butterfly effect [1]. Small differences in
initial conditions (such as those due to rounding errors in numerical computation) yield widely
diverging outcomes for chaotic systems.
Hyperchaotic system is usually defined as a chaotic system with more than one positive
Lyapunov exponent. The first hyperchaotic system was discovered by O.E. Rössler ([2], 1979).

76
Since hyperchaotic system has the characteristics of high capacity, high security and high
efficiency, it has the potential of broad applications in nonlinear circuits, secure communications,
lasers, neural networks, biological systems and so on. Thus, the studies on hyperchaotic systems,
viz. control, synchronization and circuit implementation are very challenging problems in the
chaos literature [3].
Chaos synchronization problem received great attention in the literature when Pecora and Carroll
[4] published their results on chaos synchronization in 1990. From then on, chaos synchronization
has been extensively and intensively studied in the last three decades [4-37]. Chaos theory has
been explored in a variety of fields including physical systems [5], chemical systems [6],
ecological systems [7], secure communications [8-10], etc.
Synchronization of chaotic systems is a phenomenon that may occur when a chaotic oscillator
drives another chaotic oscillator. Because of the butterfly effect which causes the exponential
divergence of the trajectories of two identical chaotic systems started with nearly the same initial
conditions, synchronizing two chaotic systems is seemingly a very challenging problem.
In most of the chaos synchronization approaches, the master-slave or drive-response formalism is
used. If a particular chaotic system is called the master or drive system and another chaotic
system is called the slave or response system, then the idea of anti-synchronization is to use the
output of the master system to control the slave system so that the states of the slave system have
the same amplitude but opposite signs as the states of the master system asymptotically. In other
words, the sum of the states of the master and slave systems are designed to converge to zero
asymptotically, when anti-synchronization appears.
In the recent years, various schemes have been deployed for chaos synchronization such as PC
method [4], OGY method [11], active control [12-15], adaptive control [16-20], backstepping
design [21-23], sampled-data feedback [24], sliding mode control [25-28], etc.
In generalized projective synchronization (GPS) of chaotic systems [29-30], the chaotic systems
can synchronize up to a constant scaling matrix. Complete synchronization [12-13], anti-
synchronization [31-34], hybrid synchronization [35], projective synchronization [36] and
generalized synchronization [37] are particular cases of generalized projective synchronization.
GPS has important applications in areas like secure communications and secure data encryption.
In this paper, we deploy active control method so as to derive new results for the generalized
projective synchronization (GPS) for identical and different hyperchaotic Lü and hyperchaotic
Cai systems. Explicitly, using active nonlinear control and Lyapunov stability theory, we achieve
generalized projective synchronization for identical hyperchaotic Lü systems (Chen, Lu, Lü and
Yu, [38], 2006), identical hyperchaotic Cai systems (Wang and Cai, [39], 2009) and non-identical
hyperchaotic Lü and hyperchaotic Cai systems.
This paper has been organized as follows. In Section 2, we give the problem statement and our
methodology. In Section 3, we present a description of the hyperchaotic systems considered in
this paper. In Section 4, we derive results for the GPS of two identical hyperchaotic Lü systems.
In Section 5, we derive results for the GPS of two identical hyperchaotic Cai systems. In Section
6, we discuss the GPS of non-identical hyperchaotic Lü and hyperchaotic Cai systems. In Section
7, we summarize the main results derived in this paper.

77
2. PROBLEM STATEMENT AND OUR METHODOLOGY
Consider the chaotic system described by the dynamics
( )x Ax f x= +& (1)
where n
x∈R is the state of the system, A is the n n× matrix of the system parameters and
: n n
f →R R is the nonlinear part of the system. We consider the system (1) as the master or
drive system.
As the slave or response system, we consider the chaotic system described by the dynamics
( )y By g y u= + +& (2)
where n
y ∈R is the state of the system, B is the n n× matrix of the system parameters,
: n n
g →R R is the nonlinear part of the system and n
u ∈R is the controller of the slave system.
If A B= and ,f g= then x and y are the states of two identical chaotic systems. If A B≠ or
,f g≠ then x and y are the states of two different chaotic systems.
In the active control approach, we design a feedback controller ,u which achieves the generalized
projective synchronization (GPS) between the states of the master system (1) and the slave
system (2) for all initial conditions (0), (0) .n
x z ∈R
For the GPS of the systems (1) and (2), the synchronization error is defined as
,e y Mx= − (3)
where
1
2
0 0
0 0
0 0 n
M
α
α
α
 
 
 =
 
 
 
L
L
M M O M
L
(4)
In other words, we have
, ( 1,2, , )i i i ie y x i nα= − = K (5)
From (1)-(3), the error dynamics is easily obtained as
( ) ( )e By MAx g y Mf x u= − + − +& (6)
The aim of GPS is to find a feedback controller u so that
lim ( ) 0
t
e t
→∞
= for all (0) .n
e ∈R (7)

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Thus, the problem of generalized projective synchronization (GPS) between the master system (1)
and slave system (2) can be translated into a problem of how to realize the asymptotic
stabilization of the system (6). So, the objective is to design an active controller u for stabilizing
the error dynamical system (6) at the origin.
We take as a candidate Lyapunov function
( ) ,T
V e e Pe= (8)
where P is a positive definite matrix.
Note that : n
V →R R is a positive definite function by construction.
We assume that the parameters of the master and slave system are known and that the states of
both systems (1) and (2) are measurable.
If we find a feedback controller u so that
( ) ,T
V e e Qe= −& (9)
where Q is a positive definite matrix, then : n
V →& R R is a negative definite function.
Thus, by Lyapunov stability theory [40], the error dynamics (6) is globally exponentially stable
and hence the condition (7) will be satisfied. Hence, GPS is achieved between the states of the
master system (1) and the slave system (2).
3. SYSTEMS DESCRIPTION
The hyperchaotic Lü system ([38], 2006) is described by the dynamics
1 2 1 4
2 2 1 3
3 3 1 2
4 4 1 3
( )x a x x x
x cx x x
x bx x x
x dx x x
= − +
= +
= − +
= +
&
&
&
&
(10)
where 1 2 3 4, , ,x x x x are the states and , , ,a b c d are constant, positive parameters of the system.
The Lü system (10) exhibits a hyperchaotic attractor when the parameter values are taken as
36, 3, 20a b c= = = and 1.3d =
Figure 1 depicts the phase portrait of the hyperchaotic Lü system (10).
The hyperchaotic Cai system ([39], 2009) is described by the dynamics
1 2 1
2 1 2 4 1 3
2
3 3 2
4 1
( )x p x x
x qx rx x x x
x sx x
x xε
= −
= + + −
= − +
= −
&
&
&
&
(11)

79
where 1 2 3 4, , ,x x x x are the states and , , , ,p q r s ε are constant, positive parameters of the system.
The Cai dynamics (11) exhibits a hyperchaotic attractor when the parameter values are taken as
27.5, 3, 19.3, 2.9p q r s= = = = and 3.3ε =
Figure 2 depicts the phase portrait of the hyperchaotic Cai system (11).
Figure 1. The Phase Portrait of the Hyperchaotic Lü System
Figure 2. The Phase Portrait of the Hyperchaotic Cai System

80
4. GPS OF IDENTICAL HYPERCHAOTIC LÜ SYSTEMS
4.1 Theoretical Results
In this section, we apply the active nonlinear control method for the generalized projective
synchronization (GPS) of two identical hyperchaotic Lü systems ([38], 2006).
Thus, the master system is described by the hyperchaotic Lü dynamics
1 2 1 4
2 2 1 3
3 3 1 2
4 4 1 3
( )x a x x x
x cx x x
x bx x x
x dx x x
= − +
= −
= − +
= +
&
&
&
&
(12)
where 1 2 3 4, , ,x x x x are the states and , , ,a b c d are positive, constant parameters of the system.
The slave system is described by the controlled hyperchaotic Lü dynamics
1 2 1 4 1
2 2 1 3 2
3 3 1 2 3
4 4 1 3 4
( )y a y y y u
y cy y y u
y by y y u
y dy y y u
= − + +
= − +
= − + +
= + +
&
&
&
&
(13)
where 1 2 3 4, , ,y y y y are the states and 1 2 3 4, , ,u u u u are the active controls to be designed.
For the GPS of the systems (12) and (13), the synchronization error e is defined by
, ( 1,2,3,4)i i i ie y x iα= − = (14)
where the scales 1 2 3 4, , ,α α α α are real numbers.
The error dynamics is obtained as
1 1 2 1 2 4 1 4 1
2 2 1 3 2 1 3 2
3 3 1 2 3 1 2 3
4 4 1 3 4 1 3 4
( )e ae a y x y x u
e ce y y x x u
e be y y x x u
e de y y x x u
α α
α
α
α
= − + − + − +
= − + +
= − + − +
= + − +
&
&
&
&
(15)
We choose the nonlinear controller as
1
2
3
4
1 2 1 2 4 1 4 1 1
2 1 3 2 1 3 2 2
3 1 2 3 1 2 3 3
4 1 3 4 1 3 4 4
( )u a
u ce
u
u de
e a y x y x k e
y y x x k e
be y y x x k e
y y x x k e
α
α
α
α α=
= −
= −
= − −
− − − + −
+ − −
+ −
+ −
(16)
where the gains 1 2 3 4, , ,k k k k are positive constants.

81
Substituting (16) into (15), the error dynamics simplifies to
1 1
2 2
3 3
4 3
1
2
3
4
e k e
e k e
e k e
e k e
= −
= −
= −
= −
&
&
&
&
(17)
Next, we prove the following result.
Theorem 1. The active feedback controller (16) achieves global chaos generalized projective
synchronization (GPS) between the identical hyperchaotic Lü systems (12) and (13).
Proof. We consider the quadratic Lyapunov function defined by
( )2 2 2 2
1 2 3 4( )
1 1
,
2 2
T
V e e e e e e e= = + + + (18)
which is a positive definite function on 4
.R
Differentiating (18) along the trajectories of (17), we get
2 2 2 2
1 1 2 2 3 3 4 4( ) ,V e k e k e k e k e= − − − −& (19)
which is a negative definite function on 4
.R
Thus, by Lyapunov stability theory [40], the error dynamics (17) is globally exponentially stable.
This completes the proof.
4.2 Numerical Results
For the numerical simulations, the fourth-order Runge-Kutta method is used to solve the two
systems of differential equations (12) and (13) with the active controller (16).
The parameters of the identical hyperchaotic Lü systems are chosen as
36, 3, 20, 1.3a b c d= = = =
The initial values for the master system (12) are taken as
1 2 3 4(0) 24, (0) 17, (0) 12, (0) 18x x x x= = − = − =
The initial values for the slave system (13) are taken as
1 2 3 4(0) 11, (0) 20, (0) 5, (0) 34y y y y= − = = − =
The GPS scales are taken as 1 2 33.5, 2.9, 0.8,α α α= = − = and 4 1.4.α = −
We take the state feedback gains as 5ik = for 1,2,3,4.i =

82
Figure 3 shows the GPS synchronization of the identical hyperchaotic Lü systems. Figure 4
shows the time-history of the GPS errors 1 2 3 4, , ,e e e e for the identical hyperchaotic Lü systems.
Figure 3. GPS Synchronization of the Identical Hyperchaotic Lü Systems
Figure 4. Time History of the GPS Synchronization Error

83
5. GPS OF IDENTICAL HYPERCHAOTIC CAI SYSTEMS
synchronization (GPS) of two identical hyperchaotic Cai systems ([39], 2009).
Thus, the master system is described by the hyperchaotic Cai dynamics
1 2 1
2 1 2 4 1 3
2
3 3 2
4 1
( )x p x x
x qx rx x x x
x sx x
x xε
= −
= + + −
= − +
= −
&
&
&
&
(20)
where 1 2 3 4, , ,x x x x are the states and , , , ,p q r s ε are positive, constant parameters of the system.
The slave system is described by the controlled hyperchaotic Cai dynamics
1 2 1 1
2 1 2 4 1 3 2
2
3 3 2 3
4 1 4
( )y p y y u
y qy ry y y y u
y sy y u
y y uε
= − +
= + + − +
= − + +
= − +
&
&
&
&
(21)
where 1 2 3 4, , ,y y y y are the states and 1 2 3 4, , ,u u u u are the active controls to be designed.
1 1 1 1
2 2 2 2
3 3 3 3
4 4 4 4
e
e
e
e
y x
y x
y x
y x
α
α
α
α
= −
= −
= −
= −
(22)
1 1 2 1 2 1
2 2 1 2 1 4 2 4 1 3 2 1 3 2
2 2
3 3 2 3 2 3
4 1 4 1 4
( )
( )
( )
e pe p y x u
e re q y x y x y y x x u
e se y x u
e y x u
α
α α α
α
ε α
= − + − +
= + − + − − + +
= − + − +
= − − +
&
&
&
&
(23)

84
1 1 2 1 2 1 1
2 2 1 2 1 4 2 4 1 3 2 1 3 2 2
2 2
3 3 2 3 2 3 3
4 1 4 1 4 4
( )
( )
( )
u pe p y x k e
u re q y x y x y y x x k e
u se y x k e
u y x k e
α
α α α
α
ε α
= − − −
= − − − − + + − −
= − + −
= − −
(24)
where the gains 1 2 3, ,k k k are positive constants.
1 1
2 2
3 3
4 4
1
2
3
4
e k e
e k e
e k e
e k e
= −
= −
= −
= −
&
&
&
&
(25)
synchronization (GPS) between the identical hyperchaotic Cai systems (20) and (21).
( )2 2 2 2
1 2 3 4( )
1 1
,
2 2
T
V e e e e e e e= = + + + (26)
.R
2 2 2 2
1 1 2 2 3 3 4 4( ) ,V e k e k e k e k e= − − − −& (27)
.R
The parameters of the identical hyperchaotic Cai systems are chosen as
27.5, 3, 19.3, 2.9, 3.3p q r s ε= = = = =
1 2 3 4(0) 15, (0) 26, (0) 10, (0) 8x x x x= = = − =

85
1 2 3 4(0) 21, (0) 17, (0) 34, (0) 12y y y y= − = = − =
The GPS scales are taken as
1 2 3 41.8, 0.6, 3.8, 2.7α α α α= − = = − =
We take the state feedback gains as
5ik = for 1,2,3,4.i =
Figure 5 shows the GPS synchronization of the identical hyperchaotic Cai systems.
Figure 6 shows the time-history of the GPS synchronization errors for the identical hyperchaotic
Cai systems.
Figure 5. GPS Synchronization of the Identical Hyperchaotic Cai Systems

86
6. GPS OF HYPERCHAOTIC LÜ AND HYPERCHAOTIC CAI SYSTEMS
synchronization (GPS) of hyperchaotic Lü and hyperchaotic Cai systems.
Thus, the master system is described by the hyperchaotic Lü dynamics
1 2 1 4
2 2 1 3
3 3 1 2
4 4 1 3
( )x a x x x
x cx x x
x bx x x
x dx x x
= − +
= −
= − +
= +
&
&
&
&
(28)
where 1 2 3 4, , ,x x x x are the states and , , ,a b c d are constant, positive parameters of the system.
The slave system is described by the controlled hyperchaotic Cai dynamics
1 2 1 1
2 1 2 4 1 3 2
2
3 3 2 3
4 1 4
( )y p y y u
y qy ry y y y u
y sy y u
y y uε
= − +
= + + − +
= − + +
= − +
&
&
&
&
(29)

87
where 1 2 3 4, , ,y y y y are the states, , , , ,p q r s ε are positive, constant parameters of the system and
1 2 3 4, , ,u u u u are the active nonlinear controls to be designed.
, ( 1,2,3,4)i i i ie y x iα= − = (30)
[ ]
[ ]
[ ]
[ ]
1 2 1 1 2 1 4 1
2 1 2 4 1 3 2 2 1 3 2
2
3 3 2 3 3 1 2 3
4 1 4 4 1 3 4
( ) ( )e p y y a x x x u
e qy ry y y y cx x x u
e sy y bx x x u
e y dx x x u
α
α
α
ε α
= − − − + +
= + + − − − +
= − + − − + +
= − − + +
&
&
&
&
(31)
[ ]
[ ]
[ ]
[ ]
1 2 1 1 2 1 4 1 1
2 1 2 4 1 3 2 2 1 3 2 2
2
3 3 2 3 3 1 2 3 3
4 1 4 4 1 3 4 4
( ) ( )u p y y a x x x k e
u qy ry y y y cx x x k e
u sy y bx x x k e
u y dx x x k e
α
α
α
ε α
= − − + − + −
= − − − + + − −
= − + − + −
= + + −
(32)
where the gains 1 2 3 4, , ,k k k k are positive constants.
1 1
2 2
3 3
4 4
1
2
3
4
e k e
e k e
e k e
e k e
= −
= −
= −
= −
&
&
&
&
(33)
synchronization (GPS) between the hyperchaotic Lü system (28) and hyperchaotic Cai system
(29).
( )2 2 2 2
1 2 3 4( )
1 1
,
2 2
T
V e e e e e e e= = + + + (34)
.R

88
2 2 2 2
1 1 2 2 3 3 4 4( ) ,V e k e k e k e k e= − − − −& (35)
.R
The parameters of the hyperchaotic Lü system are chosen as
36, 3, 20, 1.3a b c d= = = =
The parameters of the hyperchaotic Cai system are chosen as
27.5, 3, 19.3, 2.9, 3.3p q r s ε= = = = =
1 2 3 4(0) 12, (0) 24, (0) 39, (0) 17x x x x= = = − = −
1 2 3 4(0) 11, (0) 28, (0) 7, (0) 20y y y y= − = = =
The GPS scales are taken as
1 2 3 42.1, 1.5, 3.6, 0.6α α α α= = − = − =
We take the state feedback gains as
5ik = for 1,2,3,4i =
Figure 7 shows the GPS synchronization of the non-identical hyperchaotic Lü and hyperchaotic
Cai systems.
Figure 8 shows the time-history of the GPS synchronization errors 1 2 3 4, , ,e e e e for the non-
identical hyperchaotic Lü and hyperchaotic Cai systems.

89
Figure 7. GPS Synchronization of the Hyperchaotic Lü and Hyperchaotic Cai Systems

90
7. CONCLUSIONS
In this paper, we had derived active control laws for achieving generalized projective
synchronization (GPS) of the following pairs of hyperchaotic systems:
(A) Identical Hyperchaotic Lü Systems (2006)
(B) Identical Hyperchaotic Cai systems (2009)
(C) Non-identical Hyperchaotic Lü and Hyperchaotic Cai systems
The synchronization results (GPS) derived in this paper for the hyperchaotic Lü and hyperchaotic
Cai systems have been proved using Lyapunov stability theory. Since Lyapunov exponents are
not required for these calculations, the proposed active control method is very effective and
suitable for achieving GPS of the hyperchaotic systems addressed in this paper. Numerical
simulations are shown to demonstrate the effectiveness of the GPS synchronization results
derived in this paper for the hyperchaotic Lü and hyperchaotic Cai systems.
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92
Authors
Mrs. P. Sarasu obtained her M.E. degree in Embedded System Technologies from Anna
University, Tamil Nadu, India in 2007. She obtained her B.E. degree in Computer Science
Engineering from Bharatidasan University, Trichy, India in 1998. She is working as an
Assistant Professor in the Faculty of Computer Science Engineering, Vel Tech Dr. RR &
Dr. SR Technical University, Chennai. She is currently pursuing her Ph.D degree in
Computer Science Engineering from Vel Tech Dr. RR & Dr. SR Technical University,
Chennai. She has published several papers in International Journals and International
Conferences. Her current research interests are chaos, control, secure communication and
embedded systems.
Dr. V. Sundarapandian obtained his Doctor of Science degree in Electrical and
Systems Engineering from Washington University, Saint Louis, USA under the
guidance of Late Dr. Christopher I. Byrnes (Dean, School of Engineering and Applied
Science) in 1996. He is a Professor in the Research and Development Centre at Vel
Tech Dr. RR & Dr. SR Technical University, Chennai, Tamil Nadu, India. He has
published over 240 refereed international publications. He has published over 100
papers in National Conferences and over 60 papers in International Conferences. He is
the Editor-in-Chief of International Journal of Mathematics and Scientific Computing,
International Journal of Instrumentation and Control Systems, International Journal of
Control Systems and Computer Modelling, etc. His research interests are Linear and Nonlinear Control
Systems, Chaos Theory and Control, Soft Computing, Optimal Control, Process Control, Operations
Research, Mathematical Modelling and Scientific Computing. He has delivered several Key Note Lectures
on Linear and No nlinear Control Systems, Chaos Theory and Control, Scientific Computing using
MATLAB/SCILAB, etc.

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