Projective Synchronization for a Class of Fractional-order Chaotic Systems with Fractional-order in the (1, 2) Interval

In this paper, a projective synchronization approach for a class of fractional-order chaotic systems with fractional-order 1 < q < 2 is demonstrated. The projective synchronization approach is established through precise theorization. To illustrate the effectiveness of the proposed scheme, we discuss two examples: (1) the fractional-order Lorenz chaotic system with fractional-order q = 1.1; (2) the fractional-order modified Chua's chaotic system with fractional-order q = 1.02. The numerical simulations show the validity and feasibility of the proposed scheme.

Over the last two decades, due to its potential applications in the field of science and engineering [11,12], more and more attention has been focused on synchronization of chaotic systems, and many synchronization schemes have been proposed.Among all, one particular synchronization scheme named projective synchronization has been proposed by Mainieri and Rehacek [13].A master and slave system could be synchronized up to a scaling factor in PS, which can be used to extend binary digital to M-nary digital communication for getting faster communications [13,14].
However, many previous synchronization methods [6][7][8][9][13][14][15][16] for fractional-order chaotic systems only focused on the fractional-order 1 0 < < q , when in fact, there are many fractional-order systems with fractional-order 1 < q < 2 in the real world.For example, the time fractional heat conduction equation [17], the fractional telegraph equation [18], the time fractional reaction-diffusion systems [19], the fractional diffusion-wave equation [20], the space-time fractional diffusion equation [21], the super-diffusion systems [22], etc., but the chaos phenomenon was not considered in [17][18][19][20][21][22].Meanwhile, based on numerical simulation, Ge and Jhuang [23] reported some results on synchronization of the fractional order rotational mechanical system with fractional-order q = 1.1.Up to now, to the best of our knowledge, there seem to be no results on chaotic synchronization for fractional-order chaotic systems with 1 < q < 2 through precise theorization.So, how to achieve the chaotic synchronization for fractional-order nonlinear systems with 1 < q < 2 through precise theorization is an interesting and opening question of academic significance as well as practical importance.Motivated by the abovementioned discussion, in this paper we propose a projective synchronization approach for a class of fractional-order chaotic systems with fractional-order 1 < q < 2 through precise theorization.To show the effectiveness of the proposed scheme, the projective synchronization for a fractional-order Lorenz chaotic system with fractional-order q = 1.1 and Chua's fractional-order modified chaotic system with fractional-order q = 1.02 are discussed, respectively.The numerical simulations have indicated the validity and feasibility of our scheme.

Problem Statement and Main Result
In this paper, the Caputo derivative of fractional order q for function f(t), is defined as is the m-th derivative in the usual sense, and denote the gamma function.Now, the following fractional-order chaotic system is considered: where 2 1 < < q is the fractional order, and are the linear part and nonlinear part in system (1), respectively.
In this paper, we only discuss a class of fractional-order chaotic systems which satisfy: , respectively.In fact, the nonlinear part )) ( ( t x h in many fractional-order chaotic systems such as the fractional-order Lorenz chaotic system [5,6], Chua's fractional-order modified chaotic system [24], the fractional-order Duffing chaotic system [7], the fractional-order Rossler chaotic system [8,9], the fractional-order Chen chaotic system [6][7][8], etc., all satisfy Equation (2).Now, we study how to realize the projective synchronization for fractional-order chaotic system (1).Select the fractional-order chaotic system (1) as master system, and choose the following controlled fractional-order system as slave system: Theorem.The real feedback controller in slave system ( 3) is chosen as . It is said to be a projective synchronization between master system (1) and slave system (3) if there exists a real matrix K such that: where

is the minimum absolute value of the real part of the eigenvalue of matrix
Proof.According to ( ) α ( ) ( ) e t y t x t = − , the error system between fractional-order system (1) and system (3) is described as:

t D y t x t Ae t h y t h x t u x t y t
, the system (4) can be rewritten as:

D e t Ae t h y t h x t K H x t e t
is the zero solution in error system (6).Now, let 10 e and 20 e be the initial conditions for system (6), so the solution ) (t e for system (6) can be shown as: t q q q q q q q q n e t

E A K t e tE A K t e t s E A K t s H e s x s ds
where 1 , q E , 2 , q E and q q E , are the two-parameter function of Mittag-Leffler type, i.e., ), and z is a variable.
For the Mittag-Leffler function ) ( , z E p q , the inequality (8) has been obtained in Reference [25]: According to Equation (7) and inequality (8), one has: ( ) [ ( ), ( )] q q q t q q q q q q q q n t A K t Now, the inequality ( 9) can be transformed as: So, the inequality (10) can be rewritten as:

e e N e e t t s e e s ds
That is: e t e N e N e t t s e e s ds According to the result in Reference [26], the inequality (12) can be changed as: Using the result in Reference [4]: , arg( ) ρ z ≤ ,and 0.5π min(π, π ) q q < ρ < , therefore, the inequality (13) can be changed to: q t q t q q q e t e N e N e t E q t N e N e t N e N q t That is: Since (16) Equation (16) indicates that the zero solution in error system ( 6) is asymptotically stable, so lim ( ) lim α ( ) ( ) 0 t t e t y t x t Hence, the projective synchronization between fractional-order chaotic system (1) and system (3) will be obtained.The proof is completed.□ We notice that some academics [27][28][29] have discussed complex dynamical networks with nondelayed and delayed coupling, the application of chaos synchronization to secure communication, and Takagi-Sugeno fuzzy systems with multiple state delays.Applying our results to these issues is our ongoing work.

Illustrative Example
To demonstrate the effectiveness of the projective synchronization method proposed in Section 2, we apply the synchronization scheme to the fractional-order Lorenz chaotic system with fractional-order 1 . 1 = q and the fractional-order modified Chua chaotic system with fractional-order 02 . 1 = q , respectively.
In order to realize the projective synchronization for the fractional-order Lorenz chaotic system (17), the system (17) is selected as master system, so the slave system can be constructed as follows:

D y y y D y y y h y K H x e D y y
where , and α ( 1,2,3) T denotes the transposition for matrix: Obviously,  in slave system ( 18) is chosen as: Now, it is easy to verify the following:  Based on the Theorem in Section 2, a suitable non-zero constant α and constant real matrix K can be selected such that Re[λ( α )] 0 are held, so the projective synchronization between the fractional-order Lorenz chaotic system (17) and the controlled fractional-order Lorenz chaotic system (18) can be achieved.
For example, let

Projective Synchronization of Fractional-Order Modified Chua's Chaotic System with
In 1971, Chua's chaotic circuit was discovered by Chua [30].In 2010, Muthuswamy and Chua [24] reported the simplest modified Chua chaotic circuit, which consists of a linear passive inductor, a linear passive capacitor, and a non-linear active memristor.The simplest modified Chua chaotic circuit system [24] can be shown as: Its fractional-order system is named fractional-order modified Chua chaotic system, and it can be described as follows: The fractional-order modified Chua's system (19) displays a chaotic attractor with 02 . 1 = q .
The chaotic attractor is shown in Figure 3.
In order to realize the projective synchronization for the fractional-order chaotic system (19), the system ( 19) is chosen as master system, so the slave system can be constructed as follows: where Now, it is easy to verify the following:   According to the boundedness of modified Chua's chaotic system, there exist a real positive constant M such that ( ) The above results imply that the Conditions (i) in the Theorem are satisfied.Based on the above Theorem in Section 2, a suitable non-zero constant α 0.5 = − and constant real matrix K can be selected such that Re hold, so the projective synchronization between the fractional-order modified Chua chaotic system (19) and the controlled fractional-order modified Chua chaotic system (20) can be achieved.In Figures 4a-c, the solid lines refer to attractors of system (19), and the dashed lines refer to attractors of system (20), respectively.Projective synchronization errors between system (19) and system (20)

Conclusions
In this paper, a projective synchronization approach is proposed for a class of fractional-order chaotic system with 2 1 < < q . Our approach can be applied to a class of nonlinear fractional-order chaotic systems, in which the nonlinear terms in the chaotic system satisfy Equation (2).To demonstrate the effectiveness of proposed projective synchronization scheme, we apply the synchronization scheme to the fractional-order Lorenz chaotic system with 1 . 1 = q and Chua's fractional-order modified chaotic system with 02 . 1 = q , respectively.The numerical simulations show the validity and feasibility of the proposed scheme.