Chaos Synchronization of Nonlinear Fractional Discrete Dynamical Systems via Linear Control

Abstract: By using a linear feedback control technique, we propose a chaos synchronization scheme for nonlinear fractional discrete dynamical systems. Then, we construct a novel 1-D fractional discrete income change system and a kind of novel 3-D fractional discrete system. By means of the stability principles of Caputo-like fractional discrete systems, we lastly design a controller to achieve chaos synchronization, and present some numerical simulations to illustrate and validate the synchronization scheme.

Chaos synchronization has been a hot topic [17][18][19].There are many synchronization schemes for fractional differential systems, such as synchronization via the linear control technique [20], synchronization via the adaptive sliding mode [21], projective synchronization via single sinusoidal coupling [22], hybrid chaos synchronization with a robust method [23], synchronization with activation feedback control [24], synchronization via a scalar transmitted signal [25], adaptive synchronization via a single driving variables [26], synchronization via novel active pinning controls [27].In fact, most mentioned synchronization schemes of fractional differential systems can be used in the synchronization of fractional discrete dynamical systems.
To date, only four synchronization schemes have been proposed for fractional discrete dynamical systems, as follows: chaos synchronization based on the stability condition [8], chaos synchronization with a nonlinear coupling method [28], and chaos synchronization with linear coupling strength [29]; exact synchronization is established by designing a step-by-step delayed observer [30].Just as the linear feedback control technique can be employed to achieve the synchronization of fractional differential systems, one may spontaneously want to know whether or not it can be used to obtain the synchronization of fractional discrete dynamical systems.
Linear feedback control is an economic, robust and easily implemented control technique available for chaos synchronization [31].Odibat et al. [20] designed a kind of synchronization scheme for three-dimensional chaotic fractional-order systems.Xin et al. employed the linear feedback control technique to design projective synchronization schemes for chaotic discrete dynamical systems [32] and fractional differential dynamical systems [33][34][35], respectively.In this paper, the linear feedback control technique will be applied to achieve the synchronization of fractional discrete dynamical systems.Comparing the aforementioned four synchronization schemes for fractional discrete dynamical systems [8,[28][29][30], the linear feedback control technique is not only easier to design and implement but is also more intuitive for the simplest linear stability theory of fractional discrete dynamical systems.
The remainder of this paper is organized as follows: in Section 2, preliminaries are presented.In Section 3, a synchronization scheme for n-dimensional nonlinear fractional discrete dynamical systems is proposed.The proposed synchronization scheme is applied to novel 1-D income change systems in Section 4, and novel 3-D fractional discrete dynamical systems in Section 5. Finally, the paper is concluded in Section 6.

Preliminaries
Some definitions of fractional discrete time calculus are introduced as follows.

A Synchronization Scheme of Nonlinear Fractional Discrete Dynamical Systems
Consider the following nonlinear fractional discrete dynamical system: (8)   where C ∆ ν a is the left Caputo-like delta difference, x = (x 1 , x 2 , • • • , x n ) T ∈ R n is an n-dimensional state vector of system (8), and L, N : R n → R n are linear and nonlinear functions of states, respectively.
Correspondingly, one may construct the following nonlinear fractional discrete dynamical system: (9)   where y = (y 1 , y 2 , • • • , y n ) T ∈ R n is an n-dimensional state vector of system (9), Defining the following synchronization error between the master system (8) and the slave system ( 9): The linear state error feedback controller u(t) can be defined as follows: where Â is an n × n linear constant matrix.Subtracting ( 8) from ( 9), the following error system can be obtained: where A = L + Â is an n × n linear constant matrix.Obviously, the original point is the fixed point of system (12), so one can directly obtain the following theorem by means of Theorem 2.

A Fractional Discrete Dynamical Income Change System
Puu and Sushko [39] presented the following chaotic discrete dynamical income system with cubic nonlinearity: with x denoting the change of income between the two previous periods, and ϕ ≥ 0. One can introduce the discrete fractional calculus into system (13) as follows: Figure 1a shows solutions of system (14), which are chaotic.Figure 1b is a superposed diagram of bifurcation and the largest Lyapunov exponents with ϕ ∈ [0.6, 1.4] and ν = 0.7.When ϕ = 1.4, the largest Lyapunov exponent λ = 0.386 which means that chaos occurs in system (14).

A Synchronization Scheme of Fractional Discrete Dynamical Income Change Systems
One can regard system ( 14) as the master system and construct the following slave system (denoted by the subscript s): where u(t + ν − 1) is the linear state error feedback controller.
Proposition 1.If the following control laws hold, the master-slave systems ( 14) and ( 15) will finally achieve global projective synchronization for any initial condition: Proof.One can define the synchronization errors between the master-slave systems ( 14) and (15) as follows: Subtracting system ( 14) from (15), one may get the following error system: Substituting Equation ( 16) into the error system (18), the following error system can be obtained: which has a trivial solution e(t) = 0, and the following equation holds: With Theorem 2, one can find that system (19) is asymptotically stable, i.e., the master system ( 14) and the slave system (15) finally achieve synchronization, as shown in Figure 2.
The Proposition 1 is thus proved.

A Novel Three-Dimensional Fractional Discrete Dynamical System
In this section, we present a novel three-dimensional fractional chaotic discrete dynamical system as follows: where θ ≥ 0. By introducing the discrete fractional calculus into system (21), one may get: Figure 3a shows a chaotic attractor of system (22) , and Figure 3b shows a superposed diagram of bifurcation and the largest Lyapunov exponents with θ ∈ [0, 0.1] and ν = 0.9.When θ = 0.1, the largest Lyapunov exponent λ = 0.066 which also implies that chaos exists in system (22).

A Synchronization Scheme of the Novel Three-Dimensional Fractional Discrete Dynamical Systems
System ( 14) can be regarded as the master system, and the slave system (denoted by the subscript s) can be constructed as follows: where u x (t + ν − 1), u y (t + ν − 1) and u z (t + ν − 1) are linear state error feedback controllers.
Proposition 2. If the following control laws hold, the master-slave systems ( 22) and ( 23) will finally achieve global projective synchronization for any initial condition: Proof.One can define the following synchronization errors between the master-slave systems ( 22) and ( 23): Subtracting system ( 22) from ( 23), one may get the following error system: Substituting Equation ( 24) into the error system (26), the following error system can be obtained: which has a trivial solution e(t) = 0, and the following equation holds.
With Theorem 2, one can find that the system (27) is asymptotically stable, i.e., the master system (22) and the slave system (23) finally achieve synchronization, as shown in Figure 4.

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The proposed 1-D fractional discrete income change system and a kind of novel 3-D fractional chaotic discrete system are employed to implement some interesting numerical simulations, which coincide well with the mentioned results.

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The proposed chaos synchronization scheme via the linear feedback control technique is very robust and easy to implement efficiently, and should have additional interesting applications in the future, such as secure communications, information storage, message identification, encryption and decryption.

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It is necessary for us to employ other control techniques, such as active control, sliding mode control, and pinning control, to achieve chaos synchronization of nonlinear fractional discrete dynamical systems.

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It will be challenging and interesting to expand the mentioned results to study the anti-synchronization or finite-time synchronization of the fractional discrete dynamic systems via the linear feedback control technique or others.