Chaotic Dynamics in Smart Grid and Suppression Scheme via Generalized Fuzzy Hyperbolic Model

This paper presents a method to control chaotic behavior of a typical Smart Grid based on generalized fuzzy hyperbolic model (GFHM). As more and more distributed generations (DG) are incorporated into the Smart Grid, the chaotic behavior occurs increasingly. To verify the behavior, a dynamic model which describes a power system with DG is presented firstly. Then, the simulation result shows that the power system can lead to chaos under certain initial conditions. Based on the universal approximation of GFHM, we confirm that the chaotic behavior could be suppressed by a new controller, which is designed by means of solving a linear matrix inequality (LMI). This approach could make a good application to suppress the chaos in Smart Grid. Finally, a numerical example is given to demonstrate the effectiveness of the proposed chaotic suppression strategy.


Introduction
Various types of stability problems in power systems, such as voltage collapse and oscillatory phenomenon, can be analyzed through chaotic theory [1].Thus, chaos analysis has become an important analysis tool in stability studies of power networks.A chaotic system is a very special nonlinear dynamical system and it possesses several properties such as sensitivity to initial conditions, as well as an irregular, unpredictable behavior, and thereby confines the precise operation of the system.Such problems led to many severe events in the past [2,3].Therefore, various effective methods have been proposed in the past decades to achieve the control and stabilization of chaotic systems, such as the LMI optimization approach [4], the nonfeedback method [5], inverse optimal control [6], the sliding method control [7],  ∞ control [8,9], impulsive control [10], backstepping design technique [11], cascade adaptive control [12], and the switching control [13].However, although these references focus on restraining chaotic behavior, most of them are based on theoretical models and are not yet associated with power systems.Moreover, some previous articles which are devoted to chaos in power systems just consider traditional networks.
By contrast, they neglect the uncertainty caused by Smart Grid.The reason is that when distributed generation parallels in the grid, some system state changes [14][15][16].
Motivated by the aforementioned discussion, this study aims to present a control scheme to suppress chaos of a specific Smart Grid.To achieve this target, we innovatively come up with a dynamic model and then provide initial conditions which lead to the system falling into chaos.Then we establish a novel fuzzy model based on GFHM.In this model, we can simplify the task of assigning the performance of the closed-loop system.Finally, a novel controller is designed by solving a LMI to guarantee the stability of sliding motion and thereby achieve chaos suppression of the specific system.
The rest of the report is designed as follows.First of all, the fourth-order differential equation model of a typical Smart Grid is put forward via analytical modeling method where the wind turbine generator (WTG) is considered as the distributed source.Based on the established explicit mathematical model of the considered Smart Grid, when the system's parameters lie in a certain region, chaos is generated in the system, which yields greatly disadvantageous influences on the power grid.Secondly, by virtue of the 2 Mathematical Problems in Engineering universal approximation of GFHM, the chaotic system is approximated by a simple fuzzy model with prescribed precision.Then the sufficient conditions for the stabilization of the closed-loop system are derived based on a lemma and the controller gain matrices can be obtained by solving a LMI.In this way, a corresponding controller can be realized to suppress the chaotic behavior.Finally, a numerical example is given to demonstrate the effectiveness of the proposed chaotic suppression strategy.

Chaotic Dynamics in Smart Grid
2.1.System Model and Data.In order to analyze the electrical parameter variation, a typical infrastructure of Smart Grid has been examined in Figure 1.In the model, a power station is connected to an infinite Bus 1 through a purely inductive line.Bus 2 connects a WTG and there is a dynamic load at Bus 3. The system is connected to Bus 4.
Here, we suppose   ( = 1, 2, 3, 4) is the corresponding impedance of the system and  is the angle of impedance.The voltage of infinite Bus 4 is  1 and its phase is 0. WTG works as a DG.It is a sixth-order model.Its model can be represented as follows [17]: where   is the rotator angle,  is the generator inertia,   is the damping factor per unit,   is the generator input torque, and   is the generator output torque.The load at Bus 3 is chosen as the dynamic model: ( The dynamic equations describing the system are conducted as follows.When we interconnect WTG with the power grid, the WTG should not influence the voltage of the connecting point.Therefore, the current will be the same before and after the WTG interconnection: The PWM inverter is used in this model to transform the interface circuit when we interconnect the WTG with the power grid [18].According to the active power and reactive power, output of the PWM inverter is decoupled and thus they can be controlled, respectively.In this paper, we suppose that the output reactive power of WTG cancels the reactive power of Bus 1 at the interconnecting point.For the sake of convenience, the output active power current  0 of PWM inverter is used to represent the output active power of the WTG.Consequently, the output current of PWM inverter is The current flow through  3 is The current flow through  4 is The current at Bus 3 is The power supplied at Bus 3 is The active power and reactive power at Bus 3 are The deduced process of the active power for the power station is as follows: So the active power for the power station is where Re{ } represents the real part of {•}, î * 7 represents the conjugate part of î7 , and  G is equal to the generator output torque   . According to (11), the balance of active power and reactive power at Bus 3, and the system parameter values in Tables 1, 2, and 3 [17,19], the system mathematic representation is derived as 2.2.Chaotic Behavior in Smart Grid.As we can see, the dynamics of (12) depend on five independent parameters, which makes a complete search in this large parameter space rather tedious.Since there is no simple method to predict which region of the parameter space is likely to yield chaotic solutions, some subsets (  , ,  L ,  L )  of parameters are kept fixed while the inverter current  0 is taken as a control parameter and allowed to vary arbitrarily.Assume  = ( 1 ,  2 ,  3 ,  4 )  = (  , ,  L ,  L )  .After searching several subsets , we observed chaotic phenomenon when  = (0.3, 0.2, 0.1, 0.97)  and  0 = 0.01.Simulations of chaotic state response and Lyapunov From these figures, we can see that as time elapses,  does not return to its equilibrium state.On the contrary, it enters into a disorganized oscillation.This phenomenon proves that the system causes chaotic behavior.In addition, the positive Lyapunov exponent proves this conclusion.

Controller Design Based on GFHM
Aiming at systems with severe nonlinearity and strong coupling, such as the model considered here, the GFHM with universal approximation provides a useful approach to design a controller.We can utilize GFHM to approximate the system in arbitrary precision so as to provide a theoretical basis of controlling a strong nonlinear chaotic system.Furthermore, the corresponding controller based on GFHM can be designed via intelligent control theory.Therefore, the equivalent model of Smart Grid based on GFHM brings convenience to controller synthesis.

Review of a GFHM.
In 2001, Zhang and Quan came up with a brand-new fuzzy model, which is the GFHM [20].In this model, there are two types of fuzzy sets, including Positive (  ) and Negative (  ).The membership functions   and   are defined as where   > 0. However, only two fuzzy sets are not able to cover the whole input space.In order to make the model a universal approximator, we define new variables   by transforming the input variables   as follows: where  = 1, . . .,  ( is a positive integer) and   is a constant.We can see that, after the transformation of the input variables   , the fuzzy sets will cover the whole input space if  is large enough.Before defining the GFHM, the definition of generalized input variables and the generalized fuzzy hyperbolic rule base are given first.Definition 2. Given a plant with  input variables  1 (),  2 (), . . .,   () and an output variable ẋ , the generalized input variables are defined as Definition 1.And the fuzzy rule base is called the generalized fuzzy hyperbolic rule base if the following conditions are satisfied.
(2) The constants    ( = 1, . . ., ,  = 1, . . .,   ) in the THEN-part correspond to    in the IF-part.That is, if there is    in the IF-part,    must appear in the THEN-part; otherwise,    does not appear in the THEN-part.
(3) There are  = 2  fuzzy rules in the rule base, where  = ∑  =1   , that is, all the possible   and   combinations of input variables in the IF-part and all the linear combinations of constants in the THENpart.
Lemma 4. For any real continuous function  defined in  ⊂   and an arbitrary  > 0, there exists a system  based on GFHM that makes sup ∈ |() − ()| < .
Remark 5. Lemma 4 indicates that the GFHM has universal approximation, and thus the GFHM can be used to approximate the chaotic Smart Grid system in any precision theoretically.Therefore, we can stabilize the GFHM instead of the original strong nonlinearity system.

Chaotic Suppression Strategy
. Now, we focus on designing a new controller, which stabilizes an equilibrium point of the closed-loop deterministic system for the corresponding chaotic system.According to Lemma 4, the GFHM of Smart Grid can be established by parameter identification method [21].Since it is significant to transform the equilibrium point to the origin point before establishing its GFHM, the GFHM of the chaotic Smart Grid system is expressed as and  are obtained by matrix based on system identification: Therefore, the strong nonlinear system (12) can be represented as ẋ = ( +  0 ) tanh . ( The following theorem will give the advanced suppression strategy to the chaotic Smart Grid system.Theorem 6.If there is a positive-definite diagonal matrix  and a positive scalar  0 such that the following LMI (19) holds, then the chaotic Smart Grid system can be stabilized asymptotically: Proof.Denotethe Lyapunov function as where   > 0 ( = 1, 2, 3, 4), and then we can get where  = diag( 1 ,  2 ,  3 ,  4 ) > 0.
Combining system (18), we can obtain where  0 is the output active power current of the PWM inverter.Hence, when the LMI (19) holds, (22) is negative.So the system (18) can be stabilized asymptotically.
Remark 7. In the above theorem, the stabilization condition for a closed-loop chaotic Smart Grid system is obtained based on the GFHM.Obviously, a new controller is designed by means of solving a LMI.

Simulation Study
With simulation study, we can illustrate the effectiveness of the proposed suppression scheme for (12).Here, we choose the same initial condition in Section 2 and the matrix  is chosen as a unit matrix.By solving (19), we can get  0 = 0.2.
The state response curves of controlled system are shown in Figures 7,8,9, and 10 which, respectively, denote the stable state response curves ( 1 ,  2 ,  3 ,  4 ).Since we have observed chaotic phenomenon before when  = ( 1 ,  2 ,  3 ,  4 )  = (  , ,  L ,  L )  = (0.3, 0.2, 0.1, 0.97)  , the initial values of subsets  are also set as  = (0.3, 0.2, 0.1, 0.97)  to demonstrate the effectiveness of the proposed suppression scheme based on generalized fuzzy hyperbolic model.From these figures, we can see that the state response curves ( 1 ,  2 ,  3 ,  4 ) of original controlled system return to the equilibrium state after several fluctuations.The simulation results show that the proposed controller can suppress chaos in the Smart Grid successfully.

Conclusion
In this paper, we have studied a typical Smart Grid with strong coupling and nonlinearity.In this research, it is shown that Smart Grid is more likely to fall into chaos, as more and more DG are incorporated.And a new controller is designed to suppress the chaos based on the GFHM, which will guarantee that the power network is stable.The numerical simulation demonstrates its effectiveness.