Abstract

This paper proposes the generalized projective synchronization for chaotic heavy symmetric gyroscope systems versus external disturbances via sliding rule-based fuzzy control. Because of the nonlinear terms of the gyroscope, the system exhibits complex and chaotic motions. Based on Lyapunov stability theory and fuzzy rules, the nonlinear controller and some generic sufficient conditions for global asymptotic synchronization are attained. The fuzzy rules are directly constructed subject to a common Lyapunov function such that the error dynamics of two identical chaotic motions of symmetric gyros satisfy stability in the Lyapunov sense. The proposed method allows us to arbitrarily adjust the desired scaling by controlling the slave system. It is not necessary to calculate the Lyapunov exponents and the Eigen values of the Jacobian matrix. It is a systematic procedure for synchronization of chaotic systems. It can be applied to a variety of chaotic systems no matter whether it contains external excitation or not. It needs only one controller to realize synchronization no matter how much dimensions the chaotic system contains, and the controller is easy to be implemented. The designed controller is robust versus model uncertainty and external disturbances. Numerical simulation results demonstrate the validity and feasibility of the proposed method.

1. Introduction

Dynamic chaos is a very interesting nonlinear effect which has been intensively studied during the last three decades. Chaotic phenomena can be found in many scientific and engineering fields such as biological systems, electronic circuits, power converters, and chemical systems [1].

Since the synchronization of chaotic dynamical systems has been observed by Pecora and Carroll [2] in 1990, chaos synchronization has become a topic of great interest [3–5]. Synchronization phenomena have been reported in the recent literature. Until now, different types of synchronization have been found in interacting chaotic systems, such as complete synchronization [2, 6, 7], generalized synchronization [8], phase synchronization [9], and antiphase synchronization [10]. In 1999, projective synchronization has been first reported by Mainieri and Rehacek [11] in partially linear systems that the master and slave vectors synchronize up to a constant scaling factor Ξ± (a proportional relation). Later, some researchers have extended synchronization to a general class of chaotic systems without the limitation of partial linearity, such as non-partially-linear systems [12, 13]. After that, a new synchronization, called generalized projective synchronization (GPS), has been observed in the nonlinear chaotic systems [14–16].

On the other hand, the dynamics of a gyro is a very interesting nonlinear problem in classical mechanics. The gyro has attributes of great utility to navigational, aeronautical, and space engineering [17]. Gyros for sensing angular motion are used in airplane automatic pilots, rocket-vehicle launch guidance, space-vehicle attitude systems, ship’s gyrocompasses, and submarine inertial autonavigators. The concept of chaotic motion in a gyro was first presented in 1981 by Leipnik and Newton [18], showing the existence of two strange attractors. In the past years, gyros have been found with rich phenomena which give benefit for the understanding of gyro systems. Different types of gyros with linear/nonlinear damping are investigated for predicting the dynamic responses such as periodic and chaotic motions [17, 19, 20]. Some methods have been presented to synchronize two identical/nonidentical nonlinear gyro system such as active control [21] and neural sliding mode control [7, 8].

The goal of this paper is to synchronize two chaotic heavy symmetric gyroscope systems versus external disturbances. To achieve this goal, sliding rule-based fuzzy control is applied. In addition, the results of this paper may be extended to synchronize many classes of nonlinear chaotic systems.

This paper is organized as follows. In Section 2, dynamics of a heavy symmetric gyroscope system are described. Generalized synchronization problem is explained in Section 3. In Section 4, sliding rule-based fuzzy control is designed to chaos synchronization of chaotic gyroscopes. Simulations are presented in Section 5, to show the effectiveness of the proposed control method to chaos synchronization of chaotic gyroscope systems versus disturbances. At the end, the paper is concluded in Section 6.

2. Chaotic Gyroscope System

The symmetric gyroscope mounted on a vibrating base is shown in Figure 1. The dynamics of a symmetrical gyro with linear-plus-cubic damping of angle πœƒ can be expressed as [17] Μˆβ€Œπœƒ+𝛼21(1βˆ’cosπœƒ)2sin3πœƒβˆ’π›½1sinπœƒ+𝑐1Μ‡β€Œπœƒ+𝑐2Μ‡β€Œπœƒ3=𝑓sinπœ”π‘‘sinπœƒ,(1) where 𝑓sinπœ”π‘‘ is a parametric excitation, 𝑐1Μ‡β€Œπœƒ and 𝑐2Μ‡β€Œπœƒ3 are linear and nonlinear damping terms, respectively, and 𝛼21((1βˆ’cosπœƒ)2/sin3πœƒ)βˆ’π›½1sinπœƒ is a nonlinear resilience force. According to [17], in a symmetric gyro mounted on a vibrating base, the precession and the spin angles have cyclic motions, and hence their momentum integrals are constant and equal to each other. So the governing equations of motion depend only on the mutational angle πœƒ. Using Routh’s procedure and assuming a linear-plus-cubic form for dissipative force, (1) is obtained [17]. Given the states π‘₯1=πœƒ, π‘₯2=Μ‡β€Œπœƒ, and 𝑔(πœƒ)=𝛼21((1βˆ’cosπœƒ)2/sin3πœƒ)βˆ’π›½1sinπœƒ, (19) can be rewritten as follows: Μ‡π‘₯1=π‘₯2,Μ‡π‘₯2=𝑔π‘₯1ξ€Έβˆ’π‘1π‘₯1βˆ’π‘2π‘₯32+𝛽+𝑓sinπœ”π‘‘ξ€Έsinξ€·π‘₯1ξ€Έ.(2)

This gyro system exhibits complex dynamics and has been studied by [20] for values of 𝑓 in the range 32<𝑓<36 and constant values of 𝛼21=100, 𝛽1=1, 𝑐1=0.5, 𝑐2=0.05, and πœ”2. Figure 2 illustrates the irregular motion exhibited by this system for 𝑓=35.5 and initial conditions of (π‘₯1,π‘₯2)=(1,βˆ’1).

In the next section, the chaos synchronization problem has been explained.

3. Generalized Projective Synchronization Problem

Consider two coupled, chaotic gyroscope systems, where the master and slave systems are denoted by π‘₯ and 𝑦, respectively. The master system is presented in (2). The slave system is presented as follows: ̇𝑦1=𝑦2,̇𝑦2=𝑔𝑦1ξ€Έβˆ’π‘1𝑦1βˆ’π‘2𝑦32+(𝛽+𝑓sinπœ”π‘‘)sin𝑦1ξ€Έ=𝑒(𝑑).(3)

Defining the generalized synchronization errors between the master and slave systems as follows: 𝐸(𝑑)=𝑒1(𝑑)=𝑦1(𝑑)βˆ’π›Όπ‘₯1(𝑑),𝑒2(𝑑)=𝑦2(𝑑)βˆ’π›Όπ‘₯2(𝑑),(4) where π›Όβˆˆπ‘… is a scaling factor that defines a proportional relation between the synchronized systems. Then, the error dynamics can be obtained as ̇𝑒1(𝑑)=𝑒2(𝑑),̇𝑒2(𝑑)=(1βˆ’π›Ό)𝑝π‘₯1,π‘₯2,𝑦1,𝑦2ξ€Έ+𝑒(𝑑).(5)

In order to simplify the following procedure, a nonlinear function is defined as follows: 𝑝π‘₯1,π‘₯2,𝑦1,𝑦2ξ€Έ=𝑔𝑦1ξ€Έβˆ’π‘1𝑦1βˆ’π‘2𝑦32+(𝛽+𝑓sinπœ”π‘‘)sin𝑦1ξ€Έ1βˆ’π›Όβˆ’π›Όπ‘”ξ€·π‘₯1ξ€Έβˆ’π‘1π‘₯1βˆ’π‘2π‘₯32+(𝛽+𝑓sinπœ”π‘‘)sinξ€·π‘₯1ξ€Έ1βˆ’π›Ό.(6)

The objective of the synchronization problem is to design the appropriate control signal 𝑒(𝑑) such that for any initial conditions of the master and slave systems, the synchronization errors converge to zero such that the resulting synchronization error vector satisfies. limπ‘‘β†’βˆžβ€–πΈ(𝑑)β€–βŸΆ0,(7) where β€–β‹…β€– is the Euclidean norm of a vector. In the next section, the control input will be obtained via sliding rule-based fuzzy control to achieve the synchronization goal presented in previous section.

4. Generalized Projective Synchronization of Chaotic Gyroscopes versus Disturbances via Sliding Rule-Based Fuzzy Control

The scheme of GPS of chaotic gyroscope systems versus disturbances via the fuzzy system based on sliding mode control is shown in Figure 3. First, sliding surface is designed for chaos synchronization of chaotic gyroscope systems. An appropriate observer is designed for the linear part of the slave system. Then, sliding rule-based fuzzy control is designed as a control to synchronize the master and the slave systems, with considering the external disturbances.

4.1. Sliding Surface

Using the sliding mode control method for GPS of chaotic gyroscope systems, involves two basic steps:(1)selecting an appropriate sliding surface such that the sliding motion on the sliding manifold is stable and ensures limπ‘‘β†’βˆžβ€–πΈ(𝑑)β€–β†’0;(2)establishing a robust control law which guarantees the existence of the sliding manifold 𝑆(𝑑)=0.

The sliding surfaces are defined as follows [22]: 𝑆(𝑑)=𝑑𝑑𝑑+π›Ώξ‚π‘›βˆ’1𝑒(𝑑),(8) where 𝑆(𝑑)βˆˆπ‘… and 𝛿 are real positive constant parameters. Differentiating (10) with respect to time is as follows: Μ‡β€Œπ‘†(𝑑)=𝑑𝑑𝑑+𝛿𝑛𝑒(𝑑).(9)

The rate of convergence of the sliding surface is governed by the value assigned to parameter 𝛿. Having established appropriate sliding surfaces, the next step is to design the control input to drive the error system trajectories onto the sliding surfaces.

In this study, define a sliding surface as 𝑆(𝑑)=𝑒2(𝑑)+𝛿𝑒1(𝑑).(10) Equation (10) is designed as the input of fuzzy system. Differentiating (10) with respect to time is as follows: Μ‡β€Œπ‘†(𝑑)=̇𝑒2(𝑑)+𝛿̇𝑒1(𝑑).(11) Substituting (5) into (12), we obtain Μ‡β€Œπ‘†(𝑑)=(1βˆ’π›Ό)𝑝π‘₯1,π‘₯2,𝑦1,𝑦2ξ€Έ+𝑒(𝑑)+𝛿𝑒2(𝑑).(12)

4.2. Sliding Rule-Based Fuzzy Control

A set of the fuzzy linguistic rules based on expert knowledge are applied to design the control law of fuzzy logic control. To overcome the trail-and-error tuning of the membership functions and rule base, the fuzzy rules are directly defined such that the error dynamics satisfies stability in the Lyapunov sense. The basic fuzzy logic system is composed of five function blocks [23]: (1) a rule base contains a number of fuzzy if-then rules, (2) a database defines the membership functions of the fuzzy sets used in the fuzzy rules, (3) a decision-making unit performs the inference operations on the rules, (4) a fuzzification interface transforms the crisp inputs into degrees of match with linguistic value, and (5) a defuzzification interface transforms the fuzzy results of the inference into a crisp output.

The fuzzy rule base consists of a collection of fuzzy if-then rules expressed as the form: if π‘Ž is 𝐴, then 𝑏 is 𝐡, where π‘Ž and 𝑏 denote linguistic variables, and 𝐴 and 𝐡 represent linguistic values that are characterized by membership functions. All of the fuzzy rules can be used to construct the fuzzy-associated memory.

In this study, the FLC is designed as follows: the signal 𝑆 in (10) is as the antecedent part of the proposed FLC to design the control input 𝑒 that will be used in the consequent part of the proposed FLC,𝑒=FLC(𝑆),(13) where the FLC accomplishes the objective to stabilize the error dynamics (5). The 𝑖th if-then rule of the fuzzy rule base of the FLC is of the following form.

Rule i
If 𝑆 is 𝑋, then 𝑒𝐿𝑖≑𝑓𝑖(𝑆),(14) where 𝑋 is the input fuzzy sets, 𝑒𝐿𝑖 is the output which is the analytical function 𝑓𝑖(β‹…) of the input variables (𝑆).
For given input values of the process variables, their degrees of membership πœ‡π‘₯𝑖, 𝑖=1,2,…,𝑛, called rule-antecedent weights, are calculated. The centroid defuzzifier evaluates the output of all rules as follows:𝑒=βˆ‘π‘›π‘–=1,πœ‡β‰ 0πœ‡π‘–β‹…π‘’πΏπ‘–βˆ‘π‘›π‘–=1,πœ‡β‰ 0πœ‡π‘–,πœ‡π‘–=πœ‡π‘‹(𝑆).(15)
Table 1 lists the fuzzy rule base in which the input variable in the antecedent part of the rules is 𝑆, and the output variable in the consequent is 𝑒𝐿𝑖.
Using 𝑃, 𝑍, and 𝑁 as input fuzzy sets represents β€œpositive,” β€œzero,” and β€œnegative,” respectively. The Gaussian membership function is considered. The combination of the two input variables (𝑆) forms 𝑛=3 heuristic rules in Table 1, and each rule belongs to one of the three fuzzy sets 𝑃, 𝑍, and 𝑁. The rules in Table 1 are read as follows: taking Rule 1 in Table 1 as an example, β€œRule 1: if input 1 𝑆 is 𝑃, then output is 𝑒𝐿1.”
To solve the control problem presented in (5), define a Lyapunov function as follows:𝑉(𝑑)=12𝑆2(𝑑).(16)
Differentiating (16) with respect to times is as follows:Μ‡β€Œπ‘‰=π‘†Μ‡β€Œπ‘†.(17)
Substituting (12) into (17), thenΜ‡β€Œπ‘‰=𝑆(1βˆ’π›Ό)𝑝π‘₯1,π‘₯2,𝑦1,𝑦2ξ€Έ+𝑒(𝑑)+𝛿𝑒2(𝑑)ξ€»ξ„Ώξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…ƒξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…€ξ…Œπ΄.(18)
The corresponding requirement of Lyapunov stability is [24]Μ‡β€Œπ‘‰<0.(19) If 𝐴<0, then the Lyapunov stability will be satisfied. The following cases will satisfy all the stability conditions.

Rule. If 𝑆>0, then 𝐴<0, so consider the consequent part of Rule 1, (1βˆ’π›Ό)𝑝π‘₯1,π‘₯2,𝑦1,𝑦2ξ€Έ+𝑒(𝑑)+𝛿𝑒2(𝑑)<0.(20)
Equation (20) can be simplified as follows:𝑒(𝑑)<βˆ’π›Ώπ‘’2(𝑑)βˆ’(1βˆ’π›Ό)𝑝π‘₯1,π‘₯2,𝑦1,𝑦2ξ€Έ.(21)
Let us choose the control input as follows such that (21) is satisfied:𝑒𝐿1=βˆ’π›Ώπ‘’2(𝑑)βˆ’(1βˆ’π›Ό)𝑝π‘₯1,π‘₯2,𝑦1,𝑦2ξ€Έβˆ’πœ†,(22) where πœ† is a positive constant value.

Rule. If π‘†βˆˆzero, then (1βˆ’π›Ό)𝑝π‘₯1,π‘₯2,𝑦1,𝑦2ξ€Έ+𝑒(𝑑)+𝛿𝑒2(𝑑)=βˆ’πœ‚sgn(𝑆),(23) where πœ‚ is a positive constant value. Equation (23) can be simplified as follows: 𝑒(𝑑)=βˆ’πœ‚sgn(𝑆)βˆ’(1βˆ’π›Ό)𝑝π‘₯1,π‘₯2,𝑦1,𝑦2ξ€Έβˆ’π›Ώπ‘’2(𝑑).(24)
Let us choose the control input as follows such that (24) is satisfied:𝑒𝐿2(𝑑)=βˆ’πœ‚sgn(𝑆)βˆ’(1βˆ’π›Ό)𝑝π‘₯1,π‘₯2,𝑦1,𝑦2ξ€Έβˆ’π›Ώπ‘’2(𝑑).(25)

Rule. If 𝑆<0, then 𝐴>0, so consider the consequent part of Rule 3, (1βˆ’π›Ό)𝑝π‘₯1,π‘₯2,𝑦1,𝑦2ξ€Έ+𝑒(𝑑)+𝛿𝑒2(𝑑)>0.(26)
Equation (26) can be simplified as follows:𝑒(𝑑)>βˆ’(1βˆ’π›Ό)𝑝π‘₯1,π‘₯2,𝑦1,𝑦2ξ€Έβˆ’π›Ώπ‘’2(𝑑).(27)
Let us choose the control input as follows such that (27) is satisfied:𝑒𝐿3(𝑑)=βˆ’(1βˆ’π›Ό)𝑝π‘₯1,π‘₯2,𝑦1,𝑦2ξ€Έβˆ’π›Ώπ‘’2(𝑑)+πœ†,(28) where πœ† is a positive constant value.

Therefore, all of the rules in the FLC can lead to Lyapunov stable subsystems under the same Lyapunov function (16). Furthermore, the closed-loop rule-based system equation (5) is asymptotically stable for each derivate of the Lyapunov function that satisfies Μ‡β€Œπ‘‰<0 in Table 1, that is, the error states guarantee convergence to zero.

5. Simulation Results

In this section, numerical simulations are given to demonstrate GPS of the chaotic gyros versus disturbances via the sliding rule-based fuzzy control. The parameters of nonlinear chaotic gyroscope systems are specified in Section 2.

The external disturbance 𝑑1 is attached between 3<𝑑<4 and 7<𝑑<8. The initial conditions of the master and slave systems are defined as follows: π‘₯1(0)π‘₯2(0)ξ‚„=1βˆ’1𝑇,𝑦1(0)𝑦2(0)𝑇=ξ‚ƒβˆ’22𝑇.(29)

Notice that, to reduce the system chattering, the sign functions are substituted with the saturation functions.

The time responses of the master and the slave system for GPS with 𝛼=0.5, complete synchronization 𝛼=1, and antisynchronization 𝛼=βˆ’1 are shown in Figures 4, 7, and 10, respectively.

Synchronization errors for GPS with 𝛼=0.5, complete synchronization 𝛼=1, and antisynchronization 𝛼=βˆ’1 are shown in Figures 5, 8, and 11, respectively. The errors illustrated in Figures 5, 8, and 11 converge asymptotically to zero.

In addition, the control input and sliding surface for GPS with 𝛼=0.5, complete synchronization 𝛼=1, and antisynchronization 𝛼=βˆ’1 are shown in Figures 6, 9, and 12, respectively.

The simulation results of GPS via the sliding rule-based fuzzy control have good performances and confirm that the master and the slave systems achieve the synchronized states, when external disturbance occurs. Also, these results demonstrate that the synchronization error states are regulated to zero asymptotically. It is observed that the proposed method is capable to GPS, when disturbances occur.

6. Conclution

In this paper, generalized projective synchronization of chaotic gyroscope systems with external disturbances via sliding rule-based fuzzy control has been investigated. Based on Lyapunov stability theory and fuzzy rules, the nonlinear controller and some generic sufficient conditions for global asymptotic synchronization are attained. To achieve GPS, it is clear that the proposed method is capable for creating a full-range GPS of all state variables in a proportional way. It also allows us to arbitrarily adjust the desired scaling by controlling the slave system. The advantages of this method can be summarized as follows:(i)it is a systematic procedure for GPS of chaotic gyroscope system;(ii)the controller is easy to be implemented;(iii)it is not necessary to calculate the Lyapunov exponents and the eigenvalues of the Jacobian matrix, which makes it simple and convenient;(iv)the controller is robust versus external disturbances.

Simulations results have verified the effectiveness of this method for GPS of chaotic gyroscope systems.

Since the gyro has been utilized to describe the mode in navigational, aeronautical, or space engineering, the generalized projective synchronization procedure in this study may have practical applications in the future.