Nonfragile Robust <svg xmlns:xlink="http://www.w3.org/1999/xlink" xmlns="http://www.w3.org/2000/svg" style="vertical-align:-4.172pt" id="M1" height="15.5197pt" version="1.1" viewBox="-0.0657574 -11.3477 26.7737 15.5197" width="26.7737pt"><g transform="matrix(.017,0,0,-0.017,0,0)"><path id="g50-73" d="M870 650H600L593 618C681 609 684 605 669 516L641 367H261L286 516C302 603 313 610 391 618L398 650H132L123 618C214 610 218 606 200 516L127 130C113 46 107 40 25 32L18 0H290L298 32C204 40 200 42 214 130L250 321H631L596 131C580 47 573 39 484 32L475 0H753L762 32C673 39 668 46 685 130L757 516C772 606 778 610 861 618L870 650Z"/></g><g transform="matrix(.012,0,0,-0.012,13.419,3.961)"><path id="g50-30" d="M1000 227C1000 351 905 451 780 451C658 451 590 380 530 279C465 385 388 451 261 451C168 451 38 376 38 210C38 98 121 -12 261 -12C381 -12 448 59 508 160C573 53 652 -12 780 -12C879 -12 1000 64 1000 227ZM485 199C434 109 370 25 271 25C188 25 133 117 133 241C133 355 189 414 249 414C357 414 426 302 485 199ZM903 204C903 70 852 25 790 25C681 25 611 136 552 240C603 330 669 414 768 414C855 414 903 321 903 204Z"/></g></svg> Synchronization Approach for Drive-Response Complex Dynamical Networks with Randomly Occurring Controller Gain Fluctuations and Uncertainties

Li, Dabin; Wang, Zicai; Ma, Guangfu

doi:https://doi.org/10.1155/2015/495858

Mathematical Problems in Engineering

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Advanced Control of Complex Dynamical Systems with Applications

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Research Article | Open Access

Volume 2015 | Article ID 495858 | https://doi.org/10.1155/2015/495858

Nonfragile Robust Synchronization Approach for Drive-Response Complex Dynamical Networks with Randomly Occurring Controller Gain Fluctuations and Uncertainties

Dabin Li,¹Zicai Wang,¹and Guangfu Ma²

Academic Editor: Xinggang Yan

Received22 Jun 2015

Accepted15 Oct 2015

Published30 Nov 2015

Abstract

This paper investigates the nonfragile synchronization problem of complex dynamical networks with randomly occurring controller gain fluctuations and uncertainties. These randomly occurring phenomena are described by independent stochastic variables satisfying Bernoulli distributions, which are adopted to model more realistic dynamical behaviors of the complex networks. By applying the Lyapunov-Krasovskii method, delay-dependent criteria are established to ensure that the synchronization can be achieved with the prescribed disturbance attenuation. Moreover, the obtained results do not rely on the derivatives of time-varying delays. A set of nonfragile controllers are further designed in terms of linear matrix inequality (LMI) approach. Finally, a numerical example is given to illustrate the effectiveness of our theoretical results.

1. Introduction

In the past decade, there have been intensive researches on dynamical properties of complex networks. This increasing interest in complex dynamical networks is mainly due to their wide ranging implications and applications in the real world, such as computer networks, communication networks, biological networks, and social networks [1–8]. Roughly speaking, complex dynamical networks consisted of a large set of interconnected nodes displaying collective behaviors. Specially, the synchronization problem of complex dynamical networks is becoming a hot research area in recent years, which is a universal phenomenon in nature. As a result, many synchronization methods have been developed for complex dynamical networks [9–11].

It is worth mentioning that there are inevitable disturbances in complex dynamical networks caused by environmental circumstances, which gives rise to the synchronization problem. Following this research line, several synchronization results have been reported in the literature; see, for example, [12–15]. In addition, it is generally known that time delays exist ubiquitously in almost all practical applications, which may lead to system performance degradation [16–19]. Due to their impact, there have been some efficient synchronization results of complex dynamical networks with various time delays [20, 21]. Another important issue in the complex dynamical networks is the uncertainty. Since explicit descriptions of the network parameters are always hardly obtained, robust synchronization approaches against uncertainties are proposed. Some initial attention has been focused on this problem [22].

On the other hand, there is a class of complex dynamical networks that cannot achieve synchronization by themselves, such that synchronization controllers should be designed. It should be pointed out that, due to A/D conversion, D/A conversion, and finite word length in computations, it is always very expensive or even impossible to implement the designed controller gains precisely [23–28]. Thus, nonfragile controllers are needed to tolerate the uncertainty in practical situations. Very recently, the issue of randomly occurring uncertainties has been introduced for neural networks and chaotic systems. However, to the best of the authors’ knowledge, the nonfragile synchronization problem for complex dynamical networks with randomly occurring controller gain fluctuations and uncertainties has never been tackled in the previous literatures and remains challenging, which motivates us to conduct this study.

In this paper, by introducing the complex dynamical networks subject to time-varying delays, external disturbances, and randomly occurring uncertainties, the synchronization problem is investigated. In particular, nonfragile controllers are designed, in which the randomly occurring controller gain fluctuations are taken into consideration. The parameter uncertainties and coupling delays are assumed to be time-varying and norm bounded. Compared with the existing results, the main contributions of this paper can be summarized as threefold. Firstly, the complex dynamical networks model adopted in this paper is more general, which can better simulate the networks in the applications. Both self-time-varying delays and coupling time-varying delays are considered in the model. Secondly, it is the first time to establish the nonfragile synchronization for complex dynamical networks with randomly occurring controller gain fluctuations and uncertainties. By utilizing the Lyapunov-Krasovskii method, novel synchronization criteria are derived in terms of LMIs. Finally, the obtained delay-dependent results impose no constraints on the derivative of time-varying delays, which are more applicable in the real world.

The remainder of this paper is organized as follows. Section 2 introduces the complex dynamical networks model and presents several assumptions and lemmas. The main results based on the LMI approach are established in Section 3. Section 4 gives a numerical example to demonstrate the effectiveness of our derived criteria. Finally, the paper is concluded in Section 5.

Notation. The notation in the paper is standard. denotes the dimensional Euclidean space and represents the set of all real matrices. and represent identity matrix and zero matrix with appropriate dimensions, respectively. The notation means is real symmetric and positive definite, and the superscript “” denotes matrix transposition. means the occurrence probability of the event . stands for the mathematical expectation of the stochastic variable . denotes the Kronecker product of matrices and . Moreover, in symmetric block matrices, is used as an ellipsis for the terms that are introduced by symmetry and denotes a block-diagonal matrix. Finally, if not explicitly stated, all matrices are assumed to have compatible dimensions.

2. Problem Formulation and Preliminaries

Consider the following model of complex dynamical networks with time-varying delays:where represents the state vector of the th node, , , and are constant matrices, is a smooth nonlinear function, represents the self-time-varying delays, represents the coupling time-varying delays, is the inner coupling matrix, and is the outer coupling matrix describing the network topology. If there is a connection from node to node , then the coupling ; otherwise, . Moreover, the diagonal elements are defined as , . , , and are real valued matrices representing the time-varying parameter uncertainties and are assumed to be of the following form:where , , , and are known real constant matrices and is an unknown time-varying matrix satisfying

The initial conditions are , , with some given continuous functions . Without loss of generality, the initial conditions are chosen as constant functions on . The stochastic variable is a Bernoulli distributed sequence defined by with where is a known constant.

Assumption 1. The time-varying delays satisfy and , , and are positive constants.

Assumption 2. The nonlinear function satisfies, where and are constant matrices of appropriate dimensions with .

By the drive-response synchronization concept, model (1) is set as the drive complex dynamical networks. Correspondingly, the response complex dynamical networks can be given aswhere represents the response state vector of the th node, denotes the control input to be designed for the th node, and is the disturbance on the th node.

Remark 3. Compared with the existing results, our proposed drive-response complex dynamical networks model is more general. When , the model can be utilized to describe synchronization problem of chaotic systems or neural networks. Moreover, the random appearance or disappearance of the parameter uncertainties is introduced in the model to reflect more complex behaviors of the real networks.

Define the synchronization errors as follows: such that the following synchronization error dynamics can be obtained:where . Then, in order to deal with the real world controller implementation, the following nonfragile state feedback controllers with controller gain fluctuations are designedwhere is the controller gain to be determined and the real valued matrix denotes the controller gain fluctuation. Moreover, is assumed to have the following structure:where and is an unknown time-varying matrix satisfying and , are known constant matrices. The stochastic variable is a Bernoulli distributed sequence, which describes the phenomena of randomly occurring controller gain fluctuation. is defined by withwhere is a known constant. Moreover, it is assumed that the stochastic variables and are mutually independent.

Consequently, the closed-loop synchronization error dynamics can be obtained aswhich can be further rewritten aswhere

Before proceeding, the following definitions and lemmas are given for subsequent analysis.

Definition 4. The synchronization is said to be reached if there exists a constant such that for any nonzero .

Lemma 5 (see [29]). For any positive symmetric constant matrix , scalars , satisfying , a vector function , such that the integrations concerned are well defined; then

Lemma 6 (see [30]). Let , , and be real matrices of appropriate dimensions with satisfying . Then, , if and only if there exists a scalar such that , or equivalently

The main purpose of the paper is to design a set of nonfragile controllers (10) for the response complex dynamical networks such that, for admissible external bounded disturbances, the synchronization is achieved with a prescribed attenuation level .

3. Main Results

In this section, delay-dependent criteria will be established to solve the synchronization problem of complex dynamical networks in the presence of randomly occurring controller gain fluctuations and uncertainties. Then, a design procedure is proposed for the nonfragile controllers in terms of LMIs.

Theorem 7. For given scalars , and and the upper bounds of time-varying delays and , the synchronization of the complex dynamical networks can be achieved with the given controller gains , , if there exist symmetric positive definite matrices , and constants such that , wherewith

Proof. Choose the Lyapunov-Krasovskii function candidate as follows:Note that (16) can be rewritten aswhere is defined in (21).
The infinitesimal operator of is defined as follows: Taking the derivative of (23) along the solution of system (24) yieldsBy Lemma 5, it holds thatMoreover, it can be obtained by Assumption 1 thatwhere and are defined in (21).
Combining inequalities (27)-(28), one hasIn order to show the performance , the following function is defined:Then, it can be obtained from (27)-(28) that , if holds, whereFurthermore, it can be derived thatThen, according to Schur complement lemma [31], it can be verified that if holds, whereNote that holds. By substituting (2) and (11) into (33) and performing a congruence transformation of to (33), it follows that if the following inequality holds:where Therefore, it can be obtained by Lemma 6 that if holds, then . When , under zero initial conditions, it can be verified that the condition can guarantee that , which implies that the synchronization is achieved in the sense of Definition 4 and completes the proof.

Remark 8. The two stochastic variables satisfying Bernoulli random binary distributions are adopted to character the randomly occurring phenomena in the synchronization problem for complex dynamical networks. It can be observed that when , the controllers (11) are degenerated to the general nonfragile controllers. By utilizing the stochastic information, a better synchronization performance can be obtained with less conservatism.

Remark 9. It is worth mentioning that it is a very expensive or even impossible task to obtain the real values or the boundedness of the derivatives of time delays in many applications. Regarding this aspect, our established synchronization conditions impose no constraint on the derivatives of the time-varying delays and , which is applicable to more general case in the real world. Moreover, the derived results in this paper can be directly applied to deal with the cases of constant time delays.

Based on Theorem 7, the following theorem is presented to solve the synchronization controller design problem in terms of LMIs.

Theorem 10. For given scalars , and and the upper bounds of time-varying delays and , the synchronization of the complex dynamical networks can be achieved, if there exist symmetric positive definite matrices , , and , matrix , and constants such that , wherewith, are defined in (21), and the controller gains can be obtained as , .

Proof. The proof follows directly from Theorem 7 by letting .

4. Numerical Example

In this section, an illustrative example is presented to show the effectiveness and usefulness of our proposed control strategy.

Consider two complex dynamical networks (1) and (7) with three nodes and the state vector of each node being two-dimensional, such that and . The network matrices are given asThe inner coupling matrix is assumed to be and the outer coupling matrix is given as The time-varying delays are chosen as and . Accordingly, one has and . The nonlinear function is taken assuch that can satisfy Assumption 1 with

The parameter uncertainties satisfy condition (11) with and the controller gain fluctuations are assumed to beThe external disturbances are assumed to be , . The parameters , , and are set as , , and , respectively.

By solving the LMIs (40) in Theorem 10, the desired controller gains can be obtained as follows:

Set the initial states of the two complex dynamical networks with random values. Figure 1 shows the state trajectories of the synchronization errors without the controllers and the state trajectories of the controlled synchronization errors are shown in Figure 2. It can be clearly seen that the two complex dynamical networks can achieve the synchronization with the designed controllers, which demonstrates our proposed method.

5. Conclusion

This paper is concerned with the problem of nonfragile synchronization of complex dynamical networks with randomly occurring controller gain fluctuations and uncertainties. In particular, two independent stochastic variables satisfying Bernoulli distributions are adopted to model these randomly varying phenomena. By constructing appropriate Lyapunov-Krasovskii functionals and using stochastic analysis, delay-dependent sufficient conditions are established to guarantee the synchronization of the drive-response complex dynamical networks. Moreover, the nonfragile controllers are further developed based on the obtained results in terms of LMIs. In the end, the effectiveness of our proposed strategy is demonstrated through a simulation example. Our further research would be to extend the current results to the cases with time-varying topologies and pinning control strategy, which are more comprehensive in the real world.

Conflict of Interests

The authors declare that there is no conflict of interests regarding the publication of this paper.

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Copyright © 2015 Dabin Li et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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