DOI QR코드

DOI QR Code

시변지연을 가지는 TS퍼지시스템을 위한 견실 시간종속 안정성판별법

Robust Delay-dependent Stability Criteria for Takagi-Sugeno Fuzzy Systems with Time-varying Delay

  • Liu, Yajuan (Dept. of Electronic Engineering, Daegu University) ;
  • Lee, Sangmoon (Dept. of Electronic Engineering, Daegu University) ;
  • Kwon, Ohmin (Dept. of Electrical Engineering, Chungbuk National University)
  • 투고 : 2015.03.13
  • 심사 : 2015.05.01
  • Published : 2015.06.01

Abstract

This paper presents the robust stability condition of uncertain Takagi-Sugeno(T-S) fuzzy systems with time-varying delay. New augmented Lyapunov-Krasovskii function is constructed to ensure that the system with time-varying delay is globally asymptotically stable. Also, less conservative delay-dependent stability criteria are obtained by employing some integral inequality, reciprocally convex approach and new delay-partitioning method. Finally, two numerical examples are provided to demonstrate the effectiveness of the proposed method.

Keywords

1. Introduction

Since Takagi-Sugeno(T-S) fuzzy model was first introduced in [1], the stability and design conditions for T-S fuzzy systems have been paid much attention. The main advantage of T-S fuzzy model is that it can combine the exibility of fuzzy logic theory and rigorous mathematical theory of linear system into a unified framework to approximate complex nonlinear systems [2-4]. On the other hand, time delays often appears in many dynamical systems such as metallurgical processes, biological systems, neural networks, networked control systems and so on. The existence of time delay may cause poor performance or instability. Hence, the stability of T-S fuzzy systems with time delay has been studied by many researchers [5-24,30,31].

It is well known that the delay-dependent stability criteria are less conservative that delay-independent ones especially that the time-delay is small. The main issue of delay-dependent stability criteria is to find a maximum delay bounds to guarantee the asymptotic stability of the considered systems. Therefore, the study of increasing the maximum delay bounds in delay-dependent stability criteria for fuzzy systems is an important topic and have been investigated by many researchers. In [5], the delay dependent stability problem for T-S fuzzy systems with time varying delay was investigated. Some stability criteria or stabilization of delayed T-S fuzzy systems were derived by employing free-weighting matrix [6,9,12]. Furthermore, the results was further studied by using delay-partitioning-based approach [13,17,19,23]. Recently, in [18], an augmented Lyapunov-Krasovskii functional approach that introduces a triple integral and some augmented vectors was employed to investigate the stability problem of T-S fuzzy systems with time-varying delay. In [20], the improved results was obtained by quadratically convex approach. The results was further improved in [24] by employing the delay-partitioning method and reciprocally convex approach. However, though these results and analytic methods are elegant, there still exist some rooms for further improvements. First, in [8,11,20,18], Jensen's inequality, free-weighting matrix and quadratically convex combination approach are used to derive the stability condition. However, reciprocally convex approach [25], which can play an important role in reducing conservatism of the stability condition, is not used in [8,11,20,18]. Second, though the reciprocal convex approach, delay-partitioning and integral inequalities method are combined to obtain some less conservative results in [24], it still needs some improvements since it only used the improved inequality in constant delay, not employed in time-varying delay. Furthermore, it can be predicted that delay-partitioning approach can provide tighter upper bounds than the results without delay-partitioning approach. However, as delay-partitioning number increases, matrix formulation becomes complex and time consuming and computational burden grow bigger. Therefore, there are rooms for further improvement in stability analysis of T-S fuzzy systems with time-varying delay.

In this paper, the stability analysis conditions for uncertain T-S fuzzy systems with time-varying delay are proposed. By construction of a modified augmented Lyapunov-Krasovskii functional approach, an improved stability criterion for guaranteeing the asymptotically stable is derived by using Wirtinger-based integral inequality [26], reciprocally convex approach [25], and new delay-partitioning method. It should be pointed out that different with delay-partitioning method used in [24], we only divide the time interval into two sub-intervals, and consider two different cases of delay-partitioning method. Moreover, some robust stability criteria of uncertain T-S systems with time varying delay is provided. Finally, two numerical examples are given to demonstrate the effectiveness of the proposed method.

Notation: Throughout the paper, Rn denotes the n -dimensional Euclidean space, Rm×n denotes the set of m by n real matrix. For symmetric matrices X, X >0 and X <0, mean that X is a positive/negative definite symmetric matrix, respectively. I and 0 denote the identity matrix and zero matrix with appropriate dimension. ⋆ represents the elements below the main diagonal of a symmetric matrix. diag... denotes the diagonal matrix.

 

2. Problem Statements

Consider the following nonlinear system which can be modeled as T-F fuzzy model type subject to time-varying delay:

where θ1 (t),θ2 (t),...,θn (t) are the premise variables, Mij is fuzzy set, i=1,2,...,r,j=1,2,...,n r is the index number of fuzzy rules, and x(t)∈Rn denotes the state of the system. Ai and Adi are the known system matrices and delayed-state matrices with appropriate dimensions, respectively. φ(t) is a continuously real-valued initial function vector. we assume that h(t) is a time-varying delay satisfying

where hM,μ are known constants.

The uncertainties satisfy the following condition:

where D,Ei,Edi are known constant matrices; F(t)∈Rn×n is the unknown real time-varying matrices with Lebesgue measurable elements bounded by

Using singleton fuzzifier, product inference, and center-average defuzzifier, the global dynamics of the delayed T-S system (1) is described by the convex sum form

where pi(θ(t)) denotes the normalized membership function satisfying

where Mij (θi(t)) is the grade of membership of θi(t) in Mij It is assumed that

Then, we have the following condition

For the sake of simplicity, let us define

Now, the system (5) can be rewritten as

In what follows, some essential lemmas are introduced. Lemma 1 [26] For a given matrix R>0, the following inequality holds for all continuously differentiable function x(t) in [a,b]∈Rn :

where

Lemma 2 [28] For a given matrix M>0, hm ≤ h(t)≤ hM , and any appropriate dimension matrix X, which satisfies Then, the following inequality holds for all continuously differentiable function x(t)

where

Lemma 3 (Fisher's Lemma [27]) Let ξ∈Rn,Φ = ΦT ∈Rn×n, and B∈Rm×n such that rank(B) ≤ n. The following statements are equivalent

(i) ξT Bξ <0,∀Bξ=0,ξ≠0, (ii) where B⊥ is a right orthogonal complement of B. (iii)

 

3. Main Results

In this section, we first propose a stability criterion for delayed T-S fuzzy systems without uncertainties, and the following nominal system will be considered:

For the sake of simplicity of matrix and vector representations, ei∈R8n ×n (i=1,2,...,8) are defined as block entry matrices (for example (e4 = [000 I 0000]T). The other notations are defined as :

Now we have the following Theorem.

Theorem 1 For given scalars hM >0,0 <α<1,μ, the system (11) is globally asymptotically stable if there exist symmetric positive matrices P∈R3n × 3n,Q1,Q2,Q3,R1,R2, and any matrix Sj(j=1,2)∈R2n × 2n such that the following LMIs hold

where

Proof: Let us consider the following Lyapunov-Krasovskii functional candidate as

where

Depending on whether the time-varying delay h(t) belongs the interval 0≤h(t) ≤ hM or αhM ≤ h(t) ≤ hM, different upper bound of the Vi(i = 1,4,5) can be obtained as two cases:

When 0≤h(t) ≤ αhm, the time-derivative of Vi(i = 1,2,3) can be calculated as

By applying Lemma 2, an upper bound of is obtained as

where

Note that when h(t) = 0 or h(t) = hM, we have β1 (t) = β2 (t) = 0 or β3 (t) = β4 (t) = 0 Then (19) still holds.

Next, an upper bound of can be derived by Lemma 1,

where

Therefore, in the case of 0≤h(t) ≤ hM, form Eqs. (16)-(20), an upper bound of can be given as

Based on Lemma 3, ξT(t)Y1ξ(t) < 0

with is equivalent to Furthermore, the above condition is affinely dependent on h(t). Hence, (12) and (14) imply

Next, when αhM ≤h (t) ≤ hM, the time-derivative of V1 is

Based on Eq. (17) and (18), an derivative of Vi(i = 2,3) can be calculated as

By Lemma 1,

where

Also, an upper bound of can be obtained by utilizing Lemma 2

where

Note that when h(t) = αhM or h(t) = hM, we have γ1 (t) = γ2 (t) = 0 or γ3 (t) = γ4 (t) = 0, β(t) = 0. Thus, Eq. (25) still holds.

Therefore, from Eqs. (22)-(25), an upper bound of in the case of αhM ≤ h(t) ≤ hM can be given as

Based on Lemma 3,

with is equivalent to Furthermore, the above condition is affinely dependent on h(t). Hence, (13) and (14) This completes the proof. ■

Remark 1. Unlike in [24], the proposed Lyapunov-Krasovskii functional in (15) are divided the time delay interval [0,h] into different size because of introducing parameter α. When α= 0.5, it can be reduced to the ones employed in [24], which divides the time delay interval into the same size, that is, In other words, based on two delay decomposing approach, the Lyapunov-Krasovskii functional constructed in this paper is more general than the ones used in [24]. When α= 0.5, constructing the following Lyapunov functional candidate as

where

the others are the same with the ones in (15).

Remark 2. It should be pointed out that the proposed delay-partitioning method is different from existing ones [24,29]. In [29], by using nonuniform decomposition method that the whole delay interval is nonuniformly decomposed into multiple subintervals. In [24], uniform decomposition method is used, which divides the delay interval into the same size. While the conventional method use pre-known constant value to divide the delay interval, a new nonuniform delay-partitioning method is proposed by introducing parameter α, that is, delay interval is divided as [0,hM]=[0,αhM]∪[αhM,hM].

Based on Eq. (27) with α= 0.5, the following Corollary can be obtained from Theorem 1.

Corollary 1. For given scalars hM >0,α = 0.5,μ, the system (11) is globally asymptotically stable if there exist symmetric positive matrices P∈R3n × 3n, Q∈R2n × 2n,Q1, R1, R2, and any matrix Sj (j = 1,2) ∈ R2n × 2n such that the following LMIs hold

where

Remark 3. Unlike the constructed Lyapunov-Krasovskii functional in (15), the cross term of the state x(t) and x(t − αhM) in (15) are considered, which may provide improved stability condition.

For uncertain T-S fuzzy system (10), since PT (t)p(t) ≤ qT (t)q(t), there exists a positive scalar ε satisfying the following inequality: ε[qT(t)q(t) - PT(t)p(t) ≥ 0. Define and (i = 1,2,...,9), and the other notations are given as follows:

Now we have the following Corollary 2 and Corollary 3.

Corollary 2. For given scalars hM > 0.0 < α < 1.μ, the system (10) is globally asymptotically stable if there exist symmetric positive matrices P∈R3n × 3n, Q1,Q2,Q3,R1,R2, and any matrix Sj (j = 1,2) ∈ R2n × 2n , and a positive scalar ε such that the following LMIs hold

Corollary 3. For given scalars hM >0,α =0.5,μ, the system (10) is globally asymptotically stable if there exist symmetric positive matrices P∈R3n × 3n,Q∈R2n × 2nQ1,R1,R2, and any matrix Sj(j=1,2)∈R2n × 2n, and a positive scalar ε such that the following LMIs hold

where

 

4. Numerical Examples

In this section, two numerical examples are given to show the effectiveness of the proposed method.

Example 1 Consider the system with the following parameters:

For different μ, the upper bounds of the time-varying delay computed by the proposed method and those in [8,11,20,18,24] are listed in Table 1. It is easy to know that the proposed method in this paper is less conservative than those in the existing results.

표 1다른 μ값에 대한 상한유계지연 hM Table 1 Upper delay bound hM for different μ

Example 2 Consider the system with the following parameters:

For different μ, the upper bounds of the time-varying delay computed by the proposed method and those in [5,9,12,24] are listed in Table 2. It can be concluded that the result proposed in this paper is better than the existing ones.

표 2다른 μ값에 대한 상한유계지연 hM Table 2 Upper delay bound hM for different μ

 

5. Conclusions

The robust stability for uncertain T-S fuzzy systems with time-varying delay has been investigated. Based on a modified Lyapunov-Krasovskii functional, some less conservative criteria have been obtained by employing new delay-partitioning technique, integral inequality and reciprocally convex approach. It should be worthwhile pointed out that different case of delay-partitioning method is used in this paper, that is, the delay interval is divided into even and not even. Two numerical examples have been given to demonstrate the effectiveness of the proposed method.

References

  1. T. Takagi, M. Sugeno, “Fuzzy identification of systems and its applications to modelling and control”, IEEE Trans. Syst. Man Cybern., vol. 15, no. 1, pp. 116-132, Jan. 1985.
  2. K. Tanaka, M. Sano, “A robust stabilization problem of fuzzy control systems and its application to backing up control of a truck-trailer”, IEEE Trans. Fuzzy Syst., vol. 2, no. 2, pp. 119-134, May. 1994. https://doi.org/10.1109/91.277961
  3. M.C. Teixeira, S.H. Zak, “Stabilizing controller design for uncertain nonlinear systems using fuzzy models”, IEEE Trans. Fuzzy Syst., vol. 7, no. 2, pp. 133-144, Apr. 1999. https://doi.org/10.1109/91.755395
  4. H. Ying, “The Takagi-Sugeno fuzzy controllers using the simplified linear control rules are nonlinear variable gain controllers”, Automatica, vol. 34, no. 2, pp. 157-167. Feb. 1998. https://doi.org/10.1016/S0005-1098(97)00173-8
  5. C.G. Li, H.J. Wang, X.F. Liao, “Delay-dependent robust stability of uncertain fuzzy systems with time-varying delays”, IEE Proc. Control Theory Appl., vol. 151, no. 4, pp. 417-421, Jul. 2004. https://doi.org/10.1049/ip-cta:20040641
  6. E. Tian, C. Peng, “Delay-dependent stability analysis and synthesis of uncertain T-S fuzzy systems with time-varying delay”, Fuzzy Sets Syst., vol. 157, no. 4, pp. 544-559, Feb. 2006. https://doi.org/10.1016/j.fss.2005.06.022
  7. B.C. Ding, H.X. Sun, P. Yang, “Further studies on LMI-based relaxed stabilization conditions for nonlinear systems in Takagi-Sugeno's form”, Automatica, vol. 42, no. 3, pp. 503-508, Mar. 2006. https://doi.org/10.1016/j.automatica.2005.11.005
  8. H.N. Wu, H.X. Li, “New approach to delay-dependent stability analysis and stabilization for continuous-time fuzzy systems with time-varying delay”, IEEE Trans. Fuzzy Syst., vol. 15, no. 3, pp. 482-493, Jun. 2007. https://doi.org/10.1109/TFUZZ.2006.889963
  9. C.H. Lien, K.W. Yu, W.D. Chen, Z.L. Wan, Y.J. Chung, “Stability criteria for uncertain Takagi-Sugeno fuzzy systems with interval time-varying delay”, IET Control Theory Appl., vol. 1, no. 3, pp. 746-769, May. 2007.
  10. H. Gao, X. Liu, J. Lam, “Stability analysis and stabilization for discrete fuzzy systems with time-varying delay”, IEEE Trans. Syst. Man Cybernet. Part B, vol. 39, no. 2, pp. 306-317, Apr. 2009. https://doi.org/10.1109/TSMCB.2008.2003449
  11. Z. Yang, Y. Yang, “New delay-dependent stability analysis and synthesis of T-S fuzzy systems with time-varying delay”, Int. J. Robust Nonlinear Control, vol. 20, no. 3, pp. 313-322, Mar. 2010. https://doi.org/10.1002/rnc.1431
  12. F. Liu, M. Wu, Y. He, R. Yokoyamab, “New delay-dependent stability criteria for T-S fuzzy systems with time-varying delay”, Fuzzy Sets Syst., vol. 161, no. 15, pp. 2033-2042, Aug. 2010. https://doi.org/10.1016/j.fss.2009.12.014
  13. J. An, G. Wen, “Improved stability criteria for time-varying delayed T-S fuzzy systems via delay partitioning approach”, Fuzzy Sets Syst., vol. 185, no. 1, pp. 83-94, Dec. 2011. https://doi.org/10.1016/j.fss.2011.06.016
  14. C. Peng, L.-Y. Wen, J.-Q. Yang, “On delay-dependent robust stability criteria for uncertain T-S fuzzy systems with interval time-varying delay”, International Journal of Fuzzy Systems, vol. 13, no. 1, pp. 35-44, Mar. 2011.
  15. F.-P. Da, S.-T. He, “Exponential stability analysis and controller design of fuzzy systems with time-delay”, Journal of the Franklin Institute, vol. 348, no. 5, pp. 865-883, Jun. 2011. https://doi.org/10.1016/j.jfranklin.2011.02.012
  16. L. Wu, X. Su, P. Shi, J. Qiu, “A new approach to stability analysis and stabilization of discrete-time T-S fuzzy time-varying delay systems”, IEEE Trans. Syst. Man Cybernet. Part B: Cybernet., vol. 41, no. 1, pp. 691-704, Feb. 2011.
  17. J. An, T. Li, G. Wen, R. Li, “New stability conditions for uncertain T-S fuzzy systems with interval time-varying delay”, Int. J. Control Automat. Syst., vol. 10, no. 3, pp. 490-497, Jun. 2012. https://doi.org/10.1007/s12555-012-0305-9
  18. O.M. Kwon, M.J. Park, S.M. Lee, Ju H. Park, “Augmented Lyapunov-Krasovskii functional approaches to robust stability criteria for uncertain Takagi-Sugeno fuzzy systems with time-varying delays”, Fuzzy Sets Syst., vol. 201, no. 16, pp. 1-19, Aug. 2012. https://doi.org/10.1016/j.fss.2011.12.014
  19. C. Peng, M.R. Fei, “An improved result on the stability of uncertain T-S fuzzy systems with interval time-varying delay”, Fuzzy Sets Syst., vol. 212, no. 1, pp. 97-109, Feb. 2013. https://doi.org/10.1016/j.fss.2012.06.009
  20. F. Yang, S. Guan, D. Wang, “Quadratically convex combination approach to stability of T-S fuzzy systems with time-varying delay”, Journal of the Franklin Institute, vol. 351, no. 7, pp. 3752-3765, Jan. 2014. https://doi.org/10.1016/j.jfranklin.2013.01.025
  21. F.O. Souza, V.C.S. Campos, R.M. Palhares, “On delay-dependent stability conditions for Takagi-Sugeno fuzzy systems”, Journal of the Franklin Institute, Fuzzy Sets Syst., vol. 351, no. 7, pp. 3707-3718, Jul. 2014.
  22. H. Wang, B. Zhou, R. Lu, A. Xue, “New stability and stabilization criteria for a class of fuzzy singular systems with time-varying delay”, Journal of the Franklin Institute, vol. 351, no. 7, pp. 3766-3781, Jul. 2014. https://doi.org/10.1016/j.jfranklin.2013.02.030
  23. K. Mathiyalagan, J.H. Park, R. Sakthivel, S. Marshal Anthoni, “Delay fractioning approach to robust exponential stability of fuzzy Cohen-Grossberg neural networks”, Appl. Math. Comput., vol. 230, no. 1, pp. 451-463, Mar. 2014. https://doi.org/10.1016/j.amc.2013.12.063
  24. H.-B. Zeng, Ju.H. Park, J.-W Xia, S.-P Xiao, “Improved delay-dependent stability criteria for T-S fuzzy systems with time-varying delay”, Appl. Math. Comput., vol. 235, pp. 492-501, May. 2014. https://doi.org/10.1016/j.amc.2014.03.005
  25. P.G. Park, J.W. Ko, C.K. Jeong, “Reciprocally convex approach to stability of systems with time-varying delays”, Automatica, vol. 47, no. 1, pp. 235-238, Jan. 2011. https://doi.org/10.1016/j.automatica.2010.10.014
  26. A. Seuret, F. Gouaisbaut, “Wirtinger-based integral inequality: application to time-delay systems”, Automatica, vol. 49, no. 9, pp. 2860-2866, Sep. 2013. https://doi.org/10.1016/j.automatica.2013.05.030
  27. R.E. Skelton, T. Iwasaki, K.M. Grigoradis, “A Unified Algebraic Approach to Linear Control Design”, Taylor, Francis, NewYork, 1997.
  28. Y. Liu, S.M. Lee, O.M. Kwon, Ju H. Park, “New approach to stability criteria for generalized neural networks with interval time-varying delays”, Neurocomputing, vol. 149, pp. 1544-1551, Feb. 2015. https://doi.org/10.1016/j.neucom.2014.08.038
  29. X.-M. Zhang and Q.-L. Han, “New Lyapunov-Krasovskii functionals for global asymptotic stability of delayed neural networks”, IEEE Trans. Neural Networks, vol. 20, no. 3, pp. 533-539, Feb. 2009. https://doi.org/10.1109/TNN.2009.2014160
  30. J.H. Park, S. Lee and K.C. Lee, "Study on Design of Embedded Control Network System using Cyber Physical System Concept", IEMEK J. Embed. Sys. Appl., vol. 7, no. 5, pp. 347-357, 2012. (in Korean)
  31. J. Park, S. Kang, I. Chun and W. Kim, "A Research on Designing an Autonomic Control System Towards High-Reliable Cyber-Physical Systems", IEMEK J. Embed. Sys. Appl., vol. 8, no. 6, pp. 347-357, 2013. (in Korean) https://doi.org/10.14372/IEMEK.2013.8.6.347