This article studies the problem of global stability of the Takagi–Sugeno fuzzy systems based on a novel descriptor-based non-quadratic Lyapunov function. A modified non-quadratic Lyapunov function, which comprises an integral term of the membership functions, and a modified non-parallel distributed controller constructed by constant delayed premise variables are considered that assure the global stability of the closed-loop T–S fuzzy system. The special structure of the used non-quadratic Lyapunov function results in time-delayed terms of the membership functions, instead of appearing their time derivatives, which is the well-known issue of the common non-quadratic Lyapunov functions in the literature. Also, the memory fuzzy controller is chosen such that the artificial constant delay-dependent stability analysis conditions for a non-delayed closed-loop T–S fuzzy system are formulated in terms of linear matrix inequalities. To further reduce the conservatives, some slack matrices are introduced by deploying the descriptor representation and decoupling lemmas. Moreover, the design of the robust fuzzy controller is studied through the performance criteria. The main advantages of the proposed approach are its small conservatives and the global stability analysis, which distinguish it from the state-of-the-art methods. To show the merits of the proposed approach, comparison results are provided, and two numerical case studies, namely, flexible joint robot and two-link joint robot are considered.
AsemaniMHMajdVJ (2013) A robust observer-based controller design for uncertain T–S fuzzy systems with unknown premise variables via LMI. Fuzzy Sets and Systems212: 21–40.
2.
BanksSPGürkanEErkmenİ (2005) Stable controller design for T–S fuzzy systems based on Lie algebras. Fuzzy Sets and Systems156: 226–248.
3.
ChadliMKarimiHR (2013) Robust observer design for unknown inputs Takagi–Sugeno models. IEEE Transactions on Fuzzy Systems21: 158–164.
4.
ChadliMKarimiHRShiP (2014) On stability and stabilization of singular uncertain Takagi–Sugeno fuzzy systems. Journal of the Franklin Institute351: 1453–1463.
5.
ChangWLiYTongS (2018) Adaptive fuzzy backstepping tracking control for flexible robotic manipulator. IEEE/CAA Journal of Automatica Sinica1–9. DOI: 10.1109/JAS.2017.7510886.
6.
ChangX-HYangG-H (2010) Relaxed stabilization conditions for continuous-time Takagi–Sugeno fuzzy control systems. Information Sciences180: 3273–3287.
7.
CherifiAGueltonKArceseL, et al. (2019) Global non-quadratic D-stabilization of Takagi–Sugeno systems with piecewise continuous membership functions. Applied Mathematics and Computation351: 23–36.
8.
DelmotteFGuerraTMKsantiniM (2007) Continuous Takagi–Sugeno’s models: reduction of the number of LMI conditions in various fuzzy control design technics. IEEE Transactions on Fuzzy Systems15: 426–438.
9.
GonzálezTSalaABernalM (2019) A generalised integral polynomial Lyapunov function for nonlinear systems. Fuzzy Sets and Systems356: 77–91.
10.
KhakiBRanjbar-SahraeiBNorooziN, et al. (2011) Interval type-2 fuzzy finite-time control approach for chaotic oscillation damping of power systems. International Journal of Innovative Computing, Information and Control7: 6827–6935.
11.
LamHK (2018) A review on stability analysis of continuous-time fuzzy-model-based control systems: from membership-function-independent to membership-function-dependent analysis. Engineering Applications of Artificial Intelligence67: 390–408.
12.
LamHKLauberJ (2013) Membership-function-dependent stability analysis of fuzzy-model-based control systems using fuzzy Lyapunov functions. Information Sciences232: 253–266.
13.
LamHKNarimaniM (2010) Quadratic stability analysis of fuzzy-model-based control using staircase membership functions. IEEE Transactions on Fuzzy Systems18: 125–137.
14.
LeeS (2019) Novel stabilization criteria for T–S fuzzy systems with affine matched membership functions. IEEE Transactions on Fuzzy Systems27: 540–548.
15.
LiuHTianXWangG, et al. (2016) Finite-time H∞ control for high-precision tracking in robotic manipulators using backstepping control. IEEE Transactions on Industrial Electronics63: 5501–5513.
16.
LuT-TShiouS-H (2002) Inverses of 2 × 2 block matrices. Computers & Mathematics with Applications43: 119–129.
17.
MardaniMMVafamandNKhoobanMH, et al. (2019) Non-fragile controller design of uncertain saturated polynomial fuzzy systems subjected to persistent bounded disturbance. Transactions of the Institute of Measurement and Control41: 842–858.
18.
MárquezRGuerraTMBernalM, et al. (2016) A non-quadratic Lyapunov functional for H∞ control of nonlinear systems via Takagi–Sugeno models. Journal of the Franklin Institute353: 781–796.
19.
MárquezRGuerraTMKruszewskiA, et al. (2013) Improvements on non-quadratic stabilization of Takagi–Sugeno models via line-integral Lyapunov functions. IFAC Proceedings Volumes46: 473–478.
20.
MendesEMAMPalharesRMMozelliLA (2010) Equivalent techniques, extra comparisons and less conservative control design for Takagi–Sugeno (T–S) fuzzy systems. IET Control Theory & Applications4: 2813–2822.
21.
MozelliLAPalharesRMAvellarGSC (2009) A systematic approach to improve multiple Lyapunov function stability and stabilization conditions for fuzzy systems. Information Sciences179: 1149–1162.
22.
MozelliLASouzaFOPalharesRM (2011) New Lyapunov function and extra information on membership functions for improving stability conditions of T–S systems. International Federation of Automatic Control (IFAC)44: 3398–3402.
23.
PanJGuerraTMFeiS, et al. (2012) Nonquadratic stabilization of continuous T–S fuzzy models: LMI solution for a local approach. IEEE Transactions on Fuzzy Systems20: 594–602.
24.
QiWParkJHChengJ, et al. (2018) Stochastic stability and L1-gain analysis for positive nonlinear semi-Markov jump systems with time-varying delay via T–S fuzzy model approach. Fuzzy Sets and Systems371: 110–122.
25.
RheeB-JWonS (2006) A new fuzzy Lyapunov function approach for a Takagi–Sugeno fuzzy control system design. Fuzzy Sets and Systems157: 1211–1228.
26.
SchererCWeilandS (2004) Linear Matrix Inequalities in Control. Delft, the Netherlands: Dutch Institute for Systems and Control.
27.
TanakaK (2001) Fuzzy Control Systems Design and Analysis: A Linear Matrix Inequality Approach. New York: Wiley.
28.
VafamandNAsemaniMHKhayatianA (2017a) T–S fuzzy robust L1 control for nonlinear systems with persistent bounded disturbances. Journal of the Franklin Institute354: 5854–5876.
VafamandNAsemaniMHKhayatianA, et al. (2017b) T–S fuzzy model-based controller design for a class of nonlinear systems including nonsmooth functions. IEEE Transactions on Systems, Man, and Cybernetics: Systems50: 233–244.
31.
VafamandNRakhshanM (2017) Dynamic model-based fuzzy controller for maximum power point tracking of photovoltaic systems: an linear matrix inequality approach. Journal of Dynamic Systems, Measurement, and Control139: 051010.
32.
VafamandNShasadeghiM (2017) More relaxed non-quadratic stabilization conditions using T–S open loop system and control law properties: more relaxed non-quadratic stabilization conditions. Asian Journal of Control19: 467–481.
33.
WangBXueJWuF, et al. (2018) Finite time Takagi–Sugeno fuzzy control for hydro-turbine governing system. Journal of Vibration and Control24: 1001–1010.
34.
WangLLamH-K (2018) Local stabilization for continuous-time Takagi–Sugeno fuzzy systems with time delay. IEEE Transactions on Fuzzy Systems26: 379–385.
35.
WuYDongJ (2018) Local stabilization of continuous-time T–S fuzzy systems with partly measurable premise variables and time-varying delay. IEEE Transactions on Systems, Man, and Cybernetics: Systems1–13. DOI: 10.1109/TSMC.2018.2871100.
36.
XieXMaHZhaoY, et al. (2013) Control synthesis of discrete-time T–S fuzzy systems based on a novel non-PDC control scheme. IEEE Transactions on Fuzzy Systems21: 147–157.
37.
ZhangCLamH-KQiuJ, et al. (2018) A new design of membership-function-dependent controller for T-S fuzzy systems under imperfect premise matching. IEEE Transactions on Fuzzy Systems27: 1428–1440.
38.
ZhaoLGaoHKarimiHR (2013) Robust stability and stabilization of uncertain T–S fuzzy systems with time-varying delay: an input–output approach. IEEE Transactions on Fuzzy Systems21: 883–897.
