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2015 | OriginalPaper | Buchkapitel

1. Introduction to LPV Systems

verfasst von : Corentin Briat

Erschienen in: Linear Parameter-Varying and Time-Delay Systems

Verlag: Springer Berlin Heidelberg

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Abstract

The goal of this chapter is to introduce the main ways for representing linear parameter-varying systems and emphasize their ability to represent a wide class of dynamical systems. A classification of the types of parameters regarding their mathematical properties and their physical meaning is also given. Several real world examples of LPV systems are finally discussed in order to demonstrate the relevance of the LPV framework.

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Nächstes Kapitel Stability of LPV Systems
Fußnoten
1
For more details on dynamical systems, systems theory and related fundamental results, the reader should refer to [14]. Additional details on LPV systems can also be found in [57] and references therein.
 
2
A similar framework is based on Takagi-Sugeno systems where nonlinear systems can be represented as a state-dependent convex combination of linear time-invariant systems (polytopic system); see e.g. [2729].
 
3
These ideas have been successfully applied in the context of switching controllers, see e.g. the references [9, 3439].
 
4
Nonsingularity of \(A_{22}\) automatically implies that the system is regular and impulse-free [45]. These conditions imply that for any compatible initial condition, there exists a unique continuous solution to (1.20).
 
5
The convex hull of a set \(S\) is the smallest convex set containing \(S\).
 
6
Readers interested in a short history of robust control theory should read M. G. Safonov’s paper [51].
 
7
It is a particular case of the more general equality (A.3).
 
Literatur
1.
G.D. Birkhoff, Dynamical Systems (American Mathematical Society, New York, 1927)MATH
2.
E. Sontag, Mathematical Control Theory: Deterministic Finite Dimensional Systems (Springer, New York, 1998)CrossRefMATH
3.
H.K. Khalil, Nonlinear Systems (Prentice-Hall, USA, 2002)MATH
4.
S. Smale, Differential Equations Dynamical Systems & an introduction to Chaos (Academic Press, New York, 2004)MATH
5.
J.S. Shamma, Analysis and design of gain-scheduled control systems. PhD thesis, Laboratory for Information and decision systems—Massachusetts Institute of Technology, 1988
6.
J.S. Shamma, An overview of LPV systems, in Control of Linear Parameter Varying Systems with Applications, ed. by J. Mohammadpour, C.W. Scherer (Springer, New York, 2012), pp. 3–26CrossRef
7.
J. Mohammadpour, C.W. Scherer (eds.), Control of Linear Parameter Varying Systems with Applications (Springer, New York, 2012)
8.
J.P. Hespanha, A.S. Morse, Stability of switched systems with average dwell-time, in 38th Conference on Decision and Control, Phoenix, Arizona, USA, 1999, pp. 2655–2660
9.
D. Liberzon, Switching in Systems and Control. Birkhäuser, 2003
10.
J.C. Geromel, P. Colaneri, Stability and stabilization of continuous-time switched linear systems. SIAM J. Control Optim. 45(5), 1915–1930 (2006)CrossRefMATHMathSciNet
11.
A.N. Michel, L. Hou, D. Liu, Stability of Dynamical Systems—Continuous, Discontinuous and Discrete Systems (Birkhäuser, Boston, 2008)MATH
12.
R. Goebel, R.G. Sanfelice, A.R. Teel, Hybrid dynamical systems. IEEE Control Syst. Mag. 29(2), 28–93 (2009)CrossRefMathSciNet
13.
C. Briat, A. Seuret, Affine minimal and mode-dependent dwell-time characterization for uncertain switched linear systems. IEEE Trans. Autom. Control 58(5), 1304–1310 (2013)CrossRefMathSciNet
14.
V.A. Yakubovich, V.M. Starzhinskii, Linear Differential Equations with Periodic Coefficients (Wiley, New York, 1975)MATH
15.
S. Bittanti, P. Colaneri, Periodic control systems, in Proceedings of the IFAC Workshop, Cernobbio-Como, Italy, Aug. 27–28, 2001, ed. by S. Bittanti, P. Colaneri
16.
P. Colaneri, Theoretical aspects of continuous-time periodic systems. Annu. Rev. Control 29, 205–215 (2005)CrossRef
17.
V.A. Yakubovich, A.L. Fradkov, D.J. Hill, A.V. Proskurnikov, Dissipativity of T-periodic linear systems. IEEE Trans. Autom. Control 52(6), 1039–1047 (2007)CrossRefMathSciNet
18.
J. Shamma, M. Athans, Analysis of gain scheduled control for nonlinear plants. IEEE Trans. Autom. Control 35(8), 898–907 (1990)CrossRefMATHMathSciNet
19.
J.S. Shamma, M. Athans, Gain scheduling: potential hazards and possible remedies. IEEE Contr. Syst. Mag. 12(3), 101–107 (1992)CrossRef
20.
D. Liberzon, J.P. Hespanha, A.S. Morse, Stability of switched systems: a Lie-algebraic condition. Syst. Control Lett. 37, 117–122 (1999)CrossRefMATHMathSciNet
21.
K. Tan, K.M. Grigoriadis, \({\cal {L}}_2-{\cal {L}}_2\) and \({\cal {L}}_2-{\cal {L}}_\infty \) output feedback control of time-delayed LPV systems, in Conference on on Decision and Control, 2000
22.
J.Y. Shin, Analysis of linear parameter varying system models based on reachable sets, in American Control Conference, Anchorage, AK, USA, 2002
23.
B. He, M. Yang, Robust LPV control of diesel auxiliary power unit for series hybrid electric vehicles. IEEE Trans. Power Electron. 21(3), 791–798 (2006)CrossRefMathSciNet
24.
M. Jung, K. Glover, Calibrate linear parameter-varying control of a turbocharged diesel engine. IEEE Trans. Control Syst. Technol. 14(1), 45–62 (2006)CrossRef
25.
X. Wei, L. del Re, Gain scheduled \({\cal {H}}_\infty \) control for air path systems of diesel engines using LPV techniques. IEEE Trans. Control Syst. Technol. 15(3), 406–415 (2007)
26.
B.A. White, L. Bruyere, A. Tsourdos, Missile autopilot design using quasi-LPV polynomial eigenstructure assignment. IEEE Trans. Aerosp. Electron. Syst. 43(4), 1470–1483 (2007)
27.
T. Takagi, M. Sugeno, Fuzzy identification of systems and its applications to modeling and control. IEEE Trans. Syst. Man Cybern. 15(1), 116–132 (1985)CrossRefMATH
28.
L.X. Wang, J.M. Mendel, Fuzzy basis functions, universal approximation and orthogonal least-squares. IEEE Trans. Neural Netw. 3(5), 807–814 (1992)CrossRef
29.
K. Tanaka, H.O. Wang, Fuzzy Control Systems Design and Analysis. A linear matrix inequality approach (Wiley, New York, 2001)
30.
F. Bruzelius, S. Petterssona, C. Breitholz, Linear parameter varying descriptions of nonlinear systems, in American Control Conference, Boston, Massachussetts, 2004
31.
C.S. Mehendale, K.M. Grigoriadis, A new approach to LPV gain-scheduling design and implementation, in 43rd IEEE Conference on Decision and Control, Atlantis, Paradise Island, Bahamas, 2004
32.
R.A. Nichols, R.T. Reichert, W.J. Rugh, Gain scheduling for H-infinity controllers: a flight control example. IEEE Trans. Control Syst. Technol. 1, 69–75 (1993)
33.
D.A. Lawrence, W.J. Rugh, Gain scheduling dynamic linear controllers for a nonlinear plant. Automatica 31(3), 381–390 (1995)CrossRefMATHMathSciNet
34.
35.
B. Lu, F. Wu, S. Kim, Switching LPV control of an F-16 aircraft via controller state reset. IEEE Trans. Control Syst. Technol. 14(2), 267–277 (2006)CrossRef
36.
P. Yan, H. Özbay, On switching \({H}_{\infty }\) controllers for a class of linear parameter varying systems. Syst. Control Lett. 56, 504–511 (2007)CrossRefMATH
37.
W. Jiang, E. Fridman, A. Kruszewski, J.-P. Richard, Switching controller for stabilization of linear systems with switched time-varying delays, in IEEE Conference on Decision and Control, pp. 7923–7928, 2009
38.
C. Prieur, A.R. Teel, Uniting local and global output feedback controllers. IEEE Trans. Autom. Control 56(7), 1636–1649 (2011)CrossRefMathSciNet
39.
B. Demirel, C. Briat, M. Johansson, Supervisory control design for networked systems with time-varying communication delays, in 4th IFAC Conference on Analysis and Design of Hybrid Systems, Eindovhen, The Netherlands, 2012, pp. 133–140
40.
P. Apkarian, H. D. Tuan, Parametrized LMIs in control theory, in Conference on Decision and Control, Tampa, Florida, 1998
41.
42.
A. Rehm, F. Allgöwer, Selft-scheduled \(H_\infty \) output feedback control of descriptor systems. Comput. Chem. Eng. 24, 279–284 (2000)
43.
I. Masubuchi, T. Akiyama, M. Saeki, Synthesis of output feedback gain-scheduling controllers based on descriptor LPV system representation, in 42nd IEEE Conference on Decision and Control, Maui, Hawaii, USA, 2003, pp. 6115–6120
44.
I. Masubuchi, J. Kato, M. Saeki, A. Ohara, Gain-scheduled controller design based on descriptor representation of LPV systems: Application to flight vehicle control, in 43rd IEEE Conference on Decision and Control, Atlantis, Paradise Island, Bahamas, USA, 2004, pp. 815–820
45.
46.
P. Apkarian, P. Gahinet, G. Becker, Self-scheduled control of linear parameter varying systems: a design example. Automatica 31(9), 1251–1261 (1995)CrossRefMATHMathSciNet
47.
48.
R.A. Borges, P.L.D. Peres, \({\cal {H}}_{\infty }\) LPV filtering for linear systems with arbitrarily time-varying parameters in polytopic domains, in Conference on Decision and Control, San Diego, USA, 2006
49.
R.C.L.F. Oliveira, V.F. Montagner, P.L.D. Peres, P. A. Bliman, LMI relaxations for \({\cal {H}}_\infty \) control of time-varying polytopic systems by means of parameter dependent quadratically stabilizing gains, in 3 \(^{rd}\) IFAC Symposium on System, Structure and Control, Foz do Iguassu, Brasil, 2007
50.
G. Chesi, A. Garulli, A. Tesi, A. Vicino, Homogeneous polynomial forms for robustness analysis of uncertain systems, Lecture Notes in Control and Information Sciences (Springer, Berlin, 2009)
51.
M.G. Safonov, Origins of robust control: early history and future speculations, in 7th IFAC Symposium on Robust Control Design, 2012, pp. 1–8
52.
V.M. Popov, Absolute stability of nonlinear systems of automatic control. Autom. Remote Control (Trans. Automatica i Telemekhanika) 22(8), 857–875 (1961)
53.
V.M. Popov, One problem in the theory of absolute stability of controlled systems. Autom. Remote Control 25(9), 1129–1134 (1964)
54.
A.I. Lur’e, Some Nonlinear Problems in the Theory of Automatic Control (Nekotorye Nelineinye Zadachi Teorii Automaticheskogo Regulirovaniya) (Gostekhizdat, Moscow, 1951)
55.
G. Zames, On the input output stability of time-varying nonlinear feecback systems, part i : conditions using concepts of loop gain, conicity and positivity. IEEE Trans. Aut. Control 11(2), 228–238 (1966)CrossRef
56.
M.G. Safonov, M. Athans, Gain and phase margin for multiloop LQG regulators. IEEE Trans. Autom. Control 22(2), 173–178 (1977)CrossRefMATHMathSciNet
57.
J.C. Doyle, Robustness of multiloop linear feedback systems, in 1978 IEEE Conference on Decision and Control, 1978, pp. 12–18
58.
K. Zhou, J.C. Doyle, K. Glover, Robust and Optimal Control (Prentice Hall, Upper Saddle River, 1996)MATH
59.
60.
61.
P. Apkarian, P. Gahinet, A convex characterization of gain-scheduled \({\cal {H}}_\infty \) controllers. IEEE Trans. Autom. Control 5, 853–864 (1995)
62.
63.
C.W. Scherer, I.E. Köse, Gain-scheduled control synthesis using dynamic D-scales. IEEE Trans. Autom. Control 57(9), 2219–2234 (2012)CrossRef
64.
M.G. Safonov, M. Athans, On stability theory, in 17th Conference on Decision and Control, San Diego, California, USA, 1978, pp. 301–314
65.
T. Iwasaki, S. Hara, Well-posedness of feedback systems: insight into exact robustness analysis and approximate computations. IEEE Trans. Autom. Control 43, 619–630 (1998)CrossRefMATHMathSciNet
66.
A. Megretski, A. Rantzer, System analysis via integral quadratic constraints. IEEE Trans. Autom. Control 42(6), 819–830 (1997)CrossRefMATHMathSciNet
67.
P. Apkarian, R.J. Adams, Advanced gain-scheduling techniques for uncertain systems. IEEE Trans. Autom. Control 6, 21–32 (1998)
68.
69.
S. Hecker, A. Varga, J.F. Magni, Enhanced LFR-toolbox for Matlab. Aerosp. Sci. Technol. 9, 173–180 (2005)CrossRefMATH
70.
D. de Vito, A. Kron, J. de la Fontaine, M. Lovera, A Matlab toolbox for LMI-based analysis and synthesis of LPV/LFT self-scheduled \(H_\infty \) control systems, in IEEE International Symposium on Computer-Aided Control System Design (CACSD’10), 2010, pp. 1397–1402
71.
B. Bamieh, L. Giarré, Identification of linear parameter varying models. Int. J. Robust Nonlinear Control 12, 841–853 (2002)CrossRefMATH
72.
R. Tóth, F. Felici, P.S.C. Heuberger, P. M. J. van der Hof, Discrete time LPV I/O and state space representations—differences of behavior and pitfalls of interpolation, in 9th European Control Conference, Kos, Greece, 2007, pp. 5418–5425
73.
R. Tóth, Modeling and identification of linear parameter-varying systems—an orthonormal basis function approach, PhD thesis, Technische Universiteit Delft, 2008
74.
R. Tóth, Modeling and Identification of Linear Parameter-Varying Systems (Springer, Germany, 2010)CrossRefMATH
75.
V. Cerone, D. Piga, D. Reguto, R. Tóth, Fixed order LPV controller design for LPV models in input-output form, in 51st IEEE Conference on Decision and Control, Maui, Hawaii, USA, 2012, pp. 6297–6302
76.
77.
78.
M. Halás, An algebraic framework generalizing the concept of transfer functions to nonlinear systems. Automatica 44, 1181–1190 (2008)CrossRefMATH
79.
H. Kajiwara, P. Apkarian, P. Gahinet, LPV techniques for control of an inverted pendulum. IEEE Control Syst. Mag. 19, 44–54 (1999)CrossRef
80.
C. Poussot-Vassal, M. Tanelli, M. Lovera, Linear parametrically varying MPC for combined quality of service and energy management in web service systems, in American Control Conference, 2010, pp. 3106–3111
81.
C. Poussot-Vassal, M. Tanelli, M. Lovera, A control-theoretic approach for the combined management of quality-of-service and energy in service centers, in Run-time Models for Self-managing Systems and Applications, Autonomic Systems, ed. by D. Ardagna, L. Zhang (Springer, Basel, 2010), pp. 73–96
82.
D. Robert, O. Sename, D. Simon, An \({\cal {H}}_\infty \) LPV design for sampling varying controllers: experimentation with a T-inverted pendulum. IEEE Trans. Control Syst. Technol. 18(3), 741–749 (2010)
83.
C. Poussot-Vassal, Global chassis control using a multivariable robust LPV control approach, PhD thesis, Grenoble-INP, 2008
84.
C. Moler, C. van Loan, Nineteen dubious ways to compute the exponential of a matrix, Twenty-five years later. SIAM Rev. 45(1), 3–49 (2003)CrossRefMATHMathSciNet
85.
S.M. Savaresi, C. Poussot-Vassal, C. Spelta, O. Sename, L. Dugard, Semi-active Suspension Control Design for Vehicles (Butterworth Heinemann, Oxford, 2010)
86.
C. Gauthier, O. Sename, L. Dugard, G. Meissonier, Modeling of a diesel engine common rail injection system, in 16th IFAC World Congress, Prague, Czech Republic, 2005
87.
C. Gauthier, O. Sename, L. Dugard, G. Meissonier, A \({\cal {H}}_\infty \) linear parameter varying (LPV) controller for a diesel engine common rail injection system, in European Control Conference, Kos, Greece, 2007
88.
C. Gauthier, O. Sename, L. Dugard, G. Meissonnier, An LFT approach to \({\cal {H}}_\infty \) control design for diesel engine common rail injection system. Oil Gas Sci. and Technol. Rev. IFP 62, 513–522 (2007)
89.
A. Kominek, H. Werner, M. Garwon, M. Schultalbers, Identification of low-complexity LPV input-output models for control of a turbocharged combustion engine, in Control of Linear Parameter Varying Systems with Applications, ed. by J. Mohammadpour, C.W. Scherer (Springer, New York, 2012), pp. 445–460CrossRef
90.
L. Reberga, D. Henrion, F. Vary, LPV modeling of a turbofan engine, in IFAC World Congress on Automatic Control, Prague, Szech Republic, 2005
91.
W. Gilbert, D. Henrion, J. Bernussou, Polynomial LPV synthesis applied to turbofan engines, in IFAC Symposium on Automatic Control in Aerospace, Toulouse, France, 2007
92.
A. Forrai, T. Ueda, T. Yumura, Electromagnetic actuator control: a linear parameter-varying (LPV) approach. IEEE Trans. Ind. Electron. 54(3), 1430–1441 (2007)CrossRef
93.
A. Kwiatkowski, H. Werner, LPV control of a 2-DOF robot using parameter reduction, in European Control Conference, Seville, Spain, 2005
94.
Q. Liu, V. Vittal, N Elia, LPV supplementary damping controller design thyristor controlled series capacacitor (TCSC) device. IEEE Trans. Power Syst. 21(3), 1242–1249 (2006)
95.
Q. Liu, V. Vittal, N Elia, Expansion of system operating range by an interpolated LPV FACTS controller using multiple Lyapunov functions. IEEE Trans. Power Syst. 21(3), 1311–1320 (2006)
96.
F. Daher Adegas, C. Solth, J. Stoustrup, Structured linear parameter varying control of wind turbines, in Control of Linear Parameter Varying Systems with Applications, ed. by J. Mohammadpour, C.W. Scherer (Springer, Heidelberg, 2012), pp. 303–337CrossRef
97.
S. Lim, J. How, Application of improved \({\cal {L}}_2\) gain synthesis on LPV missile autopilot design, in American Control Conference, San Diego, CA, USA, 1999
98.
J.M. Barker, G.J. Balas, Comparing linear parameter-varying gain-scheduled control techniques for active flutter suppression. J. Guidance, Control, Dyn. 23(5), 948–955 (2000)CrossRef
99.
A. Corti, M. Lovera, Attitude regulation for spacecraft with magnetic actuators: an LPV approach, in Control of Linear Parameter Varying Systems with Applications, ed. by J. Mohammadpour, C.W. Scherer (Springer, Heidelberg, 2012), pp. 339–355CrossRef
100.
H.D. Hughes, F. Wu, LPV \(H_\infty \) control for flexible hypersonic vehicle, in Control of Linear Parameter Varying Systems with Applications, ed. by J. Mohammadpour, C.W. Scherer (Springer, Heidelberg, 2012), pp. 413–444
101.
P. Seiler, G.J. Balas, A. Packard, Linear parameter-varying control for the X-53 active aeroelastic wing, in Control of Linear Parameter Varying Systems with Applications, ed. by J. Mohammadpour, C.W. Scherer (Springer, Heidelberg, 2012), pp. 483–512
102.
P. Gaspard, I. Szaszi, J. Bokor, Active suspension design using LPV control, in IFAC Symposium on Advances in Automotive Control, University of Salerno, Italy, April 2004
103.
C. Poussot-Vassal, O. Sename, L. Dugard, P. Gáspár, Z. Szabó, J. Bokor, Multi-objective qLPV \({\cal {H}}_\infty \)/\({\cal {H}}_2\) control of a half vehicle, in Proceedings of the 10th Mini-conference on Vehicle System Dynamics, Identification and Anomalies (VSDIA), Budapest, Hungary, November 2006
104.
C. Poussot-Vassal, A. Drivet, O. Sename, L. Dugard, R. Ramirez-Mendoza, A self tuning suspension controller for multi-body quarter vehicle model, in Proceedings of the 17th IFAC World Congress (WC), Seoul, South Korea, July 2008
105.
C. Poussot-Vassal, O. Sename, L. Dugard, P. Gáspár, Z. Szabó, J. Bokor, New semi-active suspension control strategy through LPV technique. Control Eng. Pract. 16, 1519–1534 (2008)CrossRef
106.
A.-L. Do, O. Sename, L. Dugard, LPV modeling and control of semi-active dampers in automotive systems, in Control of Linear Parameter Varying Systems with Applications, ed. by J. Mohammadpour, C.W. Scherer (Springer, Heidelberg, 2012), pp. 381–411
107.
C. Poussot-Vassal, C. SPelta, O. Sename, S.M. Savaresi, L. Dugard, Survey and performance evaluation on some automotive semi-active suspension control methods—a comparative study on a single-corner model. Annu. Rev. Control 36, 148–160 (2012)CrossRef
108.
P. Gáspár, Z. Szabó, J. Bokor, C. Poussot-Vassal, O. Sename, L. Dugard, Toward global chassis control by integrating the brake and suspension systems, in Proceedings of the 5th IFAC Symposium on Advances in Automotive Control (AAC), Aptos, California, USA, August 2007
109.
C. Poussot-Vassal, O. Sename, L. Dugard, P. Gáspár, Z. Szabó, J. Bokor, Attitude and handling improvements through gain-scheduled suspensions and brakes control, in Proceedings of the 17th IFAC World Congress (WC), Seoul, South Korea, July 2008
110.
Z. Szabó, P. Gáspár, J. Bokor, Design of integrated vehicle chassis control based on LPV methods, in Control of Linear Parameter Varying Systems with Applications, ed. by J. Mohammadpour, C.W. Scherer (Springer, Heidelberg, 2012), pp. 513–534CrossRef
111.
A. Kwiatkowski, J.P. Blath, H. Werner, M. Schultalbers, Application of LPV gain scheduling to charge control a SI engine, in IEEE Conference on Computer Aided Control Systems Design, Munich, Germany, 2006, pp. 2327–2331
112.
A. Kwiatkowski, J. P. Blath, H. Werner, A. Ali, M. Schultalbers, Linear parameter varying PID controller design for charge control of a spark-ignited engine. Control Eng. Pract. 17, 1307–1317 (2009)
113.
O. Sename, P. Gáspár, J. Bokor (eds.), Robust Control and Linear Parameter Varying Approaches—Application to Vehicle Dynamics (Springer, Berlin, 2013)
114.
M. Rodrigues, M. Sahnoun, D. Theilliol, J.-C. Ponsart, Sensor fault detection and isolation filter for polytopic lpv systems: a winding machine application. J. Process Control 23, 805–816 (2013)CrossRef
115.
M. Debert, G. Colin, G. Bloch, Y. Chamaillard, An observer looks at the cell temperature in automotive battery packs. Control Eng. Pract. 21, 1035–1042 (2013)CrossRef
116.
T. Luspay, T. Péni, B. Kulcsár, Constrained freeway traffic control via linear parameter varying paradigms, in Control of Linear Parameter Varying Systems with Applications, ed. by J. Mohammadpour, C.W. Scherer (Springer, Heidelberg, 2012), pp. 461–482CrossRef
117.
D. Robert, O. Sename, D. Simon, Synthesis of a sampling period dependent controller using LPV approach, in 5th IFAC Symposium on Robust Control Design ROCOND’06, Toulouse, France, 2006
118.
C. Briat, O. Sename, J.-F. Lafay, A LFT/\({\cal {H}}_\infty \) state-feedback design for linear parameter varying time delay systems, in 9th European Control Conference, Kos, Greece, 2007, pp. 4882–4888
119.
C. Briat, O. Sename, J.-F. Lafay, Delay-scheduled state-feedback design for time-delay systems with time-varying delays, in 17th IFAC World Congress, Seoul, South Korea, 2008, pp. 1267–1272
120.
C. Briat, O. Sename, J.-F. Lafay, Delay-scheduled state-feedback design for time-delay systems with time-varying delays—a LPV approach. Syst. Control Lett. 58(9), 664–671 (2009)CrossRefMATHMathSciNet
121.
C. Briat, O. Sename, J.-F. Lafay, \({\cal {H}}_\infty \) delay-scheduled control of linear systems with time-varying delays. IEEE Trans. Autom. Control 42(8), 2255–2260 (2009)
122.
S. M. Hashemi, H. Werner, Observer-based LPV control of a nonlinear PDE, in 50th IEEE Conference on Decision and Control, Orlando, Florida, USA, 2011, pp. 2010–2015
123.
H.D. Tuan, P. Apkarian, T.Q. Nguyen, Robust and reduced order filtering. IEEE Trans. Signal Process. 49, 2875–2984 (2001)CrossRef
124.
H. D. Tuan, P. Apkarian, T. Q. Nguyen, Robust filtering for uncertain nonlinearly parametrized plants. IEEE Trans. Signal Process. 51, 1806–1815 (2003)
125.
N.T. Hoang, H.D. Tuan, P. Apkarian, S. Hosoe, Gain-scheduled filtering for time-varying discrete systems. IEEE Trans. Signal Process. 52(9), 2464–2476 (2004)CrossRefMathSciNet
126.
R.A. Borges, V.F. Montagner, R.C.L.F. Oliveira, P.L.D. Peres, P.-A. Bliman, Parameter-dependent \({{H}}_2\) and \({{H}}_\infty \) filter design for linear systems with arbitrarily time-varying parameters in poltopic domains. Signal Process. 88, 1801–1816 (2008)CrossRefMATH
127.
M. Sato, Filter design for LPV systems using quadratically parameter-dependent Lyapunov functions. Automatica 42, 2017–2023 (2006)CrossRefMATH
128.
M. Sato, Gain-scheduled \(H_2\) filter synthesis via polynomially parameter-dependent Lyapunov functions with inexact scheduling parameters, in 19th International Symposium on Mathematical Theory of Networks and Systems, Budapest, Hungary, 2010, pp. 2291–2298
129.
M. Sato, Gain-scheduled \(H_\infty \) filters using inexactly measured scheduling parameters, in American Control Conference, Baltimore, Maryland, USA, 2010, pp. 3088–3093
130.
G. Iulia Bara, J. Daafouz, F. Kratz, J. Ragot, Parameter-dependent state observer design for affine LPV systems. Int. J. control 74(16), 1601–1611 (2001)
131.
J. Daafouz, G. I. Bara, F. Katz, J. Ragot, State observers for discrete-time LPV systems: an interpolation based approach, in 39th IEEE Conference on Decision and Control, Sydney, Australia, 2000, pp. 4571–4572
132.
J. Daafouz, G. Milerioux, L. Rosier, Observer design with guaranteed bound for LPV systems, in IFAC World Congress, Prague, Czech Republic, 2005, pp. 961–966
133.
F. Anstett, G. Millérioux, G. Bloch, Polytopic observer design for LPV systems based on minimal convex polytope finding. J Algorithms Comput. Technol. 3(1), 23–43 (2009)
134.
A.M. Gonzales, C. Hoffmann, C. Radisch, H. Werner, LPV observer design and damping control of container crane load swing, in European Control Conference, Zürich, Switzerland, 2013, pp. 1848–1853
135.
G.J. Balas, J. Bokor, Z. Szabo, Invariant subspaces for LPV systems and their application. IEEE Trans. Autom. Contr. 48, 2065–2069 (2003)CrossRefMathSciNet
136.
F. Wu, Control of linear parameter varying systems. PhD thesis, University of California Berkeley, 1995
137.
138.
M. Fu, Pole placement via static output feedback is NP-hard. IEEE Trans. Autom. Control 49(5), 855–857 (2004)CrossRef
139.
L. El-Ghaoui, F. Oustry, M.A. Rami, A cone complementary linearization algorithm for static output-feedback and related problems. IEEE Trans. Autom. Control 42, 1171–1176 (1997)CrossRefMATH
140.
141.
D. Peaucelle, D. Arzelier, Ellipsoidal sets for resilient and robust static output feedback. IEEE Trans. Autom. Control 50, 899–904 (2005)CrossRefMathSciNet
142.
D. Henrion, LMI optimization for fixed-order \(H_\infty \) controller design, in Positive Polynomials in Control, Lecture Notes in Control and Information Science, ed. by D. Henrion, A. Garulli (Springer, Heidelberg, 2005), pp. 73–85
143.
C.W.J. Hol, C.W. Scherer, A sum-of-squares approach to fixed-order \(H_\infty \) synthesis, in Positive Polynomials in Control, Lecture Notes in Control and Information Science, ed. by D. Henrion, A. Garulli (Springer, Heidelberg, 2005), pp. 45–71
144.
D. Henrion, J.B. Lasserre, Convergent relaxations of polynomial matrix inequalities and static output feedback. IEEE Trans. Autom. Control 51(2), 192–202 (2006)CrossRefMathSciNet
145.
J. de Caigny, J.F. Camino, R.C.L.F. Oliveira, P.L.D. Peres, J. Swevers, Gain-scheduled \({{H}}_2\) and \({{H}}_\infty \) control of discrete-time polytopic time-varying systems. IET Control Theory Appl. 4(3), 362–380 (2010)CrossRefMathSciNet
146.
B.-S. Hong, Observer-based paramterized LPV L2-gain control synthesis, in American Control Conference, Anchorage, Alaska, USA, 2002, pp. 4427–4432
147.
W.P.M.H. Heemels, J. Daafouz, G. Millerioux, Observer-based control of discrete-time LPV systems with uncertain parameters. IEEE Trans. Autom. Control 55(9), 2130–2135 (2010)CrossRefMathSciNet
148.
F. Wu, X.H. Yang, A. Packard, G. Becker, Induced \({\cal {L}}_2\)-norm control for LPV systems with bounded parameter variation rates. Int. J. Robust Nonlinear Control 6(9–10), 983–998 (1996)
149.
F. Wu, A generalized LPV system analysis and control synthesis framework. Int. J. Control 74, 745–759 (2001)CrossRefMATH
150.
K. Tan, K.M. Grigoriadis, F. Wu, Output-feedback control of LPV sampled-data systems. Int. J. Control 75(4), 252–264 (2002)CrossRefMATHMathSciNet
151.
M. Sato, D. Peaucelle, Gain-scheduled output-feedback controllers using inexact scheduling parameters for continuous-ime LPV systems. Automatica 49, 1019–1025 (2013)CrossRefMATHMathSciNet
152.
J. Daafouz, J. Bernussou, J.C. Geromel, On inexact LPV control design of continuous-time polytopic systems. IEEE Trans. Autom. Control 53(7), 1674–1978 (2008)CrossRefMathSciNet
Metadaten
Titel
Introduction to LPV Systems
verfasst von
Corentin Briat
Copyright-Jahr
2015
Verlag
Springer Berlin Heidelberg
Buch
Linear Parameter-Varying and Time-Delay Systems

Print ISBN: 978-3-662-44049-0

Electronic ISBN: 978-3-662-44050-6

Copyright-Jahr: 2015

DOI
https://doi.org/10.1007/978-3-662-44050-6_1

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