MTNS 06, Kyoto (July, 2006) Shinji Hara The University of Tokyo, Japan
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1 MTNS 06, Kyoto (July, 2006) Shinji Hara The University of Tokyo, Japan
2 Outline Motivation & Background: H2 Tracking Performance Limits: new paradigm Explicit analytical solutions with examples H2 Regulation Performance Limits: Explicit analytical solutions with examples Phase Property vs Achievable Robustness Performance H_inf loop shaping procedure - Concluding remarks
3
4 New Paradigm on Control Theory Find r(t) e(t) Best u(t) - K(s) d(t) Given P(s) y(t) d(t) Characterize r(t) - e(t) Best K(s) u(t) Desirable P(s) y(t)
5 Bode Integral Relation Assumption L(s)=P(s)K(s): stable, r.d. >1 0 log( Closed-loop system: stable S( jω ) ) dω = 0 π pi S( jω ) ω S( s) : = 1+ 1 P( s) K( s)
6 Question! Is any stable & MP plant always easy to control under physical constraints in practice? control input energy measurement accuracy sampling period channel capacity etc. Answer: NO! Aim of researches on control perf.. limits: Characterization of easily controllable plants in practical situations
7 3-Disk Torsion System ª ªª ª ªª ª ªª J 3 J 1 θ 3 θ J 1 2 J 2 θ 2 θ 2 J 3 J 1 θ θ 1 3 ªªª ªª c 3 c k 1 2 k 1 c 2 c k 2 1 k 2 T u c 3 c 1 poles Disk 1 Disk 2 All 3 TFs are marginally stable & MP, but the achievable performances are different.
8 Step responses Disk1 Disk2 Disk1 is better than Disk2. Why?
9 Question! Is any stable & MP plant always easy to control under physical constraints in practice? Aim of researches on control perf.. limits: Characterization of easily controllable plants in practical situations New Paradigm From Controller Design to Plant Design To provide guidelines of plant design from the view point of control
10 Best Tracking and Regulation Performance under Control Energy Constraint by J. Chen, S. Hara & G. Chen, IEEE TAC (2003) Optimal Tracking Performance for SIMO Feedback Control Systems: Analytical closed-form expressions and guaranteed accuracy computation by S. Hara, M. Kanno & T. Bakhtiar, CDC 06 (submitted)
11 Control Performance Limitations Bode Integral Relation SISO stable/unstable MIMO Discrete-time/Sampled-data Nonlinear H-inf norm performance Time-response performance Tracking performance (H2 norm) Regulation performance (H2 norm) Special issue in IEEE TAC, Aug.,2003 Seron et. al. Fundamental Limitations in Filtering and Control
12 H2 Optimal Tracking Problem unit step input SIMO plant Performance Index: tracking error control effort
13 G w(t) u(t) y(t) z(t) P P K(s) K(s) 1/s - = ) ( ) ( 1/ 0 1/ ) ( s P W s P s s s G u Analytic solution closed-form Riccati & LMI 1 W u e(t)
14 SISO marginally stable plant NMP zeros Plant gain
15 Numerical Example 1 ( = ) 2 W u J 2 * a 1.0 z 1 = 1 z1 = 1
16 Application to 3-disk 3 torsion system Disk 3 Disk 2 Disk 1 W u
17 Discrete-time time case NMP zeros Plant gain Delta Operator Continuous-time result
18 General SIMO Case Numerator: Unstable poles & NMP zeros:
19 Stable terms: NMP zeros Plant gain
20 Unstable terms: Unstable poles Unstable pole / NMP zeros
21 Remarks: Several cases where the computation of is not required. SIMO marginally stable SISO non control input penalty SIMO SIMO unstable: common unstable poles Jcu=0 many applications
22 Optimal length of Inv. Pend.?
23 Tracking performance limit J * c l (m)
24 Discrete-time time case NMP zeros Plant gain Delta Operator Continuous-time result
25 Best Tracking and Regulation Performance under Control Energy Constraint by J.Chen, S.Hara & G.Chen, IEEE TAC (2003) H2 Regulation Performance Limits for SIMO Feedback Control Systems by T.Bakhtiar & S.Hara, MTNS 06
26 H2 Optimal Regulation Problem Impulse input Performance Index : SIMO plant performance on disturbance rejection control effort
27 SISO MP plant unstable poles Plant gain
28 Numerical Example via Theorem 1 via Toolbox 2500 * E c E c * p p
29 SIMO NMP plant Common NMP zeros MP case
30 Application to a Magnetic Bearing System Normalized state-space equation:
31 one unstable pole at p current sensor: position sensor: multiple sensors: NMP MP MP
32
33 SISO MP discrete-time time plant: r.d.=1 Delta Operator Continuous-time result
34 Magnetic bearing system: caused by discretized NMP zeros
35 Dynamical System Design from a Control Perspective: Finite frequency positive-realness approach by T. Iwasaki & S. Hara, IEEE TAC (2003) Finite Frequency Phase Property Versus Achievable Control Performance in H_inf Loop Shaping Design by S. Hara, M. Kanno & M. Onishi, SICE-ICCAS 06 (to be presented)
36 FFPR (Finite Frequency Positive Realness)
37 Finite Frequency Positive Realness + < D D B B C I A C I A T T T X Y Y 2 ω 0 X, ) ( = D C B A G s (LMI condition) > + 0, ) ( ) ( * ω ω jω G j G 0 ω ω 0 > 0 given.., 0 t s Y Y X X T T = > =
38 Hinf LSDP (Hinf Loop-Shaping Design Procedure)
39 Good Phase Property
40 2 nd order plant
41 Characterization of good plants
42 Numerical Example P(s) K(s) L(s)=P(s)K(s) Nyquist plots Bode diagrams
43 Explicit analytical solutions for H2 tracking performance limits H2 regulation performance limits Finite frequency phase property vs achievable robustness performance in H_inf LSDP Characterizations of easily controllable plants in practical situations, which provide guidelines of plant design from the view point of control
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