Title: Study of the periodic time-varying nonlinear iterative learning control
1Study of the periodic time-varying nonlinear
iterative learning control
- ECE 6330 Nonlinear and Adaptive Control
- FISP
- Hyo-Sung Ahn
- Dept of Electrical and Computer Engineering
- Utah State University
2Backgrounds of Iterative Learning Control (ILC)
- ? Leading researchers in ILC Leading research
groups around world Dr. Arimoto, Dr. Moore and
Dr. Chens group, Dr. Rogers and Dr. Owens
group, Dr. Longman, Dr. Xu, Dr. Bien, Dr. Amann,
etc. - ? Categories Linear system ILC, Nonlinear
system linear ILC, Nonlinear system nonlinear
ILC, Super-vector ILC.
3Nonlinear System Iterative Learning Control
- ? Major assumption
- and are globally
Lipschitz continuous
? Nonlinear system Type 1
? Learning controller (high order ILC)
4Stability Condition and Controller
? Stability condition (asymptotically
convergence)
? Learning controller (if only typical gains are
used, r 0) Stability condition
5Nonlinear system (SISO) Type 2
? Learning controller
? Stability condition
6Nonlinear system (MIMO) Type 3
? Learning controller
? Stability condition
7Iterative Learning Controller Design
- ? KLM and YQC High order ILC in time domain,
High order ILC in iteration domain, PI, PD type
in iteration domain optimal design, Feedback
controller (2002, ASCC), and Super-vector ILC. - ? Owens, et al. Optimal algorithm (2003 IJC).
- ? Hatonen, et al. Time-variant ILC control laws
(2004 IJC). - ? Amann et al. Optimization method (?).
- ? Jian-Xin Xu Nonlinear ILC and convergence
speed, time varying periodic parameter. - ? LQ method(?) James A. Frueh, IJC 2000.
- Longman Frequency domain analysis
8Observer Based Time Varying Iterative Learning
Control Problem Definition
- ? There is periodically time dependent parameter
uncertainty - ? States are not measured directly, so observer
is needed - ? Periodically time dependent parameter is
adapted - ? States are estimated
- ? Lyapunov analysis is indispensable
9Systems
Consider following system Jina-Xin Xu and Jing
Xu, IEEE TAC, Vol. 49, No. 2, Feb, 2004
where is unknown
periodically time varying parameter, is
known system dynamics (assumed as Lipschitz
continuous), and z could be X and Y. In this
report, we assume that z X. Because is
periodically time varying and A, B, C are known,
we can apply iterative learning control. Also,
it is assumed that state X are not directly
measured. So, observer is used in this method.
10Observer Jina-Xin Xu and Jing Xu, IEEE TAC, Vol.
49, No. 2, Feb, 2004
L is design parameter
11Controller Jina-Xin Xu and Jing Xu, IEEE TAC,
Vol. 49, No. 2, Feb, 2004
and are time dependent positive diagonal
matrices
12Theorem
- ? The control law, the algebraic learning
law, and the adaptation law ensure the
convergence of the state estimation and the
output tracking in norm. - ? Proof Jina-Xin Xu and Jing Xu, IEEE
TAC, Vol. 49, No. 2, Feb, 2004
13Example
14Target Trajectory, Input Disturbance, Design
Parameters
So,
15Signal tracking errors
16Estimated state errors
17True periodically time varying parameter and
adaptive parameter
18True periodically time varying parameter and
adaptive parameter
19Conclusions
- ? Good Results
- ? Two new approaches in observer based time
varying nonlinear ILC - - Observer design Parameters are
estimated in adaptive way. - - Periodically time varying parameter ILC
tries to minimize the reference tracking signal
error. - ? Possible future research works
- - Can we find new adaptation dynamics
based on Lyapunov analysis on new system model? - - Can we apply above theorem to
super-vector ILC, which has parameter
uncertainties? - - What does thing happen, when there is a
periodic uncertain parameter in measured output? - - With non-periodic uncertain parameter, the
stochastic ILC (Kalman filter)? - - Whats the relationship?