High-order iterative learning control : convergence, robustness and applications

High-order iterative learning control : convergence, robustness and applications

Several new aspects of Iterative Learning Control (ILC) have been addressed and investigated for a better understanding of the fact that improved control performance can be achieved from system's repetitive operations. Firstly, a high-order ILC scheme is proposed and explained in the iteration...

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Main Author: Chen, Yangquan.
Other Authors: Wen, Changyun
Format: Theses and Dissertations
Published: 2010
Subjects:
DRNTU::Engineering::Electrical and electronic engineering::Control and instrumentation::Control engineering
Online Access:http://hdl.handle.net/10356/38969
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Institution: Nanyang Technological University
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spelling sg-ntu-dr.10356-389692023-07-04T15:26:38Z High-order iterative learning control : convergence, robustness and applications Chen, Yangquan. Wen, Changyun School of Electrical and Electronic Engineering DRNTU::Engineering::Electrical and electronic engineering::Control and instrumentation::Control engineering Several new aspects of Iterative Learning Control (ILC) have been addressed and investigated for a better understanding of the fact that improved control performance can be achieved from system's repetitive operations. Firstly, a high-order ILC scheme is proposed and explained in the iteration number direction. By considering the dynamics along the ILC iteration number direction, the high-order scheme offers additional po-tentials in the improvement of ILC convergence property compared to the conventional first-order scheme which is merely an integral controller. Secondly, the use of current iter-ation tracking error information is shown to be helpful in tuning the tracking error bound and the ILC convergence rate. Thirdly, ILC for uncertain discrete-time nonlinear sys-tems has been studied systematically with the consideration of actuator saturation. The ILC scheme with a feedback controller and the ILC scheme utilizing the current iteration tracking error are investigated respectively and their differences are discussed explicitly. Fourthly, the ILC scheme with an iterative initial state learning method is shown to be effective to remove a commonly used re-initialization assumption in the conventional ILC methods. The unknown desired states can be identified through the ILC process. Fifthly, the terminal ILC is proposed when only the terminal output tracking error is measurable at the end of each run. This new point-to-point control method is applied to a rapid thermal processing chemical vapor deposition (RTPCVD) thickness control problem in wafer fab industry. Doctor of Philosophy (EEE) 2010-05-21T03:37:54Z 2010-05-21T03:37:54Z 1997 1997 Thesis http://hdl.handle.net/10356/38969 NANYANG TECHNOLOGICAL UNIVERSITY 236 p. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
topic DRNTU::Engineering::Electrical and electronic engineering::Control and instrumentation::Control engineering
spellingShingle DRNTU::Engineering::Electrical and electronic engineering::Control and instrumentation::Control engineering
Chen, Yangquan.
High-order iterative learning control : convergence, robustness and applications
description Several new aspects of Iterative Learning Control (ILC) have been addressed and investigated for a better understanding of the fact that improved control performance can be achieved from system's repetitive operations. Firstly, a high-order ILC scheme is proposed and explained in the iteration number direction. By considering the dynamics along the ILC iteration number direction, the high-order scheme offers additional po-tentials in the improvement of ILC convergence property compared to the conventional first-order scheme which is merely an integral controller. Secondly, the use of current iter-ation tracking error information is shown to be helpful in tuning the tracking error bound and the ILC convergence rate. Thirdly, ILC for uncertain discrete-time nonlinear sys-tems has been studied systematically with the consideration of actuator saturation. The ILC scheme with a feedback controller and the ILC scheme utilizing the current iteration tracking error are investigated respectively and their differences are discussed explicitly. Fourthly, the ILC scheme with an iterative initial state learning method is shown to be effective to remove a commonly used re-initialization assumption in the conventional ILC methods. The unknown desired states can be identified through the ILC process. Fifthly, the terminal ILC is proposed when only the terminal output tracking error is measurable at the end of each run. This new point-to-point control method is applied to a rapid thermal processing chemical vapor deposition (RTPCVD) thickness control problem in wafer fab industry.
author2 Wen, Changyun
author_facet Wen, Changyun
Chen, Yangquan.
format Theses and Dissertations
author Chen, Yangquan.
author_sort Chen, Yangquan.
title High-order iterative learning control : convergence, robustness and applications
title_short High-order iterative learning control : convergence, robustness and applications
title_full High-order iterative learning control : convergence, robustness and applications
title_fullStr High-order iterative learning control : convergence, robustness and applications
title_full_unstemmed High-order iterative learning control : convergence, robustness and applications
title_sort high-order iterative learning control : convergence, robustness and applications
publishDate 2010
url http://hdl.handle.net/10356/38969
_version_ 1772827484791767040

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