An analysis and design framework for robust control of a multi-axis active vibration isolation system with unknown payload

An analysis and design framework for robust control of a multi-axis active vibration isolation system with unknown payload

© The Author(s) 2013. This paper presents a framework for model-based analysis of robust stability and performance for a multi-axis active vibration isolation system with constant but unknown payload and subject to modelling errors associated with structural flexibility. The theoretical treatment in...

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Main Authors: Wichaphon Fakkaew, Theeraphong Wongratanaphisan, Matthew O T Cole
Format: Journal
Published: 2018
Subjects:
Engineering
Materials Science
Online Access:https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84924956010&origin=inward
http://cmuir.cmu.ac.th/jspui/handle/6653943832/54521
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Institution: Chiang Mai University
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spelling th-cmuir.6653943832-545212018-09-04T10:18:11Z An analysis and design framework for robust control of a multi-axis active vibration isolation system with unknown payload Wichaphon Fakkaew Theeraphong Wongratanaphisan Matthew O T Cole Engineering Materials Science © The Author(s) 2013. This paper presents a framework for model-based analysis of robust stability and performance for a multi-axis active vibration isolation system with constant but unknown payload and subject to modelling errors associated with structural flexibility. The theoretical treatment involves a linear time-invariant system subject to real parameter uncertainty associated with the unknown payload. A set of performance indices are formulated based on generalized H2 (Hg) and H∞ measures. A method for stability/performance verification is then developed using a parameter-dependent Lyapunov function that incorporates the kinetic energy of the uncertain payload mass. This allows nonconservative bounds on the performance indices to be established via numerical solution of a corresponding set of matrix inequalities. The approach is especially suitable, and computationally efficient, for multi-degree-of-freedom systems as the overall (symmetric positive-definite) properties of the system mass matrix are accounted for without involving information for each scalar parameter. The associated LMIs can therefore be solved in polynomial time with respect to the number of unknown parameters. Numerical examples for the case of sky-hook damping control and multi-objective Hg/H∞ control are provided that demonstrate the effectiveness of the method as a tool for model-based controller evaluation and multi-objective optimization. 2018-09-04T10:15:21Z 2018-09-04T10:15:21Z 2015-01-01 Journal 17412986 10775463 2-s2.0-84924956010 10.1177/1077546313494099 https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84924956010&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/54521
institution Chiang Mai University
building Chiang Mai University Library
country Thailand
collection CMU Intellectual Repository
topic Engineering
Materials Science
spellingShingle Engineering
Materials Science
Wichaphon Fakkaew
Theeraphong Wongratanaphisan
Matthew O T Cole
An analysis and design framework for robust control of a multi-axis active vibration isolation system with unknown payload
description © The Author(s) 2013. This paper presents a framework for model-based analysis of robust stability and performance for a multi-axis active vibration isolation system with constant but unknown payload and subject to modelling errors associated with structural flexibility. The theoretical treatment involves a linear time-invariant system subject to real parameter uncertainty associated with the unknown payload. A set of performance indices are formulated based on generalized H2 (Hg) and H∞ measures. A method for stability/performance verification is then developed using a parameter-dependent Lyapunov function that incorporates the kinetic energy of the uncertain payload mass. This allows nonconservative bounds on the performance indices to be established via numerical solution of a corresponding set of matrix inequalities. The approach is especially suitable, and computationally efficient, for multi-degree-of-freedom systems as the overall (symmetric positive-definite) properties of the system mass matrix are accounted for without involving information for each scalar parameter. The associated LMIs can therefore be solved in polynomial time with respect to the number of unknown parameters. Numerical examples for the case of sky-hook damping control and multi-objective Hg/H∞ control are provided that demonstrate the effectiveness of the method as a tool for model-based controller evaluation and multi-objective optimization.
format Journal
author Wichaphon Fakkaew
Theeraphong Wongratanaphisan
Matthew O T Cole
author_facet Wichaphon Fakkaew
Theeraphong Wongratanaphisan
Matthew O T Cole
author_sort Wichaphon Fakkaew
title An analysis and design framework for robust control of a multi-axis active vibration isolation system with unknown payload
title_short An analysis and design framework for robust control of a multi-axis active vibration isolation system with unknown payload
title_full An analysis and design framework for robust control of a multi-axis active vibration isolation system with unknown payload
title_fullStr An analysis and design framework for robust control of a multi-axis active vibration isolation system with unknown payload
title_full_unstemmed An analysis and design framework for robust control of a multi-axis active vibration isolation system with unknown payload
title_sort analysis and design framework for robust control of a multi-axis active vibration isolation system with unknown payload
publishDate 2018
url https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84924956010&origin=inward
http://cmuir.cmu.ac.th/jspui/handle/6653943832/54521
_version_ 1681424335914401792

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