Analysis and Control of Non-Affine, Non-Standard, Singularly Perturbed Systems

This dissertation addresses the control problem for the general class of control non-affine, non-standard singularly perturbed continuous-time systems. The problem of control for nonlinear multiple time scale systems is addressed here for the first time in a systematic manner. Toward this end, this...

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Main Author: Narang, Anshu
Other Authors: Valasek, John
Format: Others
Published: 2013
Subjects:
Online Access:http://hdl.handle.net/1969.1/148104
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spelling ndltd-tamu.edu-oai-repository.tamu.edu-1969.1-1481042013-03-16T03:51:39ZAnalysis and Control of Non-Affine, Non-Standard, Singularly Perturbed SystemsNarang, AnshuTracking and regulationFlight controlNon-Minimum phase systemsSingular perturbationsMultiple time scaleNonlinear control theoryThis dissertation addresses the control problem for the general class of control non-affine, non-standard singularly perturbed continuous-time systems. The problem of control for nonlinear multiple time scale systems is addressed here for the first time in a systematic manner. Toward this end, this dissertation develops the theory of feedback passivation for non-affine systems. This is done by generalizing the Kalman-Yakubovich-Popov lemma for non-affine systems. This generalization is used to identify conditions under which non-affine systems can be rendered passive. Asymptotic stabilization for non-affine systems is guaranteed by using these conditions along with well-known passivity-based control methods. Unlike previous non-affine control approaches, the constructive static compensation technique derived here does not make any assumptions regarding the control influence on the nonlinear dynamical model. Along with these control laws, this dissertation presents novel hierarchical control design procedures to address the two major difficulties in control of multiple time scale systems: lack of an explicit small parameter that models the time scale separation and the complexity of constructing the slow manifold. These research issues are addressed by using insights from geometric singular perturbation theory and control laws are designed without making any assumptions regarding the construction of the slow manifold. The control schemes synthesized accomplish asymptotic slow state tracking for multiple time scale systems and simultaneous slow and fast state trajectory tracking for two time scale systems. The control laws are independent of the scalar perturbation parameter and an upper bound for it is determined such that closed-loop system stability is guaranteed. Performance of these methods is validated in simulation for several problems from science and engineering including the continuously stirred tank reactor, magnetic levitation, six degrees-of-freedom F-18/A Hornet model, non-minimum phase helicopter and conventional take-off and landing aircraft models. Results show that the proposed technique applies both to standard and non-standard forms of singularly perturbed systems and provides asymptotic tracking irrespective of the reference trajectory. This dissertation also shows that some benchmark non-minimum phase aerospace control problems can be posed as slow state tracking for multiple time scale systems and techniques developed here provide an alternate method for exact output tracking.Valasek, John2013-03-14T16:13:17Z2012-122012-09-18December 20122013-03-14T16:13:17ZThesistextapplication/pdfhttp://hdl.handle.net/1969.1/148104
collection NDLTD
format Others
sources NDLTD
topic Tracking and regulation
Flight control
Non-Minimum phase systems
Singular perturbations
Multiple time scale
Nonlinear control theory
spellingShingle Tracking and regulation
Flight control
Non-Minimum phase systems
Singular perturbations
Multiple time scale
Nonlinear control theory
Narang, Anshu
Analysis and Control of Non-Affine, Non-Standard, Singularly Perturbed Systems
description This dissertation addresses the control problem for the general class of control non-affine, non-standard singularly perturbed continuous-time systems. The problem of control for nonlinear multiple time scale systems is addressed here for the first time in a systematic manner. Toward this end, this dissertation develops the theory of feedback passivation for non-affine systems. This is done by generalizing the Kalman-Yakubovich-Popov lemma for non-affine systems. This generalization is used to identify conditions under which non-affine systems can be rendered passive. Asymptotic stabilization for non-affine systems is guaranteed by using these conditions along with well-known passivity-based control methods. Unlike previous non-affine control approaches, the constructive static compensation technique derived here does not make any assumptions regarding the control influence on the nonlinear dynamical model. Along with these control laws, this dissertation presents novel hierarchical control design procedures to address the two major difficulties in control of multiple time scale systems: lack of an explicit small parameter that models the time scale separation and the complexity of constructing the slow manifold. These research issues are addressed by using insights from geometric singular perturbation theory and control laws are designed without making any assumptions regarding the construction of the slow manifold. The control schemes synthesized accomplish asymptotic slow state tracking for multiple time scale systems and simultaneous slow and fast state trajectory tracking for two time scale systems. The control laws are independent of the scalar perturbation parameter and an upper bound for it is determined such that closed-loop system stability is guaranteed. Performance of these methods is validated in simulation for several problems from science and engineering including the continuously stirred tank reactor, magnetic levitation, six degrees-of-freedom F-18/A Hornet model, non-minimum phase helicopter and conventional take-off and landing aircraft models. Results show that the proposed technique applies both to standard and non-standard forms of singularly perturbed systems and provides asymptotic tracking irrespective of the reference trajectory. This dissertation also shows that some benchmark non-minimum phase aerospace control problems can be posed as slow state tracking for multiple time scale systems and techniques developed here provide an alternate method for exact output tracking.
author2 Valasek, John
author_facet Valasek, John
Narang, Anshu
author Narang, Anshu
author_sort Narang, Anshu
title Analysis and Control of Non-Affine, Non-Standard, Singularly Perturbed Systems
title_short Analysis and Control of Non-Affine, Non-Standard, Singularly Perturbed Systems
title_full Analysis and Control of Non-Affine, Non-Standard, Singularly Perturbed Systems
title_fullStr Analysis and Control of Non-Affine, Non-Standard, Singularly Perturbed Systems
title_full_unstemmed Analysis and Control of Non-Affine, Non-Standard, Singularly Perturbed Systems
title_sort analysis and control of non-affine, non-standard, singularly perturbed systems
publishDate 2013
url http://hdl.handle.net/1969.1/148104
work_keys_str_mv AT naranganshu analysisandcontrolofnonaffinenonstandardsingularlyperturbedsystems
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