Gap metric based robustness analysis of nonlinear systems with full and partial feedback linearization

A. Al-Gburi; C. T. Freeman; M. C. French

doi:10.1080/00207179.2017.1316425

Gap metric based robustness analysis of nonlinear systems with full and partial feedback linearization

A. Al-Gburi, C. T. Freeman, M. C. French

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3 Citations (Scopus)

Abstract

This paper uses gap metric analysis to derive robustness and performance margins for feedback linearizing controllers. Distinct from previous robustness analysis, it incorporates the case of output unstructured uncertainties, and is shown to yield general stability conditions which can be applied to both stable and unstable plants. It then expands on existing feedback linearizing control schemes by introducing a more general robust feedback linearizing control design which classifies the system nonlinearity into stable and unstable components and cancels only the unstable plant nonlinearities. This is done in order to preserve the stabilizing action of the inherently stabilizing nonlinearities. Robustness and performance margins are derived for this control scheme, and are expressed in terms of bounds on the plant nonlinearities andthe accuracy of the cancellation of the unstable plant nonlinearity by the controller. Case studies then confirm reduced conservatism compared with standard methods.

Original language	English
Pages (from-to)	1385-1402
Number of pages	18
Journal	INTERNATIONAL JOURNAL OF CONTROL
Volume	91
Issue number	6
DOIs	https://doi.org/10.1080/00207179.2017.1316425
Publication status	Published - 1 Apr 2017

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abstract = "This paper uses gap metric analysis to derive robustness and performance margins for feedback linearizing controllers. Distinct from previous robustness analysis, it incorporates the case of output unstructured uncertainties, and is shown to yield general stability conditions which can be applied to both stable and unstable plants. It then expands on existing feedback linearizing control schemes by introducing a more general robust feedback linearizing control design which classifies the system nonlinearity into stable and unstable components and cancels only the unstable plant nonlinearities. This is done in order to preserve the stabilizing action of the inherently stabilizing nonlinearities. Robustness and performance margins are derived for this control scheme, and are expressed in terms of bounds on the plant nonlinearities andthe accuracy of the cancellation of the unstable plant nonlinearity by the controller. Case studies then confirm reduced conservatism compared with standard methods.",

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AB - This paper uses gap metric analysis to derive robustness and performance margins for feedback linearizing controllers. Distinct from previous robustness analysis, it incorporates the case of output unstructured uncertainties, and is shown to yield general stability conditions which can be applied to both stable and unstable plants. It then expands on existing feedback linearizing control schemes by introducing a more general robust feedback linearizing control design which classifies the system nonlinearity into stable and unstable components and cancels only the unstable plant nonlinearities. This is done in order to preserve the stabilizing action of the inherently stabilizing nonlinearities. Robustness and performance margins are derived for this control scheme, and are expressed in terms of bounds on the plant nonlinearities andthe accuracy of the cancellation of the unstable plant nonlinearity by the controller. Case studies then confirm reduced conservatism compared with standard methods.

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Gap metric based robustness analysis of nonlinear systems with full and partial feedback linearization

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