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3 - Analysis of Reference Tracking in LPNI Systems

Published online by Cambridge University Press:  01 June 2011

ShiNung Ching ,
Yongsoon Eun ,
Cevat Gokcek ,
Pierre T. Kabamba  and
Semyon M. Meerkov
ShiNung Ching
Affiliation:
Massachusetts Institute of Technology
Yongsoon Eun
Affiliation:
Xerox Center for Research and Technology
Cevat Gokcek
Affiliation:
Michigan State University
Pierre T. Kabamba
Affiliation:
University of Michigan
Semyon M. Meerkov
Affiliation:
University of Michigan
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Summary

Motivation: This chapter is intended to quantify steady state errors and transient performance of LPNI systems in the problem of tracking reference signals.

For linear systems, the steady state error in tracking deterministic references is characterized by the notion of system type, defined by the poles of the loop gain at the origin. This definition is not applicable to LPNI systems since, if the actuator saturates, controller poles at the origin play a different role than those of the plant and, thus, the loop gain does not define the system type. This motivates the first goal of this chapter, which is to introduce the notion of system type for LPNI systems.

Also in contrast with the linear case, LPNI systems with saturating actuators are not capable of tracking steps with arbitrary amplitudes. This motivates the second goal of this chapter: to introduce and quantify the notion of trackable domains, that is, the sets of step (or ramp, or parabolic) input magnitudes that can, in fact, be tracked by an LPNI system.

As far as the transients are concerned, the usual step tracking measures, such as overshoot, settling time, and so on, are clearly not appropriate for random references. The variance of tracking errors, as it turns out, is not a good measure either, since for the same variance, the nature of tracking errors can be qualitatively different.

Type
Chapter
Information
Quasilinear Control
Performance Analysis and Design of Feedback Systems with Nonlinear Sensors and Actuators
 , pp. 66 - 113
Publisher: Cambridge University Press
Print publication year: 2010

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References

[3.1] Y., Eun, P.T., Kabamba, and S.M., Meerkov, “System types in feedback control with saturating actuators,” IEEE Transactions on Automatic Control, Vol. 49, pp. 287–291, 2004Google Scholar
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[3.7] Y., Eun, P.T., Kabamba, and S.M., Meerkov, “Tracking random references: Random sensitivity function and tracking quality indicators,” IEEE Transactions on Automatic Control, Vol. 48, pp. 1666–1671, 2003Google Scholar
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