Feedback stability of negative imaginary systems

Alexander Lanzon, Hsueh-Ju Chen

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    This paper extends the robust feedback stability theorem of negative imaginary systems by removing restrictive assumptions on the instantaneous gains of the systems that were imposed in the earlier literature, and it further generalises this robust analysis result into the case that allows negative imaginary systems to have poles at the origin. In so doing, we extend the class of negative imaginary systems for which this robust stability theorem is applicable. We also show that this new generalised necessary and sufficient result specialises to the earlier theorems under the same assumptions. We additionally prove that the previously known dc gain condition is not only necessary and sufficient for robust feedback stability under the earlier specified instantaneous gain assumptions, but is also necessary and sufficient for robust feedback stability under new, different and equally simple assumptions. The general robust feedback stability theorem for negative imaginary systems with free body dynamics (i.e. poles at the origin) derived in this paper also specialises to the case that is only applicable for the negative imaginary system without poles at the origin. Since the results for negative imaginary systems with free body dynamics developed n this paper depend on the existence of a matrix with certain properties, we also propose a systematic construction of this matrix and show that construction of one such is sufficient for determining the feedback stability of the closed-loop system.
    Finally, examples are used to demonstrate the applicability of the results.
    Original languageEnglish
    Pages (from-to)5620 - 5633
    JournalIEEE Transactions on Automatic Control
    Issue number11
    Early online date29 Mar 2017
    Publication statusPublished - 29 Mar 2017


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