Globally convergent algorithms for robust pole assignment by state feedback

It is observed that an algorithm proposed in 1985 by Kautsky, Nichols, and Van Dooren (KNV) amounts to maximizing, at each iteration, the determinant of the candidate closed-loop eigenvector matrix X with respect to one of its columns (with unit-length constraint), subject to the constraint that it...

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Bibliographic Details
Published inIEEE transactions on automatic control Vol. 41; no. 10; pp. 1432 - 1452
Main Authors Tits, A.L., Yaguang Yang
Format Journal Article
LanguageEnglish
Published IEEE 01.10.1996
Subjects
Arithmetic
Convergence
Cost function
Eigenvalues and eigenfunctions
Poles and zeros
Robustness
State feedback
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Summary:It is observed that an algorithm proposed in 1985 by Kautsky, Nichols, and Van Dooren (KNV) amounts to maximizing, at each iteration, the determinant of the candidate closed-loop eigenvector matrix X with respect to one of its columns (with unit-length constraint), subject to the constraint that it remains an achievable closed-loop eigenvector matrix. This interpretation is used to prove convergence of the KNV algorithm. It is then shown that a more efficient algorithm is obtained if det (X) is concurrently maximized with respect to two columns of X, and such a scheme is easily extended to the case where the eigenvalues to be assigned include complex conjugate pairs. Variations exploiting the availability of multiple processors are suggested. Convergence properties of the proposed algorithms are established. Their superiority is demonstrated numerically.
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ISSN:0018-9286
DOI:10.1109/9.539425