A linear interpolatory algorithm for robust system identification with corrupted measurement data

Er-Wei Bai; Sundar Raman

doi:10.1109/9.233158

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A linear interpolatory algorithm for robust system identification with corrupted measurement data

Journal article

Peer reviewed

A linear interpolatory algorithm for robust system identification with corrupted measurement data

Er-Wei Bai and Sundar Raman

IEEE transactions on automatic control, Vol.38(8), pp.1236-1241

08/1993

DOI: 10.1109/9.233158

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Abstract

A linear, robustly convergent interpolatory algorithm for system identification in the presence of bounded noise is presented. The algorithm converges in the actual, but unknown, system in the frequency domain in the noise-free case and maintains the robust convergence result in the face of bounded noise. This robustness property distinguishes the algorithm from existing linear schemes. A key idea of this robust linear algorithm is that the approximation is separated into real and imaginary parts and into Fejer (Hermite) interpolation. Because of the Fejer interpolation the data points are required at the Chebyshev points.< >

Control Systems

Automatic control

Chebyshev approximation

Circuit stability

Feedback

Linear systems

Noise robustness

Stability analysis

System identification

Details

Title: Subtitle: A linear interpolatory algorithm for robust system identification with corrupted measurement data
Creators: Er-Wei Bai - University of Iowa
Sundar Raman - University of Iowa
Resource Type: Journal article
Publication Details: IEEE transactions on automatic control, Vol.38(8), pp.1236-1241
Publisher: IEEE
DOI: 10.1109/9.233158
ISSN: 0018-9286
eISSN: 1558-2523
Language: English
Date published: 08/1993
Academic Unit: Electrical and Computer Engineering
Record Identifier: 9984197459302771

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