Principal component analysis for non-linearity detection and linear equivalent transfer function estimation
Principal component analysis for non-linearity detection and linear equivalent transfer function estimation
Summary form only given as follows. In this paper the term system identification addresses the process of obtaining useful information to describe the system characteristics from the relationships between the measured input and output data of a physical system in the most efficient way possible. It can be shown that if the model SISO system under investigation is assumed to be linear time-invariant and stable, in the case of uncorrelated additive measurement noise on both the system input and the output, the use of principal component analysis (PCA) as a transfer function estimator gives results which makes it a useful alternate to the conventional estimators. When the input-output relationship is non-linear, PCA leads to a form of linearization of the system and offers a logical and consistent interpretation. The relative strengths (eigenvalues) of the principal components is a direct indicator of the significance of the non-linearity. The eigenvectors give the features of the equivalent linear system.
iv-4172
Tan, M.H.
0f067bdc-abb1-4814-83ca-14cb1528fa07
Hammond, J.K.
9ee35228-a62c-4113-8394-1b24df97b401
2002
Tan, M.H.
0f067bdc-abb1-4814-83ca-14cb1528fa07
Hammond, J.K.
9ee35228-a62c-4113-8394-1b24df97b401
Tan, M.H. and Hammond, J.K.
(2002)
Principal component analysis for non-linearity detection and linear equivalent transfer function estimation.
In IEEE International Conference on Acoustics, Speech, and Signal Processing, 2002 (ICASSP '02): proceedings.
IEEE.
.
(doi:10.1109/ICASSP.2002.1004879).
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Conference or Workshop Item
(Paper)
Abstract
Summary form only given as follows. In this paper the term system identification addresses the process of obtaining useful information to describe the system characteristics from the relationships between the measured input and output data of a physical system in the most efficient way possible. It can be shown that if the model SISO system under investigation is assumed to be linear time-invariant and stable, in the case of uncorrelated additive measurement noise on both the system input and the output, the use of principal component analysis (PCA) as a transfer function estimator gives results which makes it a useful alternate to the conventional estimators. When the input-output relationship is non-linear, PCA leads to a form of linearization of the system and offers a logical and consistent interpretation. The relative strengths (eigenvalues) of the principal components is a direct indicator of the significance of the non-linearity. The eigenvectors give the features of the equivalent linear system.
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Published date: 2002
Venue - Dates:
IEEE International Conference on Acoustics, Speech, and Signal Processing, 2002 (ICASSP '02), Orlando, USA, 2002-05-13 - 2002-05-17
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Local EPrints ID: 10928
URI: http://eprints.soton.ac.uk/id/eprint/10928
PURE UUID: 8bc4a58f-2a8e-47dc-893b-5a96d40bc643
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Date deposited: 13 Jun 2005
Last modified: 15 Mar 2024 05:01
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Author:
M.H. Tan
Author:
J.K. Hammond
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