Operational modal analysis of under-determined system based on Bayesian CP decomposition

Operational modal analysis of under-determined system based on Bayesian CP decomposition

Modal properties such as natural frequencies, modal shapes and damping ratio are useful to understand structural dynamics of mechanical systems. To use the modal properties for structural health monitoring, they need to be estimated under operational conditions. Therefore, operational modal analysis...

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Bibliographic Details
Published in:Kikai Gakkai ronbunshū = Transactions of the Japan Society of Mechanical Engineers Vol. 87; no. 899; p. 21-00134
Main Authors: TOMITA, Sunao, JIMBO, Tomohiko
Format: Journal Article
Language:English
Japanese
Published: The Japan Society of Mechanical Engineers 2021
Subjects:
Bayesian inference
Blind source separation
CANDECOMP/PARAFAC decomposition
Modal properties extraction
Operational modal analysis
Second-order blind identification
Tensor decomposition
Under-determined problem
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Summary:Modal properties such as natural frequencies, modal shapes and damping ratio are useful to understand structural dynamics of mechanical systems. To use the modal properties for structural health monitoring, they need to be estimated under operational conditions. Therefore, operational modal analysis (OMA), extraction of the modal properties without input signals, has been proposed to easily extract the modal properties under operational conditions. Recently, OMA for underdetermined systems, i.e. number of measurements is less than that of active modes, has been paid attention to reduce the number of sensors. This paper proposes the OMA framework for the underdetermined systems based on Bayesian tensor decomposition of second-order statistics data. The proposed method enables us to extract the modal properties from underdetermined systems without tuning the number of active modes because rank of the tensor data corresponding to the number of the active modes is automatically determined via Bayesian inference. To show advantage of the method, the modal properties are extracted from artificial vibration data obtained from a mass-spring system under the operational and the underdetermined conditions.
ISSN:2187-9761
2187-9761
DOI:10.1299/transjsme.21-00134