Research on tacholess fast-varying instantaneous rotating frequency estimation model based on nonlinear short-time Fourier transform combination with adaptive chirp mode decomposition and its application

Instantaneous rotating frequency extraction is one of the key technologies for mechanical health monitoring and fault diagnosis. As the instantaneous rotating frequency presents fast-varying property under high-speed fluctuation, this paper uses a coarse-to-fine strategy to propose a tacholess fast-...

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Bibliographic Details
Published inJournal of low frequency noise, vibration, and active control Vol. 44; no. 3; pp. 1311 - 1322
Main Authors Yan, Lu, Lan, Tian Zhong, Yang, Shi Li, Chen, Qin Xiao, Bie, Jin Wei
Format Journal Article
LanguageEnglish
Published London, England SAGE Publications 01.09.2025
Sage Publications Ltd
SAGE Publishing
Subjects
Chirp
Decomposition
Energy distribution
Fault diagnosis
Fourier transforms
Frequency distribution
Roller bearings
Rotation
Time-frequency analysis
Vibration
instantaneous rotating frequency estimation
Nonlinear short-time Fourier transform
fault diagnosis
order component extraction
adaptive chirp mode decomposition
high-speed fluctuation
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Summary:Instantaneous rotating frequency extraction is one of the key technologies for mechanical health monitoring and fault diagnosis. As the instantaneous rotating frequency presents fast-varying property under high-speed fluctuation, this paper uses a coarse-to-fine strategy to propose a tacholess fast-varying instantaneous rotating frequency estimation model based on nonlinear short-time Fourier transform (NLSTFT) combination with adaptive chirp mode decomposition (ACMD). By self-adaptive matching and decomposing the vibration signal based on its time-frequency distribution, it increases the energy aggregation of time-frequency representation, which not only improves computational efficiency but also avoids the spectral ambiguity problem. As a result, the proposed model is very suitable for extracting instantaneous rotating frequency under severe speed fluctuation; simulation signal and rolling bearing fault vibration signal also validate this conclusion. Furthermore, by integrating with signal decomposition technology, various order components of fault vibration signal can also be self-adaptive extracted.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
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content type line 14
ISSN:1461-3484
2048-4046
DOI:10.1177/14613484251320211