Quasi-Periodic Harmonic Feature Extraction of Power Signals via Improved Scaling-Basis Chirplet Transform.
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| Title: | Quasi-Periodic Harmonic Feature Extraction of Power Signals via Improved Scaling-Basis Chirplet Transform. |
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| Authors: | Hu, Yihao1 (AUTHOR), Yu, Jiexiao1 (AUTHOR) |
| Source: | Energies (19961073). May2026, Vol. 19 Issue 9, p2122. 28p. |
| Subject Terms: | *Time-frequency analysis, *Signal reconstruction, *Automatic tracking |
| Abstract: | The increasing randomness of source–load fluctuations and the rapid proliferation of power-electronic devices have introduced wide dynamic ranges, fast time-varying behaviors, and strong stochastic characteristics into power signals, leading to severe measurement deviations in existing metering equipment. Conventional modeling and feature analysis methods based on fixed-frequency steady-state assumptions are inadequate for characterizing such non-stationary behaviors, making the underlying causes of metering deviations difficult to identify. To address this issue, we propose a modeling and dynamic time–frequency feature extraction method for complex non-stationary power signals. First, the operating characteristics of power equipment are analyzed to identify the fundamental non-stationary features of power signals, based on which a quasi-periodic harmonic signal model is established. Then, the scaling-basis chirplet transform is employed to intuitively represent the time–frequency structure, while a ridge detection algorithm is incorporated to quantitatively characterize the time–frequency trajectories and instantaneous amplitude features. Finally, to cope with the limited availability of power signal measurements, a non-stationary component reconstruction method based on cross-correntropy is developed. Experimental results from multiple datasets, including field-measured signals, demonstrate that the proposed method enables effective dynamic monitoring and reconstruction of non-stationary components, offering significant advantages in both time–frequency analysis capabilities and reconstruction accuracy. [ABSTRACT FROM AUTHOR] |
| Database: | Energy & Power Source |
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| Abstract: | The increasing randomness of source–load fluctuations and the rapid proliferation of power-electronic devices have introduced wide dynamic ranges, fast time-varying behaviors, and strong stochastic characteristics into power signals, leading to severe measurement deviations in existing metering equipment. Conventional modeling and feature analysis methods based on fixed-frequency steady-state assumptions are inadequate for characterizing such non-stationary behaviors, making the underlying causes of metering deviations difficult to identify. To address this issue, we propose a modeling and dynamic time–frequency feature extraction method for complex non-stationary power signals. First, the operating characteristics of power equipment are analyzed to identify the fundamental non-stationary features of power signals, based on which a quasi-periodic harmonic signal model is established. Then, the scaling-basis chirplet transform is employed to intuitively represent the time–frequency structure, while a ridge detection algorithm is incorporated to quantitatively characterize the time–frequency trajectories and instantaneous amplitude features. Finally, to cope with the limited availability of power signal measurements, a non-stationary component reconstruction method based on cross-correntropy is developed. Experimental results from multiple datasets, including field-measured signals, demonstrate that the proposed method enables effective dynamic monitoring and reconstruction of non-stationary components, offering significant advantages in both time–frequency analysis capabilities and reconstruction accuracy. [ABSTRACT FROM AUTHOR] |
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| ISSN: | 19961073 |
| DOI: | 10.3390/en19092122 |