Abstract
Based on outlier detection algorithms, a feasible quantification method for supraharmonic emission signals is presented. It is designed to tackle the requirements of high-resolution and low data volume simultaneously in the frequency domain. The proposed method was developed from the skewed distribution data model and the self-tuning parameters of density-based spatial clustering of applications with noise (DBSCAN) algorithm. Specifically, the data distribution of the supraharmonic band was analyzed first by the Jarque–Bera test. The threshold was determined based on the distribution model to filter out noise. Subsequently, the DBSCAN clustering algorithm parameters were adjusted automatically, according to the k-dist curve slope variation and the dichotomy parameter seeking algorithm, followed by the clustering. The supraharmonic emission points were analyzed as outliers. Finally, simulated and experimental data were applied to verify the effectiveness of the proposed method. On the basis of the detection results, a spectrum with the same resolution as the original spectrum was obtained. The amount of data declined by more than three orders of magnitude compared to the original spectrum. The presented method will benefit the analysis of quantification for the amplitude and frequency of supraharmonic emissions.
Highlights
Due to the fact that power electronic devices are widely deployed in the power grid, in addition to the low-frequency harmonic emissions, the phenomenon of supraharmonic emissions in the frequency range 2 kHz–150 kHz has been observed [1,2,3]
The MATLAB version number used in this work was R2016a, and the filter design and analysis tool (FDATool) toolbox was used in the high-pass filter design process
The supraharmonic emissions of the drive model were mainly distributed in the odd-order sideband at the switching frequency and its integer multiples
Summary
Due to the fact that power electronic devices are widely deployed in the power grid, in addition to the low-frequency harmonic emissions, the phenomenon of supraharmonic emissions in the frequency range 2 kHz–150 kHz has been observed [1,2,3]. There is still no unified standard for measurement methods, EMC level, and immunity level in 2–150 kHz [6]. International standards such as the European Standards (EN) 50,160 and the International Electrical Commission (IEC) 61000-4-19 have discussed emissions higher than 2 kHz. The International Special Committee on Radio Interference (CISPR) 16-2-1 discusses an immunity test method for high-frequency harmonics caused by intentional emissions with a range of 9–30 MHz [7]. Method A is based on the method of 2–9 kHz in Appendix B of IEC 61000-4-7 [8], a fixed rectangular window of 200 ms is selected as a sampling interval, and the application range of the 200 Hz bandwidth grouping is extended to 2–150 kHz
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