Classification of Voltage Sag Using Multi-resolution Analysis and Support Vector Machine

Ismail, Hanim; Zakaria, Zuhaina; Hamzah, Noraliza

doi:10.7763/jocet.2016.v4.276

Cited by 3 publications

(2 citation statements)

References 14 publications

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“…For the first method, feature extraction algorithms include S transform [9], wavelet transform [10], fast Fourier transform [11], and Hilbert-Huang transform (HHT) [12]. Machine learning classification algorithms include clustering algorithm, support vector machine [13], principal component analysis [14], decision tree (DT), etc. Reference [9] proposed a voltage sag classification method based on the similarity of standard templates based on S transform.…”

Section: Introductionmentioning

confidence: 99%

Voltage Sag Causes Recognition with Fusion of Sparse Auto-Encoder and Attention Unet

Fan

Zhang

et al. 2022

Electronics

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High-precision voltage sag cause identification is significant in solving the power quality problem. It is challenging for traditional deep learning models to balance training complexity and recognition performance when processing high-dimensional staging data samples, which affects the final recognition effect. This paper proposes a voltage sag identification method that fuses a sparse auto-encoder and Attention Unet. The model uses a sparse auto-encoder to perform unsupervised feature learning on the high-dimensional voltage sag waveform data and automatically obtains the deep low-dimensional features. Attention Unet, fused with cross-layer spatial and channel attention modules, further extracts these features to obtain recognition results with high performance. Compared with other deep learning recognition methods, the noise-adding experiments and the measured data are verified, indicating that the proposed method has low training complexity, higher recall, and better noise immunity. It benefits auxiliary decision-making for power quality management and governance.

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Section: Introductionmentioning

confidence: 99%

Voltage Sag Causes Recognition with Fusion of Sparse Auto-Encoder and Attention Unet

Fan

Zhang

et al. 2022

Electronics

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“…All these events cause a momentary increase in current that results in sag at point of common coupling (PCC). For detection of causes responsible for generating VS, several signal processing algorithms have been employed in the literature, for example, independent component analysis [10], empirical mode decomposition and Hilbert transform [11], discrete wavelet transform (DWT) [12][13][14], fractionally delayed wavelet transform [15,16], S-transform [17,18], wavelet transform (WT) with spectral and statistical analysis [19] and variational mode decomposition [20]. The domain of signal processing techniques employed for spectral analysis of PQ signals is being ruled by wavelets in one or another form because wavelets can capture all information of signal, for example, trends, breakdown points, discontinuities in higher derivatives and self-similarity [21], which cannot be revealed by other signal processing techniques proposed by other research works.…”

Section: Introductionmentioning

confidence: 99%

Lifting scheme‐based matched wavelet design for effective characterisation of different types of voltage sag

Aggarwal

Saini

2021

IET Science Measure & Tech

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This study presents a novel scheme for designing biorthogonal wavelets matched to the voltage sag (VS) signals. Instead of using standard wavelets, matched wavelets designed in this study can extract more distinguishing features for better characterisation of sag signals, although this study proposes only the designing process of matched wavelets. The key method used for designing matched wavelets is the lifting scheme, which has never been reported in the literature for constructing matched wavelets for PQ signals. Besides using the lifting scheme, the proposed work preprocesses sag signals to make input signal of lifting scheme rich of sag-related information. During pre-processing, 1-D sag signal is first converted to 2-D form for capturing information of every small transition (which may be overlooked in 1-D form) and then made 1-D by ring projection to implement 1-D lifting scheme. In this way, biorthogonal wavelets have been well matched to every type of VS signal collected through the experimental setup simulating different line faults, induction motor starting, transformer energisation and heavy load starting. Also, the characteristics of designed wavelets are evaluated in a MATLAB environment using frequency response and pole-zero mapping in z-plane. Higher PSNR values during signal reconstruction proved outperformance of newly designed matched wavelets.How to cite this article: Aggarwal A, Saini MK. Lifting scheme-based matched wavelet design for effective characterisation of different types of voltage sag.

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Real-time voltage sag detection and classification for power quality diagnostics

et al. 2020

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Classification of Voltage Sag Using Multi-resolution Analysis and Support Vector Machine

Cited by 3 publications

References 14 publications

Voltage Sag Causes Recognition with Fusion of Sparse Auto-Encoder and Attention Unet

Voltage Sag Causes Recognition with Fusion of Sparse Auto-Encoder and Attention Unet

Lifting scheme‐based matched wavelet design for effective characterisation of different types of voltage sag

Real-time voltage sag detection and classification for power quality diagnostics

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