A Classification Method for Power-Quality Disturbances Using Hilbert–Huang Transform and LSTM Recurrent Neural Networks

IEEE recommended practice for monitoring electric power quality (2009) IEEE Std 1159-2009 (Revision of IEEE Std 1159-1995) c1–81. https://doi.org/10.1109/IEEESTD.2009.5154067

Shukla S, Mishra S, Singh B (2014) Power quality event classification under noisy conditions using EMD-based de-noising techniques. IEEE Trans Ind Inform 10(2):1044–1054. https://doi.org/10.1109/TII.2013.2289392

Uyar M, Yildirim S, Gencoglu MT (2009) An expert system based on s-transform and neural network for automatic classification of power quality disturbances. Expert Syst Appl 36(3):5962–5975

Gaing Z-L (2004) Wavelet-based neural network for power disturbance recognition and classification. IEEE Trans Power Deliv 19(4):1560–1568

He H, Starzyk JA (2005) A self-organizing learning array system for power quality classification based on wavelet transform. IEEE Trans Power Deliv 21(1):286–295

Mishra S, Bhende C, Panigrahi B (2007) Detection and classification of power quality disturbances using s-transform and probabilistic neural network. IEEE Trans Power Deliv 23(1):280–287

Brown RA, Frayne R (2008) A fast discrete s-transform for biomedical signal processing. In: 30th annual international conference of the IEEE engineering in medicine and biology society. IEEE 2008, pp 2586–2589

Biswal M, Dash PK (2013) Detection and characterization of multiple power quality disturbances with a fast s-transform and decision tree based classifier. Digit Signal Process 23(4):1071–1083

Babu PR, Dash P, Swain S, Sivanagaraju S (2014) A new fast discrete s-transform and decision tree for the classification and monitoring of power quality disturbance waveforms. Int Trans Electr Energy Syst 24(9):1279–1300

Achlerkar PD, Samantaray SR, Manikandan MS (2016) Variational mode decomposition and decision tree based detection and classification of power quality disturbances in grid-connected distributed generation system. IEEE Trans Smart Grid 9(4):3122–3132

Sahani M, Dash P (2018) Variational mode decomposition and weighted online sequential extreme learning machine for power quality event patterns recognition. Neurocomputing 310:10–27

Mandic DP, Rehman Nu, Wu Z, Huang NE (2013) Empirical mode decomposition-based time-frequency analysis of multivariate signals: the power of adaptive data analysis. IEEE Signal Process Mag 30(6):74–86

Rodriguez MA, Sotomonte JF, Cifuentes J, Bueno-López M (2019) Classification of power quality disturbances using Hilbert–Huang transform and a multilayer perceptron neural network model. In: 2019 international conference on smart energy systems and technologies (SEST). IEEE, pp. 1–6

Lin C-H, Tsao M-C (2005) Power quality detection with classification enhancible wavelet-probabilistic network in a power system. IEE Proc Gener Transm Distrib 152(6):969–976

Yue X, Boroyevich D, Lee FC, Chen F, Burgos R, Zhuo F (2018) Beat frequency oscillation analysis for power electronic converters in DC nanogrid based on crossed frequency output impedance matrix model. IEEE Trans Power Electron 33(4):3052–3064

Mozaffari K, Amirabadi M (2019) A highly reliable and efficient class of single-stage high-frequency ac-link converters. IEEE Trans Power Electron 34(9):8435–8452

Jayasree T, Devaraj D, Sukanesh R (2009) Power quality disturbance classification using s-transform and radial basis network. Appl Artif Intell 23(7):680–693

Chakravorti T, Dash PK (2017) Multiclass power quality events classification using variational mode decomposition with fast reduced kernel extreme learning machine-based feature selection. IET Sci Meas Technol 12(1):106–117

Janik P, Lobos T (2006) Automated classification of power-quality disturbances using SVM and RBF networks. IEEE Trans Power Deliv 21(3):1663–1669

Zhang Q-M, Liu H-J (2008) Application of LS-SVM in classification of power quality disturbances. Proc Chin Soc Electr Eng 28(1):106

Li J, Teng Z, Tang Q, Song J (2016) Detection and classification of power quality disturbances using double resolution S-transform and DAG-SVMs. IEEE Trans Instrum Meas 65(10):2302–2312

Liu Z, Cui Y, Li W (2015) A classification method for complex power quality disturbances using EEMD and rank wavelet SVM. IEEE Trans Smart Grid 6(4):1678–1685

Meher SK, Pradhan AK (2010) Fuzzy classifiers for power quality events analysis. Electric power systems Research 80(1):71–76

Samantaray S (2010) Decision tree-initialised fuzzy rule-based approach for power quality events classification. IET Gener Transm Distrib 4(4):538–551

Saikia L, Borah S, Pait S (2010) Detection, and classification of power quality disturbances using wavelet transform, fuzzy logic, and neural network. In: Annual IEEE India conference (INDICON). IEEE 2010, pp 1–5

Kanirajan P, Kumar VS (2015) Wavelet-based power quality disturbances detection and classification using RBFNN and fuzzy logic. Int J Fuzzy Syst 17(4):623–634

Cai K, Cao W, Aarniovuori L, Pang H, Lin Y, Li G (2019) Classification of power quality disturbances using Wigner-Ville distribution and deep convolutional neural networks. IEEE Access 7:119099–119109

Liao H, Milanović JV, Rodrigues M, Shenfield A (2018) Voltage sag estimation in sparsely monitored power systems based on deep learning and system area mapping. IEEE Trans Power Deliv 33(6):3162–3172

Li C, Li Z, Jia N, Qi Z, Wu J (2018) Classification of power-quality disturbances using deep belief network. In: 2018 international conference on wavelet analysis and pattern recognition (ICWAPR). IEEE, pp 231–237

Temurtas F, Gunturkun R, Yumusak N, Temurtas H (2004) Harmonic detection using feed forward and recurrent neural networks for active filters. Electr Power Syst Res 72(1):33–40

Mohan N, Soman K, Vinayakumar R (2017) Deep power: deep learning architectures for power quality disturbances classification. In: 2017 international conference on technological advancements in power and energy (TAP Energy). IEEE, pp 1–6

Huang NE, Shen Z, Long SR, Wu MC, Shih HH, Zheng Q, Yen N-C, Tung CC, Liu HH (1998) The empirical mode decomposition and the Hilbert spectrum for nonlinear and non-stationary time series analysis. Proc R Soc Lond A Math Phys Eng Sci 454(1971):903–995. https://doi.org/10.1098/rspa.1998.0193

Alshahrani S, Abbod M, Taylor G (2016) Detection and classification of power quality disturbances based on Hilbert–Huang transform and feed forward neural networks. In: 2016 51st international universities power engineering conference (UPEC), pp. 1–6. https://doi.org/10.1109/UPEC.2016.8114075

Wu Z, Huang NE (2009) Ensemble empirical mode decomposition: a noise-assisted data analysis method. Adv Adapt Data Anal 1(01):1–41

Gasca-Segura MV, Bueno-López M, Molinas M, Fosso OB (2018) Time-frequency analysis for nonlinear and non-stationary signals using HHT: a mode mixing separation technique. IEEE Latin Am Trans 16(4):1091–1098. https://doi.org/10.1109/TLA.2018.8362142

Rilling G, Flandrin P (2007) One or two frequencies? The empirical mode decomposition answers. IEEE Trans Signal Process 56(1):85–95. https://doi.org/10.1109/TSP.2007.906771

Guridi Mateos G et al (2017) Modelos de redes neuronales recurrentes en clasificación de patentes, B.S. thesis

Cifuentes J, Boulanger P, Pham MT, Prieto F, Moreau R (2019) Gesture classification using lstm recurrent neural networks. In: 41st annual international conference of the IEEE engineering in medicine and biology society (EMBC), vol 2019. IEEE, pp 6864–6867. https://doi.org/10.1109/EMBC.2019.8857592

Fosso OB, Molinas M (2018) EMD mode mixing separation of signals with close spectral proximity in smart grids. In: 2018 IEEE PES innovative smart grid technologies conference Europe (ISGT-Europe), pp 1–6. https://doi.org/10.1109/ISGTEurope.2018.8571816