On‐line identification model for single phase‐earth fault in distribution network driven by wavelet transform and multi‐learner combination
Xueneng Su, Hua Zhang, Yiwen Gao, Jian Zhang, Tunfang Song
Abstract
Abstract The detection of single phase‐earth faults has been a difficult task for a long time due to its very low current in high impedance grounded fault especially in a neutral un‐effectively grounded system. To address this issue, this paper firstly proposes multi‐learner based single phase‐earth fault identification models. First, to erase disturb noise in fault recording profiles, a denoising model is put forward based on the wavelet transform optimized via the proposed threshold improvement approach. Second, feature engineering reflecting local and/or global evolutionary process of fault evolving features is modelled, and in turn two key feature transforming techniques of principal component analysis (PCA) and random forest (RF) are individually employed to recognize the best effective combination of fault feature set. Subsequently, six learners of logistical regression (LR), support vector machine (SVM), K‐neighbor (KN), RF, XGBoost and LightGBM based fault identification models are individually custom‐designed which the feature subset in high priority are fed into. Furthermore, to guide the model optimization, several advanced manners of hyper‐parametric sampling via normal and Chi‐2 distribution, learning curve, validation curve, receiver operation characteristic curve (ROC) are applied. Numerical studies indicates the the high value of the proposed model when applied in engineering practice.