Your search keyword '"fault classification"' showing total 27 results

1. Relay algorithm for STATCOM compensated line using differential current ratio.

Author

Gangolu, Suryanarayana, Sarangi, Saumendra, and Mohanty, Rabindra

Subjects

*CURRENT transformers (Instrument transformer), *FAULT location (Engineering), *ELECTRIC lines, *ELECTRIC relays, *SYNCHRONOUS capacitors, *FREQUENCY-domain analysis, *ELECTRIC power distribution grids

Abstract

• Detecting the high resistance internal fault and identifying the correct faulted phase in shunt-compensated lines using phase currents only. • No symmetrical component and frequency-domain analysis are required which reduces the computational burden. • Validation of the proposed algorithm with filed data obtained from a 400 kV line. • Independent of compensation level, fault location, line length and its parameters. The proposed method performs correctly for time synchronization errors, variation in fault location, CT saturation, source impedance variations, different line lengths and power swing, etc. Static synchronous compensators (STATCOMs) are used in the power transmission line to improve the voltage profile and stability. For a fault on the line, additional uneven reactive current from the compensator causes the maloperation of local data-based relaying schemes. In this work, using the current of both ends of the line, internal faults and faulty phases are identified by the ratio of both end's current difference to the local one. Both the magnitude and angle of the ratio are utilized to enhance the dependability and security of the relay operation. The performance of the proposed technique is validated in Western System Coordinating Council (WSCC), a 9-bus system using data obtained from PSCAD. The authenticity of the proposed method is further validated using field data collected from a 400 kV shunt compensated line in the Indian power grid. The suggested strategy is resilient to changes in fault resistance, source impedance, fault location, current transformer saturation, various compensation levels, and high resistance faults (HRF). A comparison of the proposed Algorithm with existing methodologies demonstrates its superiority. [ABSTRACT FROM AUTHOR]

Published

2024

2. Gas turbine failure classification using acoustic emissions with wavelet analysis and deep learning.

Author

Nashed, M.S., Renno, J., Mohamed, M.S., and Reuben, R.L.

Subjects

*ACOUSTIC emission, *GAS turbines, *CONVOLUTIONAL neural networks, *WAVELETS (Mathematics), *DEEP learning

Abstract

• Novel method for the condition monitoring of gas turbines using acoustic emissions. • Wavelet analysis used to transform acoustic emission signals into images. • Deep convolutional neural networks used to classify turbine condition. • Network trained on experimental data with two healthy and two faulty conditions. Compared to vibration monitoring, acoustic emission (AE) monitoring in gas turbines is highly sensitive to changes that do not involve whole-body motion, such as wear, rubbing, and fluid-induced faults. AE signals captured by suitably mounted sensors can potentially provide early indications of abnormal turbine operation before such abnormalities manifest in structural vibration or emitted airborne noise. However, developing an online fault detection system requires extensive real-time data treatment to extract appropriate features and indicators from raw AE records. To build such a system for industrial turbines, researchers need to understand the AE-generating mechanisms associated with turbine operation and the sources of background noise. In this study, we aim to develop such an understanding using a small-scale turbine whose operational conditions can be modified safely to reflect both normal and faulty conditions. Our signal processing approach involves first extracting a time-series envelope using an averaging time selected to enhance major features and eliminate irrelevant noise. We then generate time–frequency features using a continuous wavelet transform, which are used to train a deep convolutional neural network to classify gas turbine conditions. The resulting model demonstrates high accuracy in classifying two normal running conditions and two faulty conditions at various turbine speeds. Overall, the proposed methodology offers a powerful tool for gas turbine condition monitoring, and we make all associated data available in open-source format to facilitate further research in this field.4 [ABSTRACT FROM AUTHOR]

Published

2023

3. Highly imbalanced fault classification of wind turbines using data resampling and hybrid ensemble method approach.

Author

Chatterjee, Subhajit and Byun, Yung-Cheol

Subjects

*WIND turbines, *DEEP learning, *RESAMPLING (Statistics), *GENERATIVE adversarial networks, *FAULT diagnosis, *MACHINE learning, *DATA distribution

Abstract

Deep learning-based incipient fault diagnostic techniques have achieved surprisingly well in wind turbines. Due to component failures, wind turbines must undergo active maintenance, substantially influencing revenue and power generation. Unfortunately, there are consistently uneven data distributions between samples with faults and those without faults, resulting in incorrect fault classification. Wind turbine fault classification has a significant data imbalance problem, compromising learning attention for majority and minority classes. Machine learning methodologies based on Generative Adversarial Networks (GAN), over-sampling, and under-sampling techniques for generating synthetic data have been widely employed to address the imbalance data problem. However, the traditional synthetic minority oversampling technique (SMOTE) accomplishes oversampling using linear interpolation between close minority class samples, which could be confusing, subpar, and indistinguishable from the majority class. This study suggests combining over and under-sampling using adaptive SMOTE and edited nearest neighbors (ASMOTE-ENN) that incorporate over-sampling with adaptive SMOTE and under-sampling with ENN to improve the quality of the generated samples. With this resampling technique, noise in an imbalanced dataset is reduced on three levels by using an adaptive nearest neighbor selection algorithm to find the nearest neighbors that are visible. Then use SMOTE to create samples that precisely fall into the minority class, and later use the ENN technique to eliminate instances that contribute to noise afterwards. Resampling data created by combining over- and under-sampling approaches to match the data distribution over all classes is the foundation of the suggested method's efficacy. A hybrid ensemble method is used for effective classification, including boosting, bagging, and stacking techniques. The original unbalanced and balanced data using the ASMOTE-ENN algorithm were classified using the proposed hybrid ensemble method. The classification results show that the proposed strategy is more accurate than a few imbalanced fault diagnosis techniques. • To gain complete knowledge, characteristics of SCADA data are obtained using data analysis. • We present the adaptive SMOTE-ENN algorithm-based data resampling technique to deal with imbalanced data. • Create a hybrid ensemble classification technique to identify faulty and no-fault events effectively. • The results demonstrate that the suggested method outperforms the most popular ML techniques. [ABSTRACT FROM AUTHOR]

Published

2023

4. Faulty phase identification and ground detection in TCSC compensated lines integrated with wind farms.

Author

Mohanty, Subodh Kumar, Santra, Subhendu Bikash, and Siano, Pierluigi

Subjects

*WIND power plants, *OFFSHORE wind power plants, *ELECTRIC lines, *PROTECTIVE relays, *RANDOM forest algorithms, *ELECTRIC transients, *WIND speed, *GYROTRONS

Abstract

• Protection issues of TCSC compensated line integrated with DFIG based Wind Farm. • A novel protection algorithm is proposed to detect the faulty phase in a TCSC compensated line connected with DFIG based Wind Farm. • This proposed method is also validated in a real time platform using dSPACE DS-1104 based prototype processor. • Use of the ITD based technique for detecting faulty phase in TCSC compensated line connected to DFIG based wind farm. • This ITD based algorithm is sensitive for close in fault and high resistance fault in TCSC line with wind farm. Nowadays there is a trend for offshore wind farms to be connected with power grids through a TCSC series controlled compensating device employed in transmission lines for the improvement of large power flows. In such transmission lines, faulty phase identification and ground detection create a challenge for conventional distance relaying schemes because of non-linear output power fluctuation due to variations in wind speed and different firing angle operations of TCSC. Therefore, to overcome the problem of such transmission lines relaying, a novel time-frequency analysis-based intrinsic time scale decomposition (ITD) method is proposed in this paper. The proposed intrinsic time scale decomposition method uses only a three-phase grid side current from relaying end for faulty phase and ground detection and ITD supported random forest classifier for fault classification accuracy approach. The evaluation of the proposed scheme is tested on several fault cases with varying system parameters and non-fault transient events through the EMTDC/PSCAD platform during different wind speeds and varying firing angle operations of TCSC. The performance of the proposed scheme is also verified through a real-time interface dSPACE DS 1104 control prototype hardware. Finally, a comparison analysis with existing techniques demonstrated the effectiveness of the presented method to assess the mentioned problem of the conventional protective relaying schemes. The proposed method demonstrated a 100% accuracy for faulty phase selection and a 99.99% accuracy for fault classification. [ABSTRACT FROM AUTHOR]

Published

2023

5. Gaussian Discriminative Analysis aided GAN for imbalanced big data augmentation and fault classification.

Author

Zhuo, Yue and Ge, Zhiqiang

Subjects

*DISCRIMINANT analysis, *ELECTRONIC data processing, *INFORMATION commons, *MANUFACTURING processes, *CLASSIFICATION, *BIG data

Abstract

With data in industrial processes being larger in scale and easier to access, data-driven technologies have become more prevalent in process monitoring. Fault classification is an indispensable part of process monitoring, while machine learning is an effective tool for fault classification. In most practical cases, however, the number of fault data is far smaller than normal data, and this imbalance of dataset would lead to the significant decline in performance of common classifier learning algorithms. To this issue, we propose a data augmentation method, which is based on Generative Adversarial Networks(GAN) and aided by Gaussian Discriminant Analysis(GDA), for enhancement of fault classification accuracy. To validate the effectiveness of this method for imbalanced fault classification, on toy data and the Tennessee Eastman (TE) benchmark process, common oversampling method and the basic GAN are compared to our method, with different classification algorithms. Besides, proposed method is deployed and parallelly trained on Tensorflow platform, which is suitable for applications like data augmentation and imbalanced fault classification in industrial big data environments. • A data augmentation method for imbalanced fault classification. • Generative Adversarial Networks aided by Gaussian Discriminant Analysis. • Superiorities of the model are analyzed and discussed in detail. • Parallel implementation of the model for big data in Tensorflow. • The performance of the method is verified on both toy data and TE process. [ABSTRACT FROM AUTHOR]

Published

2020

6. Deep learning for fault-relevant feature extraction and fault classification with stacked supervised auto-encoder.

Author

Wang, Yalin, Yang, Haibing, Yuan, Xiaofeng, Shardt, Yuri A.W., Yang, Chunhua, and Gui, Weihua

Subjects

*DEEP learning, *FEATURE extraction, *MANUFACTURING processes, *CLASSIFICATION

Abstract

Stacked auto-encoder (SAE)-based deep learning has been introduced for fault classification in recent years, which has the potential to extract deep abstract features from the raw input data. However, SAE cannot ensure the relevance of deep features with the fault types due to its unsupervised self-reconstruction in the pretraining stage. To overcome this problem, a stacked supervised auto-encoder is proposed to pretrain the deep network and obtain deep fault-relevant features from raw input data. In each supervised auto-encoder, informative features are learned from the input data with the goal that they can largely distinguish different fault types. By stacking multiple supervised auto-encoders hierarchically, high-level fault-relevant features are gradually learned from raw input data, which can improve the classification accuracy of the classifiers. The proposed SSAE is tested on the Tennessee–Eastman (TE) benchmark process and a real industrial hydrocracking process. The results show the effectiveness and flexibility of SSAE. • A stacked supervised auto-encoder is proposed to pretrain deep network and obtain deep fault-relevant features. • In each supervised auto-encoder, informative features are learned from the input data with the goal that they can largely distinguish different fault types. • High-level fault-relevant features are gradually learned from raw input data by hierarchically stacking multiple supervised auto-encoders. • High classification performance of the proposed method is validated on TE process and an industrial hydrocracking process. [ABSTRACT FROM AUTHOR]

Published

2020

7. K-means Bayes algorithm for imbalanced fault classification and big data application.

Author

Chen, Gecheng, Liu, Yue, and Ge, Zhiqiang

Subjects

*BIG data, *K-means clustering, *MANUFACTURING processes, *CLASSIFICATION

Abstract

• K-means Bayes algorithm is newly proposed for imbalanced fault classification. • The proposed method neither adds samples nor reduces samples, ensuring the quality of the training data. • A MapReduce form of the proposed algorithm is further developed for big data application. • The superiority of the developed method is tested on a benchmark process. Fault classification is an important part of process monitoring in industrial processes. Most conventional fault classification methods are under the assumption that the amount of data in different classes are similar. However, in practice, most of the data collected from industrial process are normal data (majority) and only a few of them are fault data (minority). In other words, fault classification can be seen as an imbalanced data classification problem, which has not been considered in this area to date. In this paper, a K-means Bayes algorithm is proposed to deal with the imbalanced fault classification problem. After that, a MapReduce approach is further introduced to implement the method for fault classification in the big data case. Effectiveness of the proposed method is verified through experiments based on Tennessee Eastman (TE) benchmark process. [ABSTRACT FROM AUTHOR]

Published

2019

8. Generalizability of machine learning-based fault classification for residential air-conditioners.

Author

Chen, Yuxuan, Ebrahimifakhar, Amir, Hu, Yifeng, and Yuill, David P.

Subjects

*SUPPORT vector machines, *FAULT diagnosis, *MACHINE theory, *LIFE expectancy, *CLASSIFICATION, *MACHINE learning

Abstract

Residential air-conditioning systems are subject to soft faults, which can reduce their efficiency, capacity, and life expectancy, without being detected by the occupants. Early detection and diagnosis of faults could potentially be done by using machine learning (ML) on measurable features of the air-conditioner, such as refrigerant temperatures and pressures. This paper describes a novel approach to applying ML, which is to train a fault classifier using data from one system, and apply it to different systems. If this is effective, it can significantly reduce the cost of widescale application of ML fault classification. The support vector machine (SVM) algorithm was used. An additional question for practical application is whether the number of sensors required for input feature measurement can be reduced. This work also tests the feature reduction effect, in combination with applying an ML classifier trained on one system, to classify faults in two other systems. The results are disappointing, showing that fault classification is poor when the SVM classifier is trained on a different system than it is applied to. However, with additional work, this method has potential for improvement, possibly to a point where it can be a viable approach for field deployment. [ABSTRACT FROM AUTHOR]

Published

2023

9. Incorporate active learning to semi-supervised industrial fault classification.

Author

Yin, Lili, Wang, Huangang, Fan, Wenhui, Kou, Li, Lin, Tingyu, and Xiao, Yingying

Abstract

• A new method incorporating active learning to semi-supervised industrial fault classification is proposed to solve the lack of labeled training data. • The limited capacity of semi-supervised FDA can be effectively improved by introducing the active learning, and the semi-supervised FDA can utilize the information of unlabeled data to help active learning reduce the amount of labeled data. • At each iteration, the data having the greatest entropy will be labeled manually to update current model. • The iteration of active learning will stop when current model is confident of all unlabeled data. • Compared with semi-supervised FDA, ALSemiFDA can get better discriminant projection vectors and can handle more situations. Compared with active learning based FDA, ALSemiFDA needs less manually labeled data. The performance of Fisher discriminant analysis (FDA) method is highly depended on the labeled data. While obtaining the true labels of the industrial data is often time-consuming and expensive in practice. Although there are some researches on semi-supervised methods based on the FDA to solve this problem, they will fail when the labeled data are not satisfied with some special conditions. To improve the methods' applicability, this paper proposes an active learning based semi-supervised FDA model for industrial fault classification. This method bridges labeling important unlabeled data of active learning and learning from unlabeled data of semi-supervised learning. The performance has been greatly improved with the information from the new labeled data, and the amount of new labeled data has been reduced by additional unlabeled data. The experimental analysis on the two dimensional data sets indicates that active learning and semi-supervised learning are complementary for each other. Finally, the experiments carried out on the UCI benchmarks and Tennessee Eastman process (TEP) prove the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2019

10. An accurate classifier based on adaptive neuro-fuzzy and features selection techniques for fault classification in analog circuits.

Author

Arabi, Abderrazak, Bourouba, Nacerdine, Belaout, Abdesslam, and Ayad, Mouloud

Subjects

*INTEGRATED circuits, *DEBUGGING, *FEATURE selection, *ANALOG circuits, *ARTIFICIAL neural networks

Abstract

Abstract This paper presents a new approach for faults classification in analog integrated circuits using a multiclass adaptive neuro fuzzy inference system classifier. This is carried out to assist analog circuit's faults diagnosis suffering from inaccurate faults classification on one hand, and to lessen computational burden on the other hand. This has been achieved from features number reduction. These features serving as input feature vector are extracted from the selected circuits (CUT) frequency and transient responses under both fault free and faulty conditions. The considered faults are resistors and capacitors values variations of about 50% low and high from their nominal ones. The method accuracy has been validated with three experiment circuits, the Sallen Key band-pass, the four opamp biquad high-pass and the leapfrog filters. The obtained results reveal a high level of efficiency with an accuracy average reach to 99.76%. Hence, the proposed method has shown a good performance in term of fault classification accuracy when compared with those of both the Artificial Neural Networks (ANN) approach and the fractional Fourier transform (FRFT) method based on a statistical property. Highlights • A neuro-fuzzy classifier for faults classification in analog circuits is proposed. • Monte-Carlo simulation is used for features extraction. • Features selection technique is used to reduce the computational burden. • Classifiers fusion and winner takes all rule for multiclass fault discrimination. [ABSTRACT FROM AUTHOR]

Published

2019

11. An intelligent fault detection and classification scheme for distribution lines integrated with distributed generators.

Author

Chaitanya, B.K. and Yadav, Anamika

Subjects

*DEBUGGING, *DISTRIBUTED computing, *MAGNITUDE estimation, *ELECTRIC impedance, *ELECTRIC currents

Abstract

Conventional relays fail to detect the high impedance fault (HIF) in distribution lines, as the change in the current magnitude is very negligible compared to conventional relay settings. Moreover, the incorporation of distributed generators in the distribution lines changes the fault current level, which makes the HIF-detection more complex. In this paper, a fuzzy-based intelligent fault detection and classification scheme is developed for the distribution lines integrated with DGs. Two different fuzzy inference systems (FIS) are modelled in each phase to detect the fault. The first FIS identifies the high magnitude of fault current associated with normal shunt faults; and the second FIS identifies the small magnitude of current owing to occurrence of HIF. The proposed scheme uses the features extracted from the Teager energy operator. An extensive study is conducted and the response time is found to be around ¼-1 cycle. Results validate the efficacy of the proposed scheme. [ABSTRACT FROM AUTHOR]

Published

2018

12. Weighted random forests for fault classification in industrial processes with hierarchical clustering model selection.

Author

Liu, Yue and Ge, Zhiqiang

Subjects

*HIERARCHICAL clustering (Cluster analysis), *MANUFACTURING processes, *SIMULATION methods & models, *RANDOM forest algorithms, *AUTOMATIC control systems

Abstract

In this paper, a hierarchical clustering selection based weighted random forests scheme is proposed for fault classification in complex industrial processes. Model diversity and the strength of each model are deemed to be two key issues for the performance of ensemble learning method. To improve the diversity between classification trees and the performance of individual classification trees in random forests, the hierarchical clustering method is applied for offline model selection in random forests, which can simultaneously reduce the online fault classification complexity. Meanwhile, the weighted voting rule is used in random forests instead of majority voting, in order to boost the good performance models and weaken the bad ones. Detailed comparative studies between proposed method and conventional methods have been carried out through the Tennessee Eastman (TE) benchmark process. [ABSTRACT FROM AUTHOR]

Published

2018

13. Fault identification for photovoltaic systems using a multi-output deep learning approach.

Author

Mustafa, Zain, Awad, Ahmed S.A., Azzouz, Maher, and Azab, Ahmed

Subjects

*PHOTOVOLTAIC power systems, *SYSTEM failures, *DEEP learning, *SYSTEM identification, *CONVOLUTIONAL neural networks, *MACHINE learning

Abstract

• Fault classification and localization are carried out in a photovoltaic system. • A multi-output scalable machine- and deep-learning approach is developed. • A 50% reduction in the number of sensors needed per string is achieved. • Deep Learning models are more resilient to noise and are more accurate. • Accuracy up to 99.98% and cross-entropy loss as low as 0.002 are attained. Fault classification and localization are imperative to maintaining an efficient photovoltaic (PV) system. Due to the environmental factors that PV systems function in, they can be prone to multiple types of fault conditions such as string-to-string (SS), string-to-ground (SG), and open-circuit faults (OC). If left undetected, these faults can lead to power loss and eventually system failures. To help mitigate such outcomes, this paper presents an approach to detect, classify, and locate SS, SG, and OC faults using multi-output deep learning (DL) algorithms: convolutional neural networks (CNN), long short-term memory (LSTM), and bi-directional long short-term memory (Bi-LSTM) networks. The proposed approach reduces the number of sensors needed per string by 50% compared to the previous approaches in the literature. It also allows for increased scalability and the development of a multi-label dataset through an uncoupled modeling scheme. Fault classification and location are achieved with accuracies of 99.94% and 99.54%, respectively. Further, a comparison is conducted among the proposed DL and conventional machine learning algorithms using multiple evaluation metrics. The proposed method is validated by testing multiple datasets and adding noise. The results obtained reflect high reliability and demonstrate the effectiveness and scalability of the proposed multi-output DL approach. [ABSTRACT FROM AUTHOR]

Published

2023

14. A dual attribute weighted decision fusion system for fault classification based on an extended analytic hierarchy process.

Author

He, Yuchen, Lou, Ruichong, Wang, Yun, Wang, Jun, and Fang, Xinyun

Subjects

*ANALYTIC hierarchy process, *MANUFACTURING processes, *INDUSTRIAL efficiency, *CLASSIFICATION

Abstract

As substantial parts of process monitoring, fault classification techniques have been widely utilized in modern industries. However, most methods can only perform well under specific condition, which indicates that it is always difficult to ensure the classification efficiency for complex industrial processes using only one method. In this paper a weighted decision fusion system is proposed where an extended analytic hierarchy process (EAHP) structure is designed to give a comprehensive explanation for the weights assigned to the original fault classification results. Firstly, the fault category information is embedded in the EAHP structure, which makes it possible to consider both fault-wise and classifier-wise information in the fault classification. Secondly, an overall priority (OP) matrix is proposed to provide full prior knowledge for all classifiers. Different from previous researches, traditional OP vectors are replaced by the new-designed OP matrix which can contain more information about fault category. Thirdly, another confidence matrix is carried out to update the classification results. Compared with previous state-of-art, the confidence matrix can be adjusted according to the specific original classification result Finally, the effectiveness of the proposed method is verified by a numerical example and the Tennessee Eastman process (TEP) where the proposed decision fusion system shows superior fault classification results in both experiments. [ABSTRACT FROM AUTHOR]

Published

2022

15. Feature extraction and health status prediction in PV systems.

Author

Sepúlveda Oviedo, Edgar Hernando, Travé-Massuyès, Louise, Subias, Audine, Alonso, Corinne, and Pavlov, Marko

Subjects

*FEATURE extraction, *PHOTOVOLTAIC power systems, *FISHER discriminant analysis, *DATA acquisition systems, *CLASSIFICATION algorithms, *POWER plants, *PARTIAL least squares regression

Abstract

Diagnosis aims at predicting the health status of components and systems. In photovoltaic systems, it is vital to guarantee energy production and extend the useful life of photovoltaic power plants. Multiple prediction and classification algorithms have been proposed for this purpose in the literature. The accuracy of these algorithms depends directly on the quality of the data and the features with which they are tuned or trained. In this paper, an innovative approach for predicting the health status of photovoltaic systems is proposed, which includes a feature selection stage. This approach first discriminates severely affected photovoltaic panels using basic electrical features. In a second step, it discriminates the other faulty panels using more elaborated time–frequency features and selecting the most relevant features through correlation and variance analysis. Finally, the approach predicts the health status of photovoltaic panels using a nonlinear regression method named partial least squares. This later is then combined with linear discriminant analysis and compared. The approach is validated with real current data from a photovoltaic plant composed of twelve photovoltaic panels with power between 205 and 240 Wp in three health states, namely broken glass, healthy, and big snail trails. The results obtained show that the proposed approach efficiently predicts the three health states. It determines the level of degradation of the panels, which indicates priorities to corrective and predictive maintenance actions. Furthermore, it is cost-effective since it uses only electrical measurements that are already available in standard photovoltaic data acquisition systems. Above all, the approach is generic and it can be easily extrapolated to other diagnosis problems in other domains. [ABSTRACT FROM AUTHOR]

Published

2022

16. An efficient fault classification method in solar photovoltaic modules using transfer learning and multi-scale convolutional neural network.

Author

Korkmaz, Deniz and Acikgoz, Hakan

Subjects

*CONVOLUTIONAL neural networks, *DEEP learning, *PHOTOVOLTAIC power systems, *VISUAL perception, *NETWORK performance, *BUILDING-integrated photovoltaic systems, *POWER plants

Abstract

Photovoltaic (PV) power generation is one of the remarkable energy types to provide clean and sustainable energy. Therefore, rapid fault detection and classification of PV modules can help to increase the reliability of the PV systems and reduce operating costs. In this study, an efficient PV fault detection method is proposed to classify different types of PV module anomalies using thermographic images. The proposed method is designed as a multi-scale convolutional neural network (CNN) with three branches based on the transfer learning strategy. The convolutional branches include multi-scale kernels with levels of visual perception and utilize pre-trained knowledge of the transferred network to improve the representation capability of the network. To overcome the imbalanced class distribution of the raw dataset, the oversampling technique is performed with the offline augmentation method, and the network performance is increased. In the experiments, 11 types of PV module faults such as cracking, diode, hot spot, offline module, and other classes are utilized. The average accuracy is obtained as 97.32% for fault detection and 93.51% for 11 anomaly types. The experimental results indicate that the proposed method gives higher classification accuracy and robustness in PV panel faults and outperforms the other deep learning methods and existing studies. • The Multi-scale network efficiently classifies photovoltaic panel anomalies. • Oversampling approach overcomes the imbalanced class distribution. • Multi-scale branches aim to improve the features extracted by each parallel block. • Proposed method is validated with a large dataset collected from six continents. [ABSTRACT FROM AUTHOR]

Published

2022

17. A machine learning-based approach for comprehensive fault diagnosis in transmission lines.

Author

França, Isternândia Araújo, Vieira, Cynthia Wanick, Ramos, Daniel Correa, Sathler, Lara Hoffmann, and Carrano, Eduardo G.

Subjects

*ELECTRIC lines, *FAULT diagnosis, *DECISION trees, *ELECTRIC fault location, *MACHINE learning, *MACHINERY, *POWER transmission

Abstract

Faults in transmission lines can cause several problems to transmission utilities. An adequate diagnosis of such events can improve service restoration time and, consequently, asset availability. This work proposes a machine learning-based approach to diagnose transmission line faults. The oscillography files of the fault case are processed and applied to four different classifiers, which must identify: phases involved, electrical nature, impedance level, and, fault cause. The method, which is inherently robust regarding signal noise and lack of synchronization between relays, combines Decision Trees, feature engineering, and optimization to perform the fault diagnosis based only on relay measures. It was tested in two fault data sets, one containing 24,000 faults generated using a Real Time Digital Simulator and another one with 46 real faults. The results obtained were very promising, with accuracy values close to 100% for involved phase and fault nature, 90% for impedance level, and 80% for fault cause. [Display omitted] • A ML approach is proposed for comprehensive fault diagnosis in transmission lines. • Fault phases, nature, impedance, and cause are inferred from oscillographs. • The approach is very robust regarding noise and lack of synchronism between relays. • It relies on very few adjustable parameters. Most internal parameters are optimized. • Results on RTDS simulated and real fault cases are provided. [ABSTRACT FROM AUTHOR]

Published

2022

18. Improving classification-based diagnosis of batch processes through data selection and appropriate pretreatment.

Author

Gins, Geert, Van den Kerkhof, Pieter, Vanlaer, Jef, and Van Impe, Jan F.M.

Subjects

*DATA analysis, *FEATURE selection, *DEBUGGING, *CLASSIFICATION algorithms, *NEAREST neighbor analysis (Statistics)

Abstract

This work considers the application of classification algorithms for data-driven fault diagnosis of batch processes. A novel data selection methodology is proposed which enables online classification of detected disturbances without requiring the estimation of unknown (future) process behavior, as is the case in previously reported approaches. The proposed method is benchmarked in two case studies using the Pensim process model of Birol et al. (2002) implemented in RAYMOND . Both a simple k Nearest Neighbors ( k -NN) and complex Least Squares Support Vector Machine (LS-SVM) are employed for classification to demonstrate the generic nature of the proposed approach. In addition, the influence of different data pretreatment methods on the classification performance is discussed, together with a motivation for selecting the correct pretreatment steps. Finally, the influence of the number of available training batches is studied. The results demonstrate that a good classification performance can be achieved with the proposed data selection method even with a low number of faulty training batches by exploiting knowledge on the nature of the to-be-diagnosed faults in the data pretreatment. This provides a proof of concept for classification-based batch diagnosis and demonstrates the importance of incorporating process insight in the construction of data-driven process monitoring and diagnosis tools. [ABSTRACT FROM AUTHOR]

Published

2015

19. An intelligent fault diagnosis system for newly assembled transmission.

Author

Shang, Wenli, Zhou, Xiaofeng, and Yuan, Jie

Subjects

*ARTIFICIAL intelligence, *DEBUGGING, *GENETIC algorithms, *FEATURE selection, *SPECTRAL theory, *DATA acquisition systems, *DATA transmission systems

Abstract

Highlights: [•] We present a fault diagnosis expert system for newly assembled auto transmission. [•] Synchronous data acquisition algorithm of the vibration signal and the speed signal. [•] Improved FFT algorithm which is used for spectral transformation after a lot of tests. [•] Knowledge representation and knowledge renew algorithm for transmission. [•] Improved genetic algorithm for feature selection and fault classification with BP network. [Copyright &y& Elsevier]

Published

2014

20. Weighted local and global regressive mapping: A new manifold learning method for machine fault classification.

Author

Jin, Xiaohang, Yuan, Fang, Chow, Tommy W.S., and Zhao, Mingbo

Subjects

*REGRESSION analysis, *MATHEMATICAL mappings, *MANIFOLDS (Mathematics), *MACHINE learning, *FAULT location (Engineering), *VIBRATION (Mechanics)

Abstract

Abstract: This article studies if machine faults can be effectively determined in a reduced dimensional space. When faults occur in machines, machine vibration signals will deviate from its normal signal pattern. Such changes can be reflected in the features constructed from the machine signals. In this article, 13-dimension feature data set is constructed to represent different health conditions of machines, and unsupervised learning algorithms are introduced to deal with feature data sets for feature extraction and fault classification. A weighted local and global regressive mapping (WLGRM) algorithm is proposed for machine fault classification. Two synthetic fault data sets and two experimental data sets are employed to validate the effectiveness of the proposed approach. Comparative analysis with other unsupervised learning algorithms, such as local and global regressive mapping, locality preserving projection, Isomap, principal component analysis, and Sammon mapping, are reported. The results show that different machine faults can be classified, the degree of fault severity can be captured, and WLGRM can achieve better performance than other algorithms in most cases of machine fault classification. [Copyright &y& Elsevier]

Published

2014

21. Anomaly detection of cooling fan and fault classification of induction motor using Mahalanobis–Taguchi system.

Author

Jin, Xiaohang and Chow, Tommy W.S.

Subjects

*FANS (Machinery), *ELECTRIC fault location, *INDUCTION motors, *TAGUCHI methods, *SIGNAL theory, *DATA extraction, *GAUSSIAN distribution, *MACHINE theory, *MACHINERY maintenance & repair

Abstract

Abstract: A health index, Mahalanobis distance (MD), is proposed to indicate the health condition of cooling fan and induction motor based on vibration signal. Anomaly detection and fault classification are accomplished by comparing MDs, which are calculated based on the feature data set extracted from the vibration signals under normal and abnormal conditions. Since MD is a non-negative and non-Gaussian distributed variable, Box–Cox transformation is used to convert the MDs into normal distributed variables, such that the properties of normal distribution can be employed to determine the ranges of MDs corresponding to different health conditions. Experimental data of cooling fan and induction motor are used to validate the proposed approach. The results show that the early stage failure of cooling fan caused by bearing generalized-roughness faults can be detected successfully, and the different unbalanced electrical faults of induction motor can be classified with a higher accuracy by Mahalanobis–Taguchi system. Such works could aid in the reliable operation of the machines, the reduction of the unexpected failures, and the improvement of the maintenance plan. [Copyright &y& Elsevier]

Published

2013

22. OC fault diagnosis of multilevel inverter using SVM technique and detection algorithm.

Author

Sarita, Kumari, Kumar, Sachin, and Saket, R.K.

Subjects

*ALGORITHMS, *INSULATED gate bipolar transistors, *SUPPORT vector machines, *FEATURE extraction

Abstract

The Open Circuit (OC) faults occurring in switches of Multilevel Converters (MLC) may lead to undesirable operation of the converter. Therefore, fault detection and its localization in minimum time are necessary. This paper focuses on the fast fault detection algorithm based on the two samples technique and the fault localization algorithm using the Entropy of Wavelet Packets (EWP) as a feature. The EWP feature is used to classify and localize the OC faults in Insulated Gate Bipolar Transistors (IGBTs) of three-phase, three-level inverter using Support Vector Machine (SVM) based fault classification algorithm. The proposed technique can detect the fault in single IGBT and multiple IGBTs in a lesser time range of microseconds to 0.33 ms. It gives better performance and accuracy (99.70%) than previously proposed SVM algorithms, as the EWP-based feature extraction process used in this paper is simple and accurate with a less computational burden. [Display omitted] • An observer-based algorithm is proposed using two samples-based technique. • The Entropy of Wavelet Packets (EWP-SVM) technique is used for fault diagnosis. • The proposed algorithm can detect the faults in a single IGBT and multiple IGBTs. • The technique is faster and accurate than techniques available in the literature. • The comparison of detection time of different techniques is also discussed. [ABSTRACT FROM AUTHOR]

Published

2021

23. Application of extreme learning machine for series compensated transmission line protection

Author

Malathi, V., Marimuthu, N.S., Baskar, S., and Ramar, K.

Subjects

*MACHINE learning, *ELECTRIC lines testing, *WAVELETS (Mathematics), *ELECTRIC fault location, *ELECTRIC currents, *CAPACITORS, *ROBUST control, *FEASIBILITY studies

Abstract

Abstract: This paper proposes a new approach based on combined Wavelet Transform-Extreme Learning Machine (WT-ELM) technique for fault section identification (whether the fault is before or after the series capacitor as observed from the relay point), classification and location in a series compensated transmission line. This method uses the samples of fault currents for half cycle duration from the inception of fault. The features of fault currents are extracted by first level decomposition of the current samples using discrete wavelet transform (DWT) and the extracted features are applied as inputs to ELMs for fault section identification, classification and location. The feasibility of the proposed method has been tested on a 400kV, 300km series compensated transmission line for all the ten types of faults using MATLAB simulink. On testing 28,800 fault cases with varying fault resistance, fault inception angle, fault distance, load angle, percentage compensation level and source impedance, the performance of the proposed method has been found to be quite promising. The results also indicate that the proposed method is robust to wide variation in system and operating conditions. [Copyright &y& Elsevier]

Published

2011

24. LDA-based deep transfer learning for fault diagnosis in industrial chemical processes.

Author

Wang, Yalin, Wu, Dongzhe, and Yuan, Xiaofeng

Subjects

*CHEMICAL processes, *FAULT diagnosis, *MANUFACTURING processes, *DEEP learning, *FISHER discriminant analysis, *SIGNAL convolution

Abstract

Deep transfer network (DTN) has been widely used for classification tasks, which introduces maximum mean discrepancy (MMD) based loss function to extract similar latent features and reduce the discrepancy of distributions across the source and target data. However, it is a little challenging to apply deep transfer learning for fault classification tasks in industrial chemical processes, since process variables have physicochemical properties and occupy different impacts in reflecting the process status. Hence, features extracted from these process variables also have different contributions for domain adaptation in DTN. In this paper, a linear discriminant analysis (LDA)–based DTN is proposed for fault classification ofchemical processes, in which a weighted MMD is designed for domain adaptation. First, the LDA algorithm is introduced to determine how much influence each variable can distinguish samples from source and target domains. Then, a corresponding weight is assigned to each feature variable to design the weighted MMD for network transferring. A Tennessee Eastman (TE) process and a real hydrocracking process are used to validate the fault classification performance of the LDA-based DTN. The results indicate LDA-based DTN has better generalization performance and classification accuracy than traditional DTN. [ABSTRACT FROM AUTHOR]

Published

2020

25. Dynamic Bayesian network for robust latent variable modeling and fault classification.

Author

Zheng, Junhua, Zhu, Jinlin, Chen, Guangjie, Song, Zhihuan, and Ge, Zhiqiang

Subjects

*LATENT variables, *MULTIVARIATE analysis, *ELECTRONIC data processing, *CLASSIFICATION, *FEATURE extraction

Abstract

This work deals with robust dynamic probabilistic modeling and fault classification for process data. In dynamic processes, observed variables can be numerous in amount and correlated with each other in both variable-wise and time-wise. While multivariate statistical analysis methods such as principle component analysis (PCA) are widely used to handle variable-wise correlations and also for dimension reduction purpose, the time-wise correlation among process data is typically addressed by constructing dynamical models, e.g. time-series data model, state space model, etc. In this paper, the robust probabilistic principle component analysis (RPPCA) model is introduced for feature extraction from contaminated process data, suffered from outliers, disturbances, heave noises, etc. A dynamic Bayesian network (DBN) is then constructed, with incorporation of a mixture of Gaussian components for approximation of the non-Gaussian characteristics of latent variables. Based on the developed robust dynamic Bayesian network model, a fault classification scheme is proposed. To validate the effectiveness and feasibility of the new method, two well-known benchmark case studies are carried out. Simulation results show that robust dynamic method performs better in outlier contaminated situations, where the performance has been improved by 10%–20% in most cases. [ABSTRACT FROM AUTHOR]

Published

2020

26. Fault location estimation for series-compensated double-circuit transmission line using EWT and weighted RVFLN.

Author

Sahani, Mrutyunjaya and Dash, P.K.

Subjects

*ELECTRIC fault location, *FAULT location (Engineering), *ELECTRIC lines, *FIELD programmable gate arrays, *HILBERT transform, *FAULT diagnosis, *HOUGH transforms, *COMPUTATIONAL intelligence

Abstract

In this paper, empirical Wavelet transform (EWT), Hilbert transform (HT) and weighted random vector functional link network (WRVFLN) are integrated for fault detection, classification, and location estimation in a series capacitor compensated double circuit transmission line (SCCDCTL). The full cycle current signals from the point of fault inception are decomposed using EWT to extract three band-limited modes (BLMs). The four efficacious instantaneous features namely energy, Shannon entropy, the standard deviation of the magnitude, and crest factor are computed from the Hilbert transformed array of the BLMs to construct the feature vector. A diagonal matrix W is computed from the zero sequence current of original six current signals as a weighting factor to categorize the ground fault accurately. Numerous faults are generated with a wide variation of the system conditions such as fault resistance, fault inception angle, fault distance, percentage compensation level, source impedance, line parameters, load angle, and inter-circuit fault in MATLAB/Simulink environments. An efficient WRVFLN computational intelligence technique is proposed to recognize and estimate the location of the faults by taking the extracted suitable feature vector with weight factor as an input. The performances of WRVFLN are compared with the recently developed advanced classifiers such as least-square support vector machine (LSSVM) and extreme learning machine (ELM) in the MATLAB interface. The lesser computational complexity, faster learning speed, superior classification accuracy, accurate fault location estimation, and short event detection time prove that the proposed EWTHT–WRVFLN method can be implemented in the real power system for online fault diagnosis. Finally, the developed system architecture is implemented on the reconfigurable digital field programmable gate array (FPGA) in ISE design suite 14.5 environments to verify the cogency of the proposed method in real-time. The feasibility of the proposed method is tested and validated by using the fast FPGA digital circuitry in a loop. • Empirical Wavelet Transform is used for series compensated lines for fault studies. • A weighted Random Vector Functional Link Network is used for fault classification and location. • A comparison with LS-SVM is presented in this paper to validate the superiority of WRVFLN. • Implementation of the WRVFLN using FPGA hardware exhibits the real-time capability of the new approach. [ABSTRACT FROM AUTHOR]

Published

2020

27. Combining multiple deep learning algorithms for prognostic and health management of aircraft.

Author

Che, Changchang, Wang, Huawei, Fu, Qiang, and Ni, Xiaomei

Subjects

*MACHINE learning, *SHORT-term memory, *DEEP learning, *ARTIFICIAL intelligence, *ERROR rates, *TIME series analysis, *RECURRENT neural networks

Abstract

The development of airborne sensor monitoring and artificial intelligence technologies provides effective tools for precise prognostic and health management (PHM) of aircraft. This paper presents a PHM model which combines multiple deep learning algorithms for condition assessment, fault classification, sensor prediction, and remaining useful life (RUL) estimation of aircraft systems. A long short-term memory (LSTM) based recurrent network is used to predict multiple multivariate time series of sensors, and deep belief network (DBN) is applied to assess system condition and classify faults of aircraft systems. Then, the RUL can be estimated through the integration of condition assessment and sensor prediction. Finally, the proposed algorithm is validated experimentally using NASA's C-MAPSS dataset, and the results showed a lower error rate and deviation than traditional models. [ABSTRACT FROM AUTHOR]

Published

2019