Data-Mining Techniques Based Relaying Support for Symmetric-Monopolar-Multi-Terminal VSC-HVDC System

IF 3.8 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS
Abha Pragati, D. A. Gadanayak, Tanmoy Parida, Manohar Mishra
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引用次数: 3

Abstract

Considering the advantage of the ability of data-mining techniques (DMTs) to detect and classify patterns, this paper explores their applicability for the protection of voltage source converter-based high voltage direct current (VSC-HVDC) transmission systems. In spite of the location of fault occurring points such as external/internal, rectifier-substation/inverter-substation, and positive/negative pole of the DC line, the stated approach is capable of accurate fault detection, classification, and location. Initially, the local voltage and current measurements at one end of the HVDC system are used in this work to extract the feature vector. Once the feature vector is retrieved, the DMTs are trained and tested to identify the fault types (internal DC faults, external AC faults, and external DC faults) and fault location in the particular feeder. In the data-mining framework, several state-of-the-art machine learning (ML) models along with one advanced deep learning (DL) model are used for training and testing. The proposed VSC-HVDC relaying system is comprehensively tested on a symmetric-monopolar-multi-terminal VSC-HVDC system and presents heartening results in diverse operating conditions. The results show that the studied deep belief network (DBN) based DL model performs better compared with other ML models in both fault classification and location. The accuracy of fault classification of the DBN is found to be 98.9% in the noiseless condition and 91.8% in the 20 dB noisy condition. Similarly, the DBN-based DMT is found to be effective in fault locations in the HVDC system with a smaller percentage of errors as MSE: 2.116, RMSE: 1.4531, and MAPE: 2.7047. This approach can be used as an effective low-cost relaying support tool for the VSC-HVDC system, as it does not necessitate a communication channel.
基于数据挖掘技术的对称-单极-多端VSC-HVDC继电支持
考虑到数据挖掘技术(dmt)在模式检测和分类方面的优势,本文探讨了数据挖掘技术在基于电压源变流器的高压直流输电系统保护中的适用性。不管故障发生点的位置是外部/内部、整流-变电/逆变-变电、直流线路的正/负极,所述方法都能够准确地检测、分类和定位故障。首先,本文使用高压直流系统一端的局部电压和电流测量来提取特征向量。一旦特征向量被检索,dmt被训练和测试以识别故障类型(内部直流故障、外部交流故障和外部直流故障)和特定馈线中的故障位置。在数据挖掘框架中,几个最先进的机器学习(ML)模型以及一个先进的深度学习(DL)模型用于训练和测试。在对称-单极-多端vdc - hvdc系统上对所提出的vdc - hvdc继电保护系统进行了全面测试,并在多种工况下取得了令人振奋的结果。结果表明,所研究的基于深度信念网络(DBN)的深度学习模型在故障分类和定位方面都优于其他深度学习模型。在无噪声条件下,DBN的故障分类准确率为98.9%,在20 dB噪声条件下,准确率为91.8%。同样,基于dbn的DMT在高压直流系统的故障定位中有效,误差百分比较小,MSE: 2.116, RMSE: 1.4531, MAPE: 2.7047。这种方法可以作为一种有效的低成本的VSC-HVDC系统中继支持工具,因为它不需要通信通道。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Applied System Innovation
Applied System Innovation Mathematics-Applied Mathematics
CiteScore
7.90
自引率
5.30%
发文量
102
审稿时长
11 weeks
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