Cosine Windows in Interpolated DFT-based Method for an Accurate High-Frequency Distortion Assessment in Power Systems

Q4 Energy
A. Bracale, P. Caramia, G. Carpinelli, P. De Falco, P. Verde
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Abstract

The transformation of electrical networks in the context of the new smart grid paradigm unavoidably involves new challenges regarding Power Quality (PQ) disturbances not only for customers but also for all the other involved stakeholders. Among PQ disturbances, waveform distortions have recently gained growing interest due to the massive presence of new technologies in distributed energy resources, in modern loads and in advanced smart metering systems. The presence of these devices determines arduous electromagnetic compatibility problems since the current and voltage waveform distortions in smart grids are characterized by spectral components above the traditional 2 kHz frequency limit, in a range extended up to 150 kHz. In this paper, an interpolated DFT-based (IDFT) method, recently proposed in the relevant literature in the field of signal processing, is properly extended for an accurate and fast assessment of power system waveform distortions in the frequency range from 2 to 150 kHz. Since DFT-based methods can suffer well-known spectral leakage problems, in this paper the IDFT is applied using cosine windows that minimize interference conditions among spectral components and maximise the estimation accuracy of the spectral component amplitude, phase angle and frequency. An optimal number of cosine window terms is also searched to improve the spectral analysis of high-frequency power system waveforms. Numerical applications on synthetic test signals and measured waveforms are carried out to quantify the accuracy and computational efforts of the proposed approach and to select the cosine window terms that better optimize the waveform distortion assessment.
基于余弦窗插值dft的电力系统高频失真准确评估方法
在新的智能电网模式背景下,电网的转型不可避免地涉及电能质量(PQ)干扰的新挑战,不仅对客户,而且对所有其他相关利益相关者。在PQ干扰中,由于分布式能源、现代负载和先进的智能计量系统中大量存在新技术,波形失真最近引起了越来越多的关注。这些设备的存在决定了艰巨的电磁兼容性问题,因为智能电网中的电流和电压波形失真的特征是频谱成分高于传统的2 kHz频率限制,范围扩展到150 kHz。本文对信号处理领域的相关文献中提出的一种基于内插dft (IDFT)的方法进行了适当的扩展,以准确、快速地评估2 ~ 150khz频率范围内的电力系统波形畸变。由于基于dft的方法可能会出现众所周知的频谱泄漏问题,因此本文使用余弦窗应用IDFT,使频谱分量之间的干扰条件最小化,并最大限度地提高了频谱分量幅度、相位角和频率的估计精度。为了改进高频电力系统波形的频谱分析,本文还研究了余弦窗项的最优数目。对合成测试信号和测量波形进行了数值应用,以量化所提出方法的精度和计算量,并选择更好地优化波形失真评估的余弦窗项。
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
Renewable Energy and Power Quality Journal
Renewable Energy and Power Quality Journal Energy-Energy Engineering and Power Technology
CiteScore
0.70
自引率
0.00%
发文量
147
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