Computationally-Efficient Synchrophasor Estimation: Delayed in-quadrature Interpolated DFT
Abstract
The paper proposes a synchropahsor estimation (SE) algorithm that leverages the use of a delayed in-quadrature complex signal to mitigate the self-interference of the fundamental tone. The estimator, which uses a three-point IpDFT combined with a three-cycle Hanning window, incorporates a new detection mechanism to iteratively estimate and remove the effects caused by interfering tones within the out-of-band interference (OOBI) range. The main feature of the method is its ability to detect interfering tones with an amplitude lower than that adopted by the IEC/IEEE Std. 60255-118, this detection being notably challenging. Furthermore, it simultaneously satisfies all the accuracy requirements for the P and M phasor measurement unit (PMU) performance classes, while offering a reduction in the total computational cost compared to other state-of-the-art techniques. Despite an increase in total memory requirements, a preliminary analysis reveals its suitability for implementation on embedded devices.
Cite
@article{arxiv.2304.07634,
title = {Computationally-Efficient Synchrophasor Estimation: Delayed in-quadrature Interpolated DFT},
author = {César García Veloso and Mario Paolone and José María Maza Ortega},
journal= {arXiv preprint arXiv:2304.07634},
year = {2024}
}
Comments
15 pages, 15 figures. Article submitted for consideration to IEEE Transactions on Instrumentation and Measurement. (Non peer reviewed)