Design-Oriented Study of Advanced Synchronous Reference Frame Phase-Locked Loops
سال
: 2013
چکیده: In grid-connected applications, the synchronous reference frame phase-locked loop (SRF-PLL) is a commonly used synchronization technique due to the advantages it offers such as ease of implementation and robust performance. Under ideal grid conditions, the SRF-PLL enables a fast and accurate phase/frequency detection; however, unbalanced and distorted grid conditions highly degrade its performance. To overcome this drawback, several advanced PLLs have been proposed, such as the multiple reference frame-based PLL, the dual second-order generalized integrator-based PLL, and the multiple complex coefficient filter-based PLL. In this paper, a comprehensive design-oriented study of these advanced PLLs is presented. The starting point of this study is to derive the small-signal model of the aforementioned PLLs, which simplifies the parameter design and the stability analysis. Then, a systematic design procedure to fine tune the PLLs parameters is presented. The stabilitymargin, the transient response, and the disturbance rejection capability are the key factors that are considered in the design procedure. Finally, the experimental results are presented to support the theoretical analysis.
کلیدواژه(گان): Dual second-order generalized integrator (DSOGI),multiple complex coefficient filter (MCCF),multiple reference frame (MRF),phase-locked loop (PLL),synchronous reference frame (SRF),synchronization,three-phase gridconnected converters
کالکشن
:
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آمار بازدید
Design-Oriented Study of Advanced Synchronous Reference Frame Phase-Locked Loops
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contributor author | Saeed Golestan | en |
contributor author | محمد منفرد | en |
contributor author | Francisco D. Freijedo | en |
contributor author | Mohammad Monfared | fa |
date accessioned | 2020-06-06T13:09:30Z | |
date available | 2020-06-06T13:09:30Z | |
date issued | 2013 | |
identifier uri | https://libsearch.um.ac.ir:443/fum/handle/fum/3343887 | |
description abstract | In grid-connected applications, the synchronous reference frame phase-locked loop (SRF-PLL) is a commonly used synchronization technique due to the advantages it offers such as ease of implementation and robust performance. Under ideal grid conditions, the SRF-PLL enables a fast and accurate phase/frequency detection; however, unbalanced and distorted grid conditions highly degrade its performance. To overcome this drawback, several advanced PLLs have been proposed, such as the multiple reference frame-based PLL, the dual second-order generalized integrator-based PLL, and the multiple complex coefficient filter-based PLL. In this paper, a comprehensive design-oriented study of these advanced PLLs is presented. The starting point of this study is to derive the small-signal model of the aforementioned PLLs, which simplifies the parameter design and the stability analysis. Then, a systematic design procedure to fine tune the PLLs parameters is presented. The stabilitymargin, the transient response, and the disturbance rejection capability are the key factors that are considered in the design procedure. Finally, the experimental results are presented to support the theoretical analysis. | en |
language | English | |
title | Design-Oriented Study of Advanced Synchronous Reference Frame Phase-Locked Loops | en |
type | Journal Paper | |
contenttype | External Fulltext | |
subject keywords | Dual second-order generalized integrator (DSOGI) | en |
subject keywords | multiple complex coefficient filter (MCCF) | en |
subject keywords | multiple reference frame (MRF) | en |
subject keywords | phase-locked loop (PLL) | en |
subject keywords | synchronous reference frame (SRF) | en |
subject keywords | synchronization | en |
subject keywords | three-phase gridconnected converters | en |
journal title | IEEE Transactions on Power Electronics | fa |
pages | 765-778 | |
journal volume | 28 | |
journal issue | 2 | |
identifier link | https://profdoc.um.ac.ir/paper-abstract-1029941.html | |
identifier articleid | 1029941 |