Equivalency between Adaptive Notch Filter PLL and Inverse Park PLL by Modeling and Parameter Adjustment

Synchronism algorithms play an important role in microgrid converters, and they are fundamental to the power flow control between the converters and the main grid. In island operation, synchronism algorithms provide important frequency and voltage data for converters to operate properly at steady st...

Full description

Saved in:
Bibliographic Details
Published in:Revista IEEE América Latina 2020-12, Vol.18 (12), p.2112-2121
Main Authors: Silva, Marielle Jordane da, Ferreira, Sivia Costa, Silva, Joaquim Paulo da, Santos, Mariana Guimaraes dos, Paganotti, Andre Luiz, Barbosa, Leonardo Maia
Format: Article
Language:English
Subjects:
Adaptation models
Adaptive filters
Algorithms
Computational modeling
Converters
Design parameters
Distributed generation
Dynamic response
Electronic mail
Equivalence
Flow control
Frequency locked loops
Linearization
Mathematical models
Model testing
Modeling
Modelling
Notch filters
Phase locked loops
Power flow
Steady state
Synchronism
Synchronism algorithms
Citations: Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Synchronism algorithms play an important role in microgrid converters, and they are fundamental to the power flow control between the converters and the main grid. In island operation, synchronism algorithms provide important frequency and voltage data for converters to operate properly at steady state, and also connect and disconnect from the main grid. In this context, this work presents modeling and parameter design of two structures of single-phase PLLs: the inverse park PLL (Park-PLL) and the adaptive notch filter PLL (ANF-PLL). The derivation of the linearized model of Park-PLL, previously discussed in the literature, is detailed. In addition, as main contribution this paper, a linearized model of the ANF-PLL is presented and compared with the first one. As a result, it is possible to demonstrate equivalency between the two evaluated PLL structures when their parameters are adjusted by the proposed methodology. Practical and simulated results validate the parity of the PLL structures in terms of the dynamic response and steady-state error.
ISSN:1548-0992
1548-0992
DOI:10.1109/TLA.2020.9400439