One-Step-Prediction Discrete Observer Based Frequency-Locked-Loop Technique for Three-Phase System

One-Step-Prediction Discrete Observer Based Frequency-Locked-Loop Technique for Three-Phase System

In grid-tied power converters, the grid parameters such as the frequency, phase angle of the fundamental component, and the harmonics are essential to the control of power converters, the fast and accurate estimation of the grid parameters is a challenge especially for high-order harmonics. This pap...

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Veröffentlicht in:IEEE access 2021, Vol.9, p.95401-95411
Hauptverfasser: Hu, Wei, Wu, Yaodong, Shen, Yu, Yang, Fan, Quan, Xiangjun, Deng, Fujin, Zou, Zhixiang
Format: Artikel
Sprache:eng
Schlagworte:
adaptive state observer
Algorithms
Dynamic response
Estimation
Frequency estimation
frequency locked loop
Frequency locked loops
Frequency locking
grid synchronization
Harmonic analysis
harmonic detection
Higher harmonics
Observers
One-step prediction
Parameter estimation
Phase locked loops
Power converters
Power harmonic filters
Sampling
Synchronism
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Zusammenfassung:In grid-tied power converters, the grid parameters such as the frequency, phase angle of the fundamental component, and the harmonics are essential to the control of power converters, the fast and accurate estimation of the grid parameters is a challenge especially for high-order harmonics. This paper proposes a one-step-prediction (OSP) discrete observer (OSPDO) to observe the fundamental and harmonic sequence components of the grid voltage. Based on the proposed OSPDO, a frequency locked loop (FLL) is designed. The proposed OSPDO-FLL has a good robustness to sampling frequency on dynamic response and high precision for frequency estimation. The proposed algorithm can estimate up to maximum 50th harmonic with a low sampling frequency thanks to the robust properties. Finally, the good characteristics of the proposed synchronization algorithm are verified by simulations and laboratory experiments.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2021.3093351