From Lidar Measurement to Rotor Effective Wind Speed Prediction: Empirical Mode Decomposition and Gated Recurrent Unit Solution

From Lidar Measurement to Rotor Effective Wind Speed Prediction: Empirical Mode Decomposition and Gated Recurrent Unit Solution

Conventional wind speed sensors face difficulties in measuring wind speeds at multiple points, and related research on predicting rotor effective wind speed (REWS) is lacking. The utilization of a lidar device allows accurate REWS prediction, enabling advanced control technologies for wind turbines....

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Bibliographic Details
Published in:Sensors (Basel, Switzerland) Vol. 23; no. 23; p. 9379
Main Authors: Shi, Shuqi, Liu, Zongze, Deng, Xiaofei, Chen, Sifan, Song, Dongran
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 24-11-2023
Subjects:
Accuracy
Air-turbines
Control algorithms
Control systems
Doppler effect
empirical mode decomposition
equilibrium optimizer
gated recurrent unit
Lasers
Measurement
Methods
Optical radar
Remote sensing
rotor effective wind speed prediction
Sensors
Technology application
Turbines
wind lidar
gated recurrent unit
empirical mode decomposition
equilibrium optimizer
rotor effective wind speed prediction
wind lidar
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Summary:Conventional wind speed sensors face difficulties in measuring wind speeds at multiple points, and related research on predicting rotor effective wind speed (REWS) is lacking. The utilization of a lidar device allows accurate REWS prediction, enabling advanced control technologies for wind turbines. With the lidar measurements, a data-driven prediction framework based on empirical mode decomposition (EMD) and gated recurrent unit (GRU) is proposed to predict the REWS. Thereby, the time series of lidar measurements are separated by the EMD, and the intrinsic mode functions (IMF) are obtained. The IMF sequences are categorized into high-, medium-, and low-frequency and residual groups, pass through the delay processing, and are respectively used to train four GRU networks. On this basis, the outputs of the four GRU networks are lumped via weighting factors that are optimized by an equilibrium optimizer (EO), obtaining the predicted REWS. Taking advantages of the measurement information and mechanism modeling knowledge, three EMD-GRU prediction schemes with different input combinations are presented. Finally, the proposed prediction schemes are verified and compared by detailed simulations on the BLADED model with four-beam lidar. The experimental results indicate that compared to the mechanism model, the mean absolute error corresponding to the EMD-GRU model is reduced by 49.18%, 53.43%, 52.10%, 65.95%, 48.18%, and 60.33% under six datasets, respectively. The proposed method could provide accurate REWS prediction in advanced prediction control for wind turbines.
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content type line 23
ISSN:1424-8220
1424-8220
DOI:10.3390/s23239379