KOMPARATIVNA ANALIZA REKURENTNIH I TRANSFORMER MODELA MAŠISNKOG UČENJA ZA PREDIKCIJU PROIZVODNJE AKTIVNE SNAGE VETROGENERATORA

37. саветовање CIGRE Србија (2025) СИГУРНОСТ, СТАБИЛНОСТ, ПОУЗДАНОСТ И RESILIENCE ЕЛЕКТРОЕНЕРГЕТСКОГ СИСТЕМА МУЛТИСЕКТОРСКО ПОВЕЗИВАЊЕ У ЕНЕРГЕТИЦИ И ПРИВРЕДИ – A1.04 

АУТОР(И) / AUTHOR(S): Лука Ивановић, Илија Класнић, Саша Милић

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DOI:  10.46793/CIGRE37.A1.04

САЖЕТАК / ABSTRACT:

Wind turbines are inherently intermittent energy sources that predominantly depend on meteorological conditions. Accurate prediction of wind turbine active power generation is crucial for optimizing the operation of modern power systems rich in renewable energy sources, improving system stability, enhancing the efficiency of production and consumption balancing, optimizing the electricity market, and numerous other aspects. The development and application of advanced artificial intelligence and machine learning (ML) methods can further increase prediction accuracy, enabling the system to better adapt to the variable nature of wind energy. This paper investigates the efficiency of two machine learning approaches for predicting wind turbine active power, focusing on ML models based on recurrent neural networks (LSTM and GRU) and Transformer models adapted for processing and predicting time series data. Transformer models have recently gained prominence in time series analysis due to their ability to effectively recognize long-term dependencies in data through the self-attention mechanism, enabling parallel sequence processing and more accurate identification of relevant patterns in the data. The choice of transformer model architecture and parameter tuning is conditioned by two iterative processes. The validation of the developed ML model is performed using a practical open-source dataset that contains a large number of input features related to meteorological and operational system parameters. The selection of the most relevant features is based on their correlation with the target variable (in this case, active power), reducing the dimensionality of the problem and improving model efficiency. The experimental evaluation includes an analysis of model performance using standard metrics (RMSE and MAEI), while simultaneously examining the transformer architecture and its parameter set. The obtained results provide insight into the advantages and limitations of both approaches in various scenarios of short-term and long-term prediction, with the aim of improving broader prediction strategies and optimizing wind farm operations.

КЉУЧНЕ РЕЧИ / KEYWORDS:

windgenerator, machine learning, recurent neural network, transformer model, time series

 ПРОЈЕКАТ /ACKNOWLEDGEMENT :

Ovaj rad je podržalo Ministarstvo nauke, tehnološkog razvoja i inovacija Republike Srbije kroz Ugovor o realizaciji i finansiranju naučnoistraživačkog rada NIO u 2025. godini.

ЛИТЕРАТУРА / REFERENCES:

  • IRENA Global Energy Transformation: A Roadmap to 2050 report, April 2019.
  • Ivanović, L., Milić, S. D., Sokolović, Ž., & Rakić, A. (2024). Komparativna analiza dubokih neuronskih mreža i algoritama sa pojačanjem gradijenta u dugoročnom predviđanju snage vetra. Zbornik radova, Elektrotehnički institut „Nikola Tesla“34, 15-36. https://doi.org/10.5937/zeint34-51258
  • IRENA (2024), Renewable energy statistics 2024, International Renewable Energy Agency, Abu Dhabi.
  • Clifton-Smith, M., D. Wood, and A. Wright. „Optimising wind turbine design for operation in low wind speed environments.“ Wind Energy Systems. Woodhead Publishing, 2011. 366-e388.
  • Bošnjaković, Mladen, et al. „Wind turbine technology trends.“ Applied Sciences 12.17 (2022): 8653.
  • Zhang, H.; Yue, D.; Dou, C.; Li, K.; Hancke, G. Two-Step Wind Power Prediction Approach with Improved Complementary Ensemble Empirical Mode Decomposition and Reinforcement Learning. IEEE Syst. J. 202216, 2545.
  • Chu, X.; Bai, W.; Sun, Y.; Li, W.; Liu, C.; Song, H. A Machine Learning-Based Method for Wind Fields Forecasting Utilizing GNSS Radio Occultation Data. IEEE Access 202210, 30258.
  • Karaman, Ö.A. Prediction of Wind Power with Machine Learning  Models. Appl. Sci. 202313, 11455. https://doi.org/10.3390/app132011455
  • Liu, T.; Huang, Z.; Tian, L.; Zhu, Y.; Wang, H.; Feng, S. Enhancing Wind Turbine Power Forecast via Convolutional Neural Network. Electronics 202110, 261. 
  • Solas, M.; Cepeda, N.; Viegas, J.L. Convolutional Neural Network for Short-Term Wind Power Forecasting. In Proceedings of the 2019 IEEE PES Innovative Smart Grid Technologies Europe (ISGT-Europe), Bucharest, Romania, 29 September–2 October 2019; Institute of Electrical and Electronics Engineers: Piscataway, NJ, USA, 2019; pp. 1–5. 
  • Byrne, Raymond; MacArtain, Paul (2022), “Vestas V52 Wind Turbine, 10-minute SCADA Data, 2006-2020 – Dundalk Institute of Technology, Ireland”, Mendeley Data, V2, doi: 10.17632/tm988rs48k.2
  • J. Chung, et al., „Empirical Evaluation of Gated Recurrent Neural Networks on Sequence Modeling,“ 2015. [Online]. Available: https://doi.org/10.48550/arXiv.1412.3555
  • A. Vaswani, et al., “Attention Is All You Need,” In the Proceedings of the 31st Conference on Neural Information Processing Systems (NIPS), 2017, Long Beach, CA, USA. https://doi.org/10.48550/arXiv.1706.03762
  • Y. Nie, N. H. Nguyen, P. Sinthong, J. Kalagnanam, “A time series is worth 64 words: Long-term forecasting with transformers,” arXiv:2211.14730, 2022. https://doi.org/10.48550/arXiv.2211.14730