A D-stacking dual-fusion, spatio-temporal graph deep neural network based on a multi-integrated overlay for short-term wind-farm cluster power multi-step prediction

The uncertainty of wind energy due to its non-stationary and random nature poses a major challenge to engineers responsible for power system scheduling. In the present research, a spatio-temporal graph deep neural network is used to learn the spatial characteristics and explore the strong correlatio...

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Vydáno v:Energy (Oxford) Ročník 281; s. 128289
Hlavní autoři: Qu, Zhijian, Li, Jian, Hou, Xinxing, Gui, Jianglin
Médium: Journal Article
Jazyk:angličtina
Vydáno: Elsevier Ltd 15.10.2023
Témata:
algorithms
China
energy
Improved stacking
Multi-integration fusion
Multi-step rolling forecast
neural networks
power generation
prediction
Spatio-temporal graph deep neural network
uncertainty
wind
wind farms
wind power
Wind power forecasting
China
Improved stacking
Spatio-temporal graph deep neural network
Multi-integration fusion
Multi-step rolling forecast
Wind power forecasting
ISSN:0360-5442
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Shrnutí:The uncertainty of wind energy due to its non-stationary and random nature poses a major challenge to engineers responsible for power system scheduling. In the present research, a spatio-temporal graph deep neural network is used to learn the spatial characteristics and explore the strong correlation characteristics of wind-farm clusters. The Bagging, long short-term memory (LSTM), and random forest (RF) are superimposed based on the stacking integration algorithm. By analyzing the decomposed wind electron sequence characteristics, two Stacking models are used to predict the wind power of target wind-farms respectively and then a dual stacking model fusion strategy is formed. Finally, a multi-step prediction model with the spatio-temporal characteristics of D-stacking multi-integration fusion is designed for rolling multi-step prediction of wind-farm cluster power to obtain high-precision target wind-farm power. Through the actual wind power generation measured in northwest China to conduct case studies and comparative tests, it concludes that:(1) Spatio-temporal method in this paper can effectively extract the deep spatial features of wind farm clusters. (2) Dual fusion strategy improves Stacking effectively. (3) The proposed model can obtain accurate wind power prediction results, which is superior to 14 comparative algorithms proposed by other researchers. •The spatio-temporal graph network is proposed to capture spatiotemporal features.•An integration algorithm for a multi-integration overlay framework is investigated.•The D-stacking spatio-temporal feature multi-step prediction model is proposed.•The dual Stacking model fusion strategy is proposed to improve the stacking algorithm.•The proposed method provides more accurate predictions than other methods.
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ISSN:0360-5442
DOI:10.1016/j.energy.2023.128289