基于双元池的风电爬坡事件预测方法研究

doi:10.16381/j.cnki.issn1003-207x.2023.1508

摘要/Abstract

摘要：

近年来，风电作为重要的清洁能源在全球范围内快速发展。但是，风速急骤变化引发的风电爬坡事件会对电网产生冲击，严重时会造成风机设备损坏和电网频率失稳。现有研究表明，提高风电爬坡事件的预测精度是增强预防能力的重要手段。本文构建了能够直接预测风电爬坡事件向量的双元池预测模型。为优化数据特征提取和扩展数据，本文利用Hilbert曲线构建反映数据位置信息的数据元，利用插值法和数据扩展方法扩大训练集数据量，利用时间间隔标签分类方法降低风电爬坡向量的元素个数。为提高模型预测精度，本文设计了以时间间隔为标签的两阶段卷积神经网络分类方法，利用神经网络为每个数据元组构建方法元预测模型，并利用标签建立双元池之间的映射关系。基于澳大利亚三个风电场数据的实证分析显示，本文模型预测结果的查全率为43.90%、46.77%和43.12%，平均绝对误差为11.555、23.861和24.558，优于对比模型。

关键词: 数据元, 方法元, 神经网络, 风电爬坡

Abstract:

Wind energy， a significant source of clean energy， has undergone rapid global development in recent years. However， wind power ramp events， caused by sudden changes in wind speed， adversely affect the power grid， potentially causing damage to wind turbines and leading to frequency instability. Existing research indicates that improving the prediction accuracy for these events is crucial for enhancing preventative capabilities. The low proportion of wind power ramp events within power data， coupled with a scarcity of corresponding samples， presents a significant challenge to improving prediction accuracy. Prediction methods for wind power ramp events are primarily categorized as either indirect or direct. Indirect prediction entails initially forecasting wind power， followed by the identification of ramp events. The drawback of this approach is that its predictive accuracy decreases significantly as the prediction horizon increases， making it unsuitable for long-term forecasting. Conversely， direct prediction first identifies historical wind power ramp events and then generates predictions. While the primary prediction targets are typically Boolean values， amplitude， and rate， existing models often fail to predict key information such as the start time and location of these events. A novel dual-meta pool prediction model is proposed capable of directly predicting the wind power ramp event vector. For data processing， the Hilbert curve is employed to map one-dimensional time series data onto a two-dimensional matrix， thereby effectively preserving positional information. A dataset expansion method based on random number generation is adopted to address the paucity of wind power ramp event data. Furthermore， a meta-data classification method based on time interval labels is proposed to reduce the dimensionality of the output data and the complexity of the prediction model. A two-stage classification model based on convolutional neural networks is proposed to establish the mapping between data and labels. For each tuple of meta-data， a corresponding predictive model for the meta-method is designed， and the mapping relationship between the meta-method pool and the meta-data pool is established by using the convolutional neural network with time interval labels. In contrast to traditional methods that employ a single prediction model for all data， the proposed method effectively diminishes the complexity of the neural network， enhances the relevance of data processing， and yields superior prediction accuracy. For the empirical analysis， output power data from three wind farms （SALTCRK1， DUNDWF3 and MEWF1） are randomly selected from Australian Energy Market Operator （AEMO） website （www.aemo.com.au）.The dataset covers the period from September 15， 2021， to June 17， 2023， with a 5-minute resolution and rated installed capacities of 54MW， 121MW， and 180MW， respectively. The empirical results for the proposed model show recall rates of 43.90%， 46.77%， and 43.12%， and mean absolute errors of 11.555， 23.861， and 24.558， respectively. Although the proposed dual-meta pool prediction model introduces an innovative approach， considerable scope remains for enhancing data processing techniques and predictive methodologies， necessitating further refinement through continued research efforts.

Key words: meta-data, method-data, neural network, wind power ramp

中图分类号:

TK89

刘岭,王聚杰. 基于双元池的风电爬坡事件预测方法研究[J]. 中国管理科学, 2026, 34(2): 176-184.

Ling Liu,Jujie Wang. Dual-meta Pool Method for Wind Power Ramp Event Forecasting[J]. Chinese Journal of Management Science, 2026, 34(2): 176-184.

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参考文献 27

[1]	周伟杰，姜慧敏，成雨珂，等. 基于可重复性分数阶灰色时间幂模型的中国水电消费预测研究［J］. 中国管理科学， 2023， 31（5）： 279-286.
	Zhou W J， Jiang H M， Cheng Y K， et al. Forecasting Chinese hydropower consumption forecasting by using the repeatability fractional grey time power model［J］. Chinese Journal of Management Science， 2023， 31（5）： 279-286.
[2]	陆信辉，周开乐，杨善林. 能源互联网环境下基于分布鲁棒优化的能量枢纽负荷优化调度［J］. 系统工程理论与实践， 2021， 41（11）： 2850-2864.
	Lu X H， Zhou K L， Yang S L. Optimal load dispatch of energy hub based on distributionally robust optimization approach in energy internet environment［J］. Systems Engineering —Theory & Practice， 2021， 41（11）： 2850-2864.
[3]	Das S， Singh B. Mitigating impact of high power ramp rates in utility grid integrated wind–solar system using an RLMAT adaptive control strategy［J］. IEEE Transactions on Energy Conversion， 2023， 38（1）： 343-354.
[4]	韩学山，王心仪，杨明，等. 新能源爬坡事件综述及展望［J］. 山东大学学报（工学版）， 2021（5）： 53-62+75.
	Han X S， Wang X Y， Yang M， et al. Review and prospect of renewable energy ramp events［J］. Journal of Shandong University （Engineering Science）， 2021（5）： 53-62+75.
[5]	Fujimoto Y， Takahashi Y， Hayashi Y. Alerting to rare large-scale ramp events in wind power generation［J］. IEEE Transactions on Sustainable Energy， 2019， 10（1）： 55-65.
[6]	赵越，徐博涵，王聪，等. 基于风电场功率预测的数据价值研究［J］. 工程管理科技前沿， 2023， 42（2）： 34-42.
	Zhao Y， Xu B H， Wang C， et al. Research on data value based on wind farm power prediction［J］. Frontiers of Science & Technology of Engineering Management， 2023， 42（2）： 34-42.
[7]	Dalton A， Bekker B， Koivisto M J. Simulation and detection of wind power ramps and identification of their causative atmospheric circulation patterns［J］. Electric Power Systems Research， 2021， 192： 106936.
[8]	Dorado-Moreno M， Navarin N， Gutiérrez P A， et al. Multi-task learning for the prediction of wind power ramp events with deep neural networks［J］. Neural Networks， 2020， 123： 401-411.
[9]	Cui M， Feng C， Wang Z， et al. Statistical representation of wind power ramps using a generalized Gaussian mixture model［J］. IEEE Transactions on Sustainable Energy， 2018， 9（1）： 261-272.
[10]	Drew D R， Cannon D J， Barlow J F， et al. The importance of forecasting regional wind power ramping： A case study for the UK［J］. Renewable Energy， 2017， 114： 1201-1208.
[11]	Zucatelli P J， Nascimento E G S， Santos A Á B， et al. An investigation on deep learning and wavelet transform to nowcast wind power and wind power ramp： A case study in Brazil and Uruguay［J］. Energy， 2021， 230： 120842.
[12]	Cui Y， Chen Z， He Y， et al. An algorithm for forecasting day-ahead wind power via novel long short-term memory and wind power ramp events［J］. Energy， 2023， 263： 125888.
[13]	Cui Y， He Y， Xiong X， et al. Algorithm for identifying wind power ramp events via novel improved dynamic swinging door［J］. Renewable Energy， 2021， 171： 542-556.
[14]	Cui M， Zhang J， Wang Q， et al. A data-driven methodology for probabilistic wind power ramp forecasting［J］. IEEE Transactions on Smart Grid， 2019， 10（2）： 1326-1338.
[15]	Hu J， Zhang L， Tang J， et al. A novel transformer ordinal regression network with label diversity for wind power ramp events forecasting［J］. Energy， 2023， 280： 128075.
[16]	He Y， Zhu C， An X. A trend-based method for the prediction of offshore wind power ramp［J］. Renewable Energy， 2023， 209： 248-261.
[17]	李霞，李守伟. 基于EMD与DVG的非线性时间序列预测模型及其应用研究［J］. 中国管理科学， 2022， 30（9）： 275-286.
	Li X， Li S W. Non-linear time series prediction model based on EMD and DVG and its application［J］. Chinese Journal of Management Science， 2022， 30（9）： 275-286.
[18]	Gallego-Castillo C， Cuerva-Tejero A， Lopez-Garcia O. A review on the recent history of wind power ramp forecasting［J］. Renewable and Sustainable Energy Reviews， 2015， 52： 1148-1157.
[19]	徐思卿，柯德平，徐箭. 基于YOLOv5s的风电功率爬坡事件识别［J］. 武汉大学学报（工学版）， 2022， 55（9）： 910-918.
	Xu S Q， Ke D P， Xu J. Wind power ramp event detection based on YOLOv5s［J］. Engineering Journal of Wuhan University， 2022， 55（9）： 910-918.
[20]	Cui M， Krishnan V， Hodge B M， et al. A copula-based conditional probabilistic forecast model for wind power ramps［J］. IEEE Transactions on Smart Grid， 2019， 10（4）： 3870-3882.
[21]	Liu L， Wang J. Super multi-step wind speed forecasting system with training set extension and horizontal–vertical integration neural network［J］. Applied Energy， 2021， 292： 116908.
[22]	Liu L， Wang J， Li J， et al. Dual-meta pool method for wind farm power forecasting with small sample data［J］. Energy， 2023， 267： 126504.
[23]	Shi X， Chen Z， Wang H， et al. Convolutional LSTM network： A machine learning approach for precipitation nowcasting ［C］// Proceedings of the 29th International Conference on Neural Information Processing Systems， Montreal Canada， December 7-12 ，MIT Press， 2015： 802-810.
[24]	Kim Y， Jernite Y， Sontag D， et al. Character-aware neural language models［C］//Proceedings of the Thirtieth AAAI Conference on Artificial Intelligence，Phoenix， Arizona， February 12-17， ACM， 2016： 2741-2749.
[25]	Li G， Zhang M， Li J， et al. Efficient densely connected convolutional neural networks［J］. Pattern Recognition， 2021， 109： 107610.
[26]	Ouyang T， Zha X， Qin L， et al. Prediction of wind power ramp events based on residual correction［J］. Renewable Energy， 2019， 136： 781-792.
[27]	童林，官铮，王立威，等. 基于时序分解与误差修正的新能源爬坡事件预测［J］. 浙江大学学报（工学版）， 2022， 56（2）： 338-346.
	Tong L， Guan Z， Wang L W， et al. New energy ramp event prediction based on time series decomposition and error correction［J］. Journal of Zhejiang University （Engineering Science）， 2022， 56（2）： 338-346.

模型	方法	数据转换
M1	XGBoost	无
M2	LSTM	无
M3	GRU	无
M4	CNN-LSTM	扫描
M5	ConvLSTM	扫描

风电场	数据元数量	爬坡事件数量	占比（%）
SALTCRK1	922761	22846	2.476
DUNDWF3	922761	15007	1.626
MEWF1	922761	9206	0.998

模型	SALTCRK1	DUNDWF3	MEWF1	SALTCRK1	DUNDWF3	MEWF1	SALTCRK1	DUNDWF3	MEWF1
模型	(P)	(P)	(P)	(RC)	(RC)	(RC)	(CSI)	(CSI)	(CSI)
M1	0.1945	0.1157	0.1371	0.0773	0.2243	0.2102	0.0585	0.0826	0.0905
M2	0.2286	0.0541	0.1793	0.0339	0.0634	0.0170	0.0304	0.0301	0.0158
M3	0.1461	0.0668	0.2879	0.0324	0.0953	0.0098	0.0272	0.0409	0.0096
M4	0.1756	0.1106	0.1903	0.0461	0.1608	0.1618	0.0379	0.0701	0.0958
M5	0.1870	0.1304	0.2508	0.0592	0.1622	0.1216	0.0487	0.0779	0.0892
Mp	0.4061	0.4392	0.4918	0.4390	0.4677	0.4312	0.2674	0.2928	0.2983

模型	SALTCRK1	DUNDWF3	MEWF1	SALTCRK1	DUNDWF3	MEWF1	SALTCRK1	DUNDWF3	MEWF1
模型	(MAE)	(MAE)	(MAE)	(RMSE)	(RMSE)	(RMSE)	(MedAE)	(MedAE)	(MedAE)
M1	15.166	33.048	34.620	17.705	37.273	40.346	14.462	32.040	30.561
M2	15.128	32.892	33.206	17.761	37.155	38.505	14.448	32.282	30.364
M3	15.201	33.015	33.186	17.880	37.350	38.517	14.473	32.183	30.614
M4	15.184	33.294	34.251	17.733	37.649	40.628	14.508	32.374	30.169
M5	15.093	33.312	33.834	17.523	37.698	39.327	14.480	32.603	30.367
Mp	11.555	23.861	24.558	14.817	30.456	32.072	10.439	21.863	21.568