Abstract
Ultra-short-term wind speed prediction can assist the operation and scheduling of wind turbines in the short term and further reduce the adverse effects of wind power integration. However, as wind is irregular, nonlinear, and nonstationary, to accurately predict wind speed is a difficult task. To this end, researchers have made many attempts; however, they often use only point forecasting or interval forecasting, resulting in imperfect prediction results. Therefore, in this paper, we developed a prediction system integrating an advanced data preprocessing strategy, a novel optimization model, and multiple prediction algorithms. This combined forecasting system can overcome the inherent disadvantages of the traditional forecasting methods and further improve the prediction performance. To test the effectiveness of the forecasting system, the 10-min and one-hour wind speed sequences from the Sotavento wind farm in Spain were applied for conducting comparison experiments. The results of both the interval forecasting and point forecasting indicated that, in terms of the forecasting capability and stability, the proposed system was better than the compared models. Therefore, because of the minimum prediction error and excellent generalization ability, we consider this forecasting system to be an effective tool to assist smart grid programming.
Highlights
Along with the rapid development of modern industry, the issues of environmental deterioration and fossil fuel depletion are becoming increasingly serious
Different from the recombination idea of the denoising layer number based on subjective judgment, each subsequence obtained though decomposition was weighted and reconstructed to eliminate the adverse influence of high frequency noise. e results of experiment II show that the combination system based on Weight Adaptive Combined Denoising (WACD) was always better than the other preprocessing technologies, which indicates that the idea of adaptive combination reconstruction of weight has great potential in the future
(1) In contrast to the recombination idea of the denoising layer number based on subjective judgment, each subsequence obtained though decomposition was weighted and reconstructed to eliminate the adverse influence of high frequency noise
Summary
Along with the rapid development of modern industry, the issues of environmental deterioration and fossil fuel depletion are becoming increasingly serious. Seeking clean and renewable energy is a hotspot topic in the world. The scale of wind power generation is growing rapidly and wind energy has attracted attention [1]. When wind power is connected to the grid, the intermittence and volatility of wind power will affect the balance of power demand and supply, the security of the power system, and the power quality. Erefore, in order to ensure the stability of the wind power system and promote the large-scale integration of wind power, it is necessary to predict the short-term wind power with high accuracy [2]. For obtaining more accurate prediction results, a great deal of efforts has been made and many studies have been performed. On the basis of applied data processing models, we summarized the previous research into four classes: (a) physical class, (b) statistical class, (c) spatial correlation class, and (d) artificial intelligence class [3]
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