Day-ahead photovoltaic power generation forecasting with the HWGC-WPD-LSTM hybrid model assisted by wavelet packet decomposition and improved similar day method

IF 5.1 2区工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY Engineering Science and Technology-An International Journal-Jestech Pub Date : 2024-11-30 DOI:10.1016/j.jestch.2024.101889

Ruxue Bai , Jinsong Li , Jinsong Liu , Yuetao Shi , Suoying He , Wei Wei

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引用次数: 0

Abstract

Precisely forecasting output of solar photovoltaics is crucial for (i) effective solar power management, (ii) integration into the electrical grid, (iii) flexible allocation of power resources. While deep learning algorithms have shown promise in energy applications, single algorithms often struggle with unstable predictions and limited generalizability for predicting photovoltaic (PV) output. This study introduces an innovative hybrid model (HWGC-WPD-LSTM) that integrates an improved similar day algorithm (WGC: weighted grey correlation analysis and cosine similarity), Wavelet Packet Decomposition (WPD), and Long Short-Term Memory neural network (LSTM) for predicting day-ahead power output. The model suggests an approach to identifying similar days by integrating weighted GRA with cosine similarity. It then decomposes power sequences employing WPD to capture various frequency characteristics. Four independent LSTM networks are then applied to these sub-sequences to forecast output, which are then reconstructed to derive the ultimate forecast outcome for solar photovoltaics. The evaluation of the hybrid model is conducted based on data gathered from actual generating station in Shandong Province, China. Then it is compared against other models utilizing similar day selection methods and other hybrid HWGC-BP, HWGC-Elman, HWGC-SVM, HWGC-RF, and HWGC-LSTM models. This comparison is based on four performance metrics: Mean Absolute Error (MAE), Root Mean Square Error (RMSE), normalized Root Mean Square Error (NRMSE), and Mean Absolute Deviation (MAD). Results demonstrate that the HWGC-WPD-LSTM model offers enhanced precision and stability (MAE = 0.2168 MW, RMSE = 0.2996 MW, NRMSE = 6.78 %, MAD = 2.18 %) in day-ahead power generation predictions. This highlights the potency of the hybrid model in enhancing the forecasting capabilities for solar photovoltaics, which is crucial for the strategic enhancement of renewable energy resource exploitation in the context of modern power systems.

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基于小波包分解和改进相似日法的HWGC-WPD-LSTM混合模型日前光伏发电预测

准确预测太阳能光伏发电的输出对于(1)有效的太阳能管理，(2)并入电网，(3)灵活分配电力资源至关重要。虽然深度学习算法在能源应用中显示出前景，但单一算法在预测光伏（PV）输出时往往存在不稳定的预测和有限的通用性。本研究引入了一种创新的混合模型（HWGC-WPD-LSTM），该模型集成了改进的相似日算法（WGC：加权灰色关联分析和余弦相似度）、小波包分解（WPD）和长短期记忆神经网络（LSTM），用于预测前一天的功率输出。该模型提出了一种通过将加权GRA与余弦相似度相结合来识别相似天数的方法。然后利用WPD分解功率序列以捕获各种频率特性。然后将四个独立的LSTM网络应用于这些子序列来预测输出，然后对这些子序列进行重建，从而得出太阳能光伏发电的最终预测结果。根据山东省实际电站的数据，对混合模型进行了评价。然后与其他使用相似日选择方法的模型和其他混合HWGC-BP、HWGC-Elman、HWGC-SVM、HWGC-RF和HWGC-LSTM模型进行比较。这种比较基于四个性能指标：平均绝对误差（MAE）、均方根误差（RMSE）、标准化均方根误差（NRMSE）和平均绝对偏差（MAD）。结果表明，HWGC-WPD-LSTM模型在日前发电预测中具有较高的精度和稳定性（MAE = 0.2168 MW, RMSE = 0.2996 MW, NRMSE = 6.78%, MAD = 2.18%）。这突出了混合模型在提高太阳能光伏发电预测能力方面的效力，这对于在现代电力系统的背景下战略性地加强可再生能源的开发至关重要。

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来源期刊

Engineering Science and Technology-An International Journal-Jestech Materials Science-Electronic, Optical and Magnetic Materials

CiteScore

11.20

自引率

3.50%

发文量

153

审稿时长

22 days

期刊介绍： Engineering Science and Technology, an International Journal (JESTECH) (formerly Technology), a peer-reviewed quarterly engineering journal, publishes both theoretical and experimental high quality papers of permanent interest, not previously published in journals, in the field of engineering and applied science which aims to promote the theory and practice of technology and engineering. In addition to peer-reviewed original research papers, the Editorial Board welcomes original research reports, state-of-the-art reviews and communications in the broadly defined field of engineering science and technology. The scope of JESTECH includes a wide spectrum of subjects including: -Electrical/Electronics and Computer Engineering (Biomedical Engineering and Instrumentation; Coding, Cryptography, and Information Protection; Communications, Networks, Mobile Computing and Distributed Systems; Compilers and Operating Systems; Computer Architecture, Parallel Processing, and Dependability; Computer Vision and Robotics; Control Theory; Electromagnetic Waves, Microwave Techniques and Antennas; Embedded Systems; Integrated Circuits, VLSI Design, Testing, and CAD; Microelectromechanical Systems; Microelectronics, and Electronic Devices and Circuits; Power, Energy and Energy Conversion Systems; Signal, Image, and Speech Processing) -Mechanical and Civil Engineering (Automotive Technologies; Biomechanics; Construction Materials; Design and Manufacturing; Dynamics and Control; Energy Generation, Utilization, Conversion, and Storage; Fluid Mechanics and Hydraulics; Heat and Mass Transfer; Micro-Nano Sciences; Renewable and Sustainable Energy Technologies; Robotics and Mechatronics; Solid Mechanics and Structure; Thermal Sciences) -Metallurgical and Materials Engineering (Advanced Materials Science; Biomaterials; Ceramic and Inorgnanic Materials; Electronic-Magnetic Materials; Energy and Environment; Materials Characterizastion; Metallurgy; Polymers and Nanocomposites)