Very Short-Term Solar Power Forecasting Using a Frequency Incorporated Deep Learning Model

IF 3.3 Q3 ENERGY & FUELS
Hossein Panamtash;Shahrzad Mahdavi;Qun Zhou Sun;Guo-Jun Qi;Hongrui Liu;Aleksandar Dimitrovski
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引用次数: 0

Abstract

This paper aims to forecast solar power in very short horizons to assist in real-time distribution system operations. Popular machine learning methods for time series forecasting are studied, including recurrent neural networks with Long Short-Term Memory (LSTM). Although LSTM networks perform well in different applications by accounting for long-term dependencies, they do not consider the frequency domain patterns, especially the low frequencies in the solar power data compared to the sampling frequency. The State Frequency Memory (SFM) model in this paper extends LSTM and adds multi-frequency components into memory states to reveal a variety of frequency patterns from the data streams. To further improve the forecasting performance, the idea of Fourier Transform is integrated for optimal selection of the frequency bands by identifying the most dominant frequencies in solar power output. The results show that although the SFM model with uniform frequency selection does not significantly improve upon the LSTM model, the proper selection of frequencies yields overall better performances than the LSTM and 27% better than the persistent forecasts for forecast horizons up to one minute. Furthermore, a predictive voltage control based on solar forecasts is implemented to demonstrate the superior performance of the proposed model.
使用频率融合深度学习模型的极短期太阳能预测
本文的目的是在很短的时间内预测太阳能发电,以协助实时配电系统的运行。研究了用于时间序列预测的常用机器学习方法,包括具有长短期记忆(LSTM)的循环神经网络。尽管LSTM网络通过考虑长期依赖关系在不同的应用中表现良好,但它们没有考虑频域模式,特别是与采样频率相比太阳能数据中的低频。本文提出的状态-频率记忆(SFM)模型对LSTM进行了扩展,在记忆状态中加入了多频率分量,从而揭示了数据流中的各种频率模式。为了进一步提高预测性能,结合傅里叶变换的思想,通过识别太阳能输出中最优的频率来优化选择频段。结果表明,虽然均匀频率选择的SFM模型对LSTM模型没有显著的改进,但适当的频率选择总体上优于LSTM模型,在1分钟以内的预测范围内比持续预测好27%。此外,基于太阳能预测的电压预测控制也验证了该模型的优越性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.80
自引率
5.30%
发文量
45
审稿时长
10 weeks
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