Deep non-crossing probabilistic wind speed forecasting with multi-scale features

•A hybrid deep model is proposed for probabilistic wind speed forecasting.•A multi-scale feature extraction module is designed to extract sufficient features.•A non-crossing quantile loss is constructed to solve the crossing problem.•Kernel density estimation is used to obtain continuous probability...

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Bibliographic Details
Published in:Energy conversion and management 2022-04, Vol.257, p.115433, Article 115433
Main Authors: Zou, Runmin, Song, Mengmeng, Wang, Yun, Wang, Ji, Yang, Kaifeng, Affenzeller, Michael
Format: Article
Language:English
Subjects:
Artificial neural networks
Attention mechanism
Clean energy
Computer applications
Continuity (mathematics)
Deep learning
Distribution functions
Energy
Feature extraction
Forecasting
Information processing
Long short-term memory
Machine learning
Multi-scale features
Multilayers
Neural networks
Non-crossing quantile loss
Probabilistic wind speed forecasting
Probability distribution
Probability distribution functions
Probability theory
Quantiles
Statistical analysis
Wind power
Wind speed
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Summary:•A hybrid deep model is proposed for probabilistic wind speed forecasting.•A multi-scale feature extraction module is designed to extract sufficient features.•A non-crossing quantile loss is constructed to solve the crossing problem.•Kernel density estimation is used to obtain continuous probability distributions.•The performance of the proposed model is tested and discussed on four datasets. Clean and renewable wind energy has made an outstanding contribution to alleviating the energy crisis. However, the randomness and volatility of wind brings great risk to the integration of wind power to the grid. Therefore, it is essential to obtain reliable and efficient wind speed forecasts. Quantile-based machine learning techniques, which usually produce satisfied quantile-based prediction intervals (PIs) for wind energy, have received widespread attention. However, the obtained PIs are usually crossed and violate the monotonicity of different conditional quantiles. In addition, the completeness and quality of features directly affect the forecasting performance of the models. Therefore, mining effective and sufficient information from the limited input data helps to improve the forecasting performance. In this paper, a novel method is developed for probabilistic wind speed forecasting based on deep learning, non-crossing quantile loss, multi-scale feature (MSF) extraction, and kernel density estimation (KDE). In terms of feature extraction, sufficient MSFs with simple pattern will be extracted based on a multi-layer convolutional neural network. Attention-based long short-term memory is used to further extract and encode temporal information for features of each scale and reduce computational cost. The final feature is obtained by concatenating all the encoded feature vectors. Instead of directly outputting different conditional quantiles, this study obtains the positive difference of adjacent conditional quantiles. On this basis, a non-crossing quantile loss is designed to ensure the monotonicity of different conditional quantiles. To understand the forecasting uncertainty comprehensively, KDE is used to estimate the continuous probability distribution function for various PIs. The proposed method is verified on four wind speed datasets collected form South Dakota. The results demonstrate that the proposed method has an excellent ability of generating high-quality, high-precision, and non-crossing probabilistic wind speed forecasts.
ISSN:0196-8904
1879-2227
DOI:10.1016/j.enconman.2022.115433