风力发电
风电预测
唤醒
稳健性(进化)
计算机科学
地形
风速
模式(计算机接口)
人工神经网络
预处理器
深度学习
数据预处理
启发式
可再生能源
气象学
数值天气预报
模拟
功率(物理)
人工智能
能量(信号处理)
数据建模
工程类
电
天气预报
多层感知器
动态模态分解
作者
Antonio J. Romero-Barrera,Ana E. Sipols,Alvaro Paricio‐Garcia,Miguel A. López-Carmona
标识
DOI:10.1016/j.enconman.2025.120738
摘要
This work presents a robust hybrid framework for short-term wind power forecasting, validated on the GECAMA wind farm in Spain, which comprises 69 turbines and has a nominal capacity exceeding 300 MW. The proposed approach combines three established physics-based wake models (Jensen, Bastankhah, Larsen) with five deep learning methods, further enhanced by input preprocessing via variational mode decomposition. Hourly energy production is forecasted using wind data from ECMWF, AROME, and ICON EU meteorological databases. Including wake models as input features helps reduce bias from meteorological signals by accounting for available wind turbines and physical effects, such as wake interactions and terrain. Adding previous forecast errors as features further boosts short-term accuracy. The hybrid models achieve error reductions of 40%–50% for one-hour-ahead forecasts, tapering to 1%–10% by 24 h. With variational mode decomposition (VMD), improvements reach 74%–77% for 3–6 h horizons and about 8% at 36 h. Across all horizons, VMD-enhanced models consistently outperform both standard hybrids and pure physical models. These results show that integrating wake modeling, deep learning, and advanced preprocessing is a practical way to improve wind power forecasts and support reliable electricity market decisions. • Hybrid wake–deep learning model enhances short-term wind power forecasts. • Integrates physics-based wake effects with DL models and VMD preprocessing. • Achieves up to 77% accuracy gain over traditional physical-only approaches. • Validated on Spain’s largest wind farm, improving robustness under terrain effects.
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