计算机科学
太阳能
稳健性(进化)
光伏系统
过度拟合
数值天气预报
模式
网格
数据挖掘
人工智能
功率(物理)
气象学
工程类
社会科学
物理
量子力学
社会学
电气工程
生物化学
化学
几何学
数学
人工神经网络
基因
作者
Ziqing Ma,Wenwei Wang,Tian Zhou,Chao Chen,Bingqing Peng,Liang Sun,Rong Jin
标识
DOI:10.1145/3637528.3671509
摘要
Accurate solar power forecasting is crucial to integrate photovoltaic plants into the electric grid, schedule and secure the power grid safety. This problem becomes more demanding for those newly installed solar plants which lack sufficient operational data. Current research predominantly relies on historical solar power data or numerical weather prediction in a single-modality format, ignoring the complementary information provided in different modalities. In this paper, we propose a multi-modality fusion framework to integrate historical power data, numerical weather prediction, and satellite images, significantly improving forecast performance. We introduce a vector quantized framework that aligns modalities with varying information densities, striking a balance between integrating sufficient information and averting model overfitting. Our framework demonstrates strong zero-shot forecasting capability, which is especially useful for those newly installed plants. Moreover, we collect and release a multi-modal solar power (MMSP) dataset from real-world plants to further promote the research of multi-modal solar forecasting algorithms. Our extensive experiments show that our model not only operates with robustness but also boosts accuracy in both zero-shot forecasting and scenarios rich with training data, surpassing leading models. We have incorporated it into our eForecaster platform and deployed it for more than 300 solar plants with a total capacity of over 15GW. Our code and dataset are accessible at https://github.com/DAMO-DI-ML/FusionSF.git.
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