Abstract
A probabilistic machine learning method is applied to icing related production loss forecasts for wind energy in cold climates. The employed method, called quantile regression forests, is based on the random forest regression algorithm. Based on the performed tests on data from four Swedish wind parks available for two winter seasons, it has been shown to produce valuable probabilistic forecasts. Even with the limited amount of training and test data that were used in the study, the estimated forecast uncertainty adds more value to the forecast when compared to a deterministic forecast and a previously published probabilistic forecast method. It is also shown that the output from a physical icing model provides useful information to the machine learning method, as its usage results in an increased forecast skill when compared to only using Numerical Weather Prediction data. A potential additional benefit in machine learning for some stations was also found when using information in the training from other stations that are also affected by icing. This increases the amount of data, which is otherwise a challenge when developing forecasting methods for wind energy in cold climates.
Highlights
Wind energy production in cold climates has grown exponentially during the last decades and it is expected to continue to increase, owing to the good wind resources and low population density
The results are divided into three sections: Section 4.1 presents the possible benefit of adding the icing model to the modelling chain while using the basic random forest regression method, Section 4.2 presents the deterministic forecast performance while using the probabilistic quantile regression forest (QRF) model, and Section 4.3 depicts the probabilistic forecast performance
The main evaluation metric used throughout the study is root mean square error (RMSE) of the forecasted power production loss in Megawatt (MW)
Summary
Wind energy production in cold climates has grown exponentially during the last decades and it is expected to continue to increase, owing to the good wind resources and low population density. Ice increases the load, changes the aerodynamics of the blades, and generates vibrations, which, during severe icing events, can shorten the lifetime of the turbine if it is not shut down [2]. During these occasions, it is important for energy companies to forecast icing related power production losses in order to avoid increased trading costs in addition to production loss costs and keep the power grid stable. IEA Wind Task 19 [3]
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