Abstract
Wind Power Ramp Events (WPREs) are large fluctuations of wind power in a short time interval, which lead to strong, undesirable variations in the electric power produced by a wind farm. Its accurate prediction is important in the effort of efficiently integrating wind energy in the electric system, without affecting considerably its stability, robustness and resilience. In this paper, we tackle the problem of predicting WPREs by applying Machine Learning (ML) regression techniques. Our approach consists of using variables from atmospheric reanalysis data as predictive inputs for the learning machine, which opens the possibility of hybridizing numerical-physical weather models with ML techniques for WPREs prediction in real systems. Specifically, we have explored the feasibility of a number of state-of-the-art ML regression techniques, such as support vector regression, artificial neural networks (multi-layer perceptrons and extreme learning machines) and Gaussian processes to solve the problem. Furthermore, the ERA-Interim reanalysis from the European Center for Medium-Range Weather Forecasts is the one used in this paper because of its accuracy and high resolution (in both spatial and temporal domains). Aiming at validating the feasibility of our predicting approach, we have carried out an extensive experimental work using real data from three wind farms in Spain, discussing the performance of the different ML regression tested in this wind power ramp event prediction problem.
Highlights
The purpose in this case is modeling the “wind ramp function” (St ) as accurately as possible in terms of several input variables. Note that this way of facing the problem overcomes some problems associated with Wind Power Ramp Events (WPREs) defined as a binary classification task [43,44] or even ordinal classification [73]; for example, the appearance of highly imbalanced problems or the necessity of a threshold in S for defining the appearance of a wind ramp
We have explored the feasibility of a novel hybrid approach that—by combining data from numerical-physical models and state-of-the-art statistical Machine Learning (ML) regressors—aims at predicting Wind Power Ramp Events (WPREs)
We have proposed the use of data from the ERA-Interim reanalysis because it ensures a high resolution of the inputs, both spatial and temporal
Summary
Energies 2017, 10, 1784 the efficient integration [15] of an increasing number of wind energy generators in both the distribution and transmission power grids, which are becoming increasingly complex [16,17] Such an intrinsically complex nature of power grids is further increased because of the inherent stochastic nature of wind energy [18] that, depending on the weather conditions, can lead to intermittent generation [18]. This can affect the stability, robustness and resilience [16,17] of electric power grids. A useful discussion of the technical differences between these interrelated, but distinct concepts can be found in [17]
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