Abstract
In the past two decades, wind energy has been under fast development worldwide. The dramatic increase of wind power penetration in electricity production has posed a big challenge to grid integration due to the high uncertainty of wind power. Accurate real-time forecasts of wind farm power outputs can help to mitigate the problem. Among the various techniques developed for wind power forecasting, the hybridization of numerical weather prediction (NWP) and machine learning (ML) techniques such as artificial neural networks (ANNs) are attracting many researchers world-wide nowadays, because it has the potential to yield more accurate forecasts. In this paper, two hybrid NWP and ANN models for wind power forecasting over a highly complex terrain are proposed. The developed models have a fine temporal resolution and a sufficiently large prediction horizon (>6 h ahead). Model 1 directly forecasts the energy production of each wind turbine. Model 2 forecasts first the wind speed, then converts it to the power using a fitted power curve. Effects of various modeling options (selection of inputs, network structures, etc.) on the model performance are investigated. Performances of different models are evaluated based on four normalized error measures. Statistical results of model predictions are presented with discussions. Python was utilized for task automation and machine learning. The end result is a fully working library for wind power predictions and a set of tools for running the models in forecast mode. It is shown that the proposed models are able to yield accurate wind farm power forecasts at a site with high terrain and flow complexities. Especially, for Model 2, the normalized Mean Absolute Error and Root Mean Squared Error are obtained as 8.76% and 13.03%, respectively, lower than the errors reported by other models in the same category.
Highlights
Renewable energy is promoted worldwide as the core technology for the mitigation of climate change, which is one of the global challenges faced by humanity
This paper presents two hybrid numerical weather prediction (NWP) and artificial neural networks (ANNs) models for wind power forecasting over a highly complex terrain
It is visible in both panels that the measured data, whether it is wind power or wind speed has high frequency and low amplitude fluctuations that are hardly followed by the predictions
Summary
Renewable energy is promoted worldwide as the core technology for the mitigation of climate change, which is one of the global challenges faced by humanity. The dramatic increase of wind power penetration in electricity production has posed some new challenges to grid integration due to the intermittent and non-schedulable nature of wind power: it varies with weather conditions, and is not always available when electricity is needed. Accurate real-time wind power forecasting can help to mitigate the problem, especially to reduce the integration cost [1]. The applications of forecasts targeted at various time scales include wind turbine regulation and control (0–30 min), load dispatch planning (30 min–6 h), reducing the imbalance penalties for wind farm operators and determining the reserve capacity to ensure grid stability (6 h–1 day ahead), and maintenance scheduling and wind farm designing (>1 day ahead) [2]. Overall, forecasting plays an important role in the integration of renewables into a sustainable and resilient energy system
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