Your search keyword '"Sehnke, Frank"' showing total 3 results

1. Probabilistic short term wind power forecasts using deep neural networks with discrete target classes.

Author

Felder, Martin, Sehnke, Frank, Ohnmeiß, Kay, Schröder, Leon, Junk, Constantin, and Kaifel, Anton

Subjects

ARTIFICIAL neural networks, MACHINE learning, WIND power, ARTIFICIAL intelligence, CLIMATOLOGY

Abstract

Usually, neural networks trained on historical feed-in time series of wind turbines deterministically predict power output over the next hours to days. Here, the training goal is to minimise a scalar cost function, often the root mean square error (RMSE) between network output and target values. Yet similar to the analog ensemble (AnEn) method, the training algorithm can also be adapted to analyse the uncertainty of the power output from the spread of possible targets found in the historical data for a certain meteorological situation. In this study, the uncertainty estimate is achieved by discretising the continuous time series of power targets into several bins (classes). For each forecast horizon, a neural network then predicts the probability of power output falling into each of the bins, resulting in an empirical probability distribution. Similiar to the AnEn method, the proposed method avoids the use of costly numerical weather prediction (NWP) ensemble runs, although a selection of several deterministic NWP forecasts as input is helpful. Using state-of-the-art deep learning technology, we applied our method to a large region and a single wind farm. MAE scores of the 50-percentile were on par with or better than comparable deterministic forecasts. The corresponding Continuous Ranked Probability Score (CRPS) was even lower. Future work will investigate the overdispersiveness sometimes observed, and extend the method to solar power forecasts. [ABSTRACT FROM AUTHOR]

Published

2018

2. Machine Learning Approach for Probabilistic Wind Power Forecasts with Discrete Probability Density Function.

Author

Kaifel, Anton, Felder, Martin, Sehnke, Frank, Ohnmeiß, Kay, and Schröder, Leon

Subjects

WIND power, WIND forecasting, PROBABILITY density function, ARTIFICIAL neural networks, WIND turbine efficiency

Abstract

Neural networks trained on historical feed-in time series of wind turbines or parks are able to deterministically predict power over the next hours to days, by minimizing a scalar cost function on a training data set. Yet similar to the analog ensemble method, the training algorithm can also be adapted to analyze the uncertainty of the power output from the spread of possible targets found in the historical data for a certain meteorological situation. For this new approach of probabilistic forecasts, the uncertainty estimate is achieved by discretizing the continuous time series of power targets into probability density functions (PDF). For each forecast horizon, a deep neural network then predicts the PDF of power output. The resulting empirical probability distribution can then be analyzed to determine percentiles or statistical moments. The advantage of the proposed method is that it avoids the use of costly numerical weather prediction (NWP) ensemble runs. Although a selection of several deterministic NWP forecasts as input can be used. We demonstrate the application of this new method in case studies for a German wind power feed-in as well as a wind farm in Germany and Chile using state-of-the-art deep learning technology. [ABSTRACT FROM AUTHOR]

Published

2018

3. Probabilistic short term wind power forecasts with using Deep Neural Networks with discrete target classes.

Author

Felder, Martin, Sehnke, Frank, Ohnmeiß, Kay, Schröder, Leon, Junk, Constantin, and Kaifel, Anton

Subjects

*WIND forecasting, *WIND power, *TERMS & phrases

Published

2018