DocumentCode
836869
Title
Long-term wind speed and power forecasting using local recurrent neural network models
Author
Barbounis, Thanasis G. ; Theocharis, John B. ; Alexiadis, Minas C. ; Dokopoulos, Petros S.
Author_Institution
Electr. & Comput. Eng. Dept., Aristotle Univ. of Thessaloniki, Greece
Volume
21
Issue
1
fYear
2006
fDate
3/1/2006 12:00:00 AM
Firstpage
273
Lastpage
284
Abstract
This paper deals with the problem of long-term wind speed and power forecasting based on meteorological information. Hourly forecasts up to 72-h ahead are produced for a wind park on the Greek island of Crete. As inputs our models use the numerical forecasts of wind speed and direction provided by atmospheric modeling system SKIRON for four nearby positions up to 30 km away from the wind turbine cluster. Three types of local recurrent neural networks are employed as forecasting models, namely, the infinite impulse response multilayer perceptron (IIR-MLP), the local activation feedback multilayer network (LAF-MLN), and the diagonal recurrent neural network (RNN). These networks contain internal feedback paths, with the neuron connections implemented by means of IIR synaptic filters. Two novel and optimal on-line learning schemes are suggested for the update of the recurrent network´s weights based on the recursive prediction error algorithm. The methods assure continuous stability of the network during the learning phase and exhibit improved performance compared to the conventional dynamic back propagation. Extensive experimentation is carried out where the three recurrent networks are additionally compared to two static models, a finite-impulse response NN (FIR-NN) and a conventional static-MLP network. Simulation results demonstrate that the recurrent models, trained by the suggested methods, outperform the static ones while they exhibit significant improvement over the persistent method.
Keywords
FIR filters; IIR filters; load forecasting; multilayer perceptrons; power engineering computing; recurrent neural nets; wind turbines; atmospheric modeling system; diagonal recurrent neural network; infinite impulse response multilayer perceptron; local activation feedback multilayer network; local recurrent neural network models; long-term wind speed numerical forecasting; meteorological information; optimal online learning schemes; power forecasting; recursive prediction error algorithm; turbine cluster; wind park; Atmospheric modeling; IIR filters; Meteorology; Neurofeedback; Numerical models; Predictive models; Recurrent neural networks; Weather forecasting; Wind forecasting; Wind speed; Local recurrent neural networks; long-term wind power forecasting; nonlinear recursive least square learning; real time learning;
fLanguage
English
Journal_Title
Energy Conversion, IEEE Transactions on
Publisher
ieee
ISSN
0885-8969
Type
jour
DOI
10.1109/TEC.2005.847954
Filename
1597347
Link To Document