Wind power generation via ground wind station and topographical feedforward neural network (T-FFNN) model for small-scale applications

This study presents the potential of harvesting wind energy in Sarawak, Malaysia based on the ground station and prediction models. A topographical feedforward neural network (T-FFNN) is proposed as an alternative to predict the wind speed in the areas where wind speed measurements are not done. The...

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Bibliographic Details
Main Authors: Salisu Muhammad, Lawan, Wan Azlan, Wan Zaina Abidinl, Thelaha, Bin Hj Masri, Chai, Wangyin, Baharun, Azhaili
Format: E-Article
Language:English
Published: Elsevier Ltd 2017
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Online Access:http://ir.unimas.my/id/eprint/14963/1/Wind-power-generation-via-ground-wind-station-and-topographical-feedforward-neural-network-%28T-FFNN%29-model-for-small-scale-applications_2017_Journal-of-Cleaner-Production.html
http://ir.unimas.my/id/eprint/14963/
http://www.sciencedirect.com/science/article/pii/S0959652616320194
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Institution: Universiti Malaysia Sarawak
Language: English
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Summary:This study presents the potential of harvesting wind energy in Sarawak, Malaysia based on the ground station and prediction models. A topographical feedforward neural network (T-FFNN) is proposed as an alternative to predict the wind speed in the areas where wind speed measurements are not done. The model has nine meteorological, geographical and topographical parameters as inputs while monthly winds speed as an output variable. The suitability of the model was assessed based on the mean absolute percentage error (MAPE). The most effective network design with lowest MAPE of 3.4% and correlation R between the predicted and the ground station wind speed of 0.91 was obtained. The study shows the characteristics of wind speed at 10–40 m heights. For the wind speed distribution, in addition to the widely applied Weibull and Rayleigh models, Gamma, Erlang and Lognormal are included. It was found that Gamma and Weibull outperform the others based on the three goodness-of-fit (GOF). An assessment of wind energy potential was performed using the measured and predicted wind speed data. The outcomes show that wind power density falls within class 1 (PD≤100 W/m2). Final results from micro-sitting investigating the performance of annual energy output (AEO) in the examined area are presented. The results indicate that the AEO differs with altitudes. In all the examined areas, the AEO values varied from about 5800–13,622 kWh/year. These results show the possibility of using wind energy for small-scale purpose.