Araştırma Makalesi
BibTex RIS Kaynak Göster
Yıl 2021, Cilt: 34 Sayı: 4, 1128 - 1143, 01.12.2021
https://doi.org/10.35378/gujs.795265

Öz

Kaynakça

  • Sahin, A.D.A.: Review of Research and Development of Wind Energy in Turkey, Clean-Soil, Air, Water. 36; 734-742 (2008)
  • Babu, S , Loganathan, A , Vaıravasundaram, I .: Optimizing Electrical Generators of Wind Energy Conversion System for Efficient Power Extraction . Gazi University Journal of Science , 31 (4) , 1141-1154 (2018)
  • Wind Energy potential in Europe. https://windeurope.org/ (2020). Access Date: 14 September 2020
  • Mutlu Ö. Akpınar S. E. ve Balıkçı A.: Power Quality Analysis of Wind Farm Connected to Alaçatı Substation in Turkey. Renewable Energy. 34(5): 1312-1318 (2009)
  • Jaramillo O. A. Borja M. A.: Wind speed analysis in La Ventosa, Mexico: a bimodal probability distribution case. Renewable Energy 29, 1613-1630 (2004)
  • Incecik S, and Erdogmus F.: An Investigation of the Wind Power Potential on the Western Coast of Anatolia. Renewable Energy 6; 863-865 (1995)
  • Kose R, Ozgur MA, Erbas O, and Tugcu, A.: The Analysis of Wind Data and Wind Energy Potential in Kutahya, Turkey. Renewable and Sustainable Energy Reviews 8;277-288 (2004)
  • Akpınar E.K, and Akpınar S.: Determination of the Wind Energy Potential for Maden-Elazig, Turkey. Energy Conversion and Management 45; 2901-2914 (2004)
  • Dorvlo A. S. Estimating wind speed distribution. Energy Conversion and Management 43(17), 2311-2318 (2002)
  • Efe-eyefıa, E , Thomas, J , Zelıbe, S .: Theoretical Analysis of the Weibull Alpha Power Inverted Exponential Distribution: Properties and Applications . Gazi University Journal of Science , 33 (1) , 265-277 (2020)
  • Carta J. A. Ramirez P. Bueno C.: A joint probability density function of wind speed and direction for wind energy analysis. Energy Conversion and Management. 49(6), 1309-1320 (2008)
  • Shu Z. R. Li Q. S. Chan P. W.: Investigation of offshore wind energy potential in Hong Kong based on Weibull distribution function. Applied Energy. 156, 362-373 (2015)
  • Usta I.: An innovative estimation method regarding Weibull parameters for wind energy applications. Energy. 106, 301-314 (2016)
  • Mohammadi K. Alavi O. Mostafaeipour A. Goudarzi N. Jalilvand, M.: Assessing different parameters estimation methods of Weibull distribution to compute wind power density. Energy Conversion and Management. 108, 322-335 (2016)
  • Ramírez P. Carta J. A.: Influence of the data sampling interval in the estimation of the parameters of the Weibull wind speed probability density distribution: a case study. Energy Conversion and Management. 46(15-16), 2419-2438 (2005)
  • Akdağ S. A. Dinler A.: A new method to estimate Weibull parameters for wind energy applications. Energy conversion and management. 50(7), 1761-1766 (2009)
  • Yu C. Li Y. Bao Y. Tang H. Zhai G.: A novel framework for wind speed prediction based on recurrent neural networks and support vector machine. Energy Conversion and Management.178, 137-145 (2018)
  • Cliff, W. C., The Effect of generalized wind characteristics on annual power estimates from wind turbine generators, PNL-2436, Richland, Washington: Battele Pacific Northwest Laboratory (1977)
  • Çelik A. N., A Statistical analysis of wind power density based on the Weibull and Rayleigh models at Southern Region of Turkey. Renewable Energy. 29, 593-604 (2004)
  • Chang T. P.: Performance comparison of six numerical methods in estimating Weibull parameters for wind energy application. Apply Energy. 88, 272-282 (2011)
  • Erdem, O , Kesen, S .:Estimation of Turkey’s Natural Gas Consumption by Machine Learning Techniques. Gazi University Journal of Science, 33 (1), 120-133 (2020)
  • Rumelhart, D. E., Hinton, G. E., Williams, R. J.: Learning representations by back-propagating errors. nature, 323(6088), 533-536 (1986)
  • Reikard, G.: Regime‐switching models and multiple causal factors in forecasting wind speed. Wind Energy. 13(5), 407-.418 (2010)
  • Ballireddy, T. R. R., Modi, P. K.: Reliability evaluation of power system incorporating wind farm for generation expansion planning based on ANLSA approach. Wind Energy. 22(7), 975-991 (2019)
  • Meenakshi, S., Venkatachalam, V.: FUDT: a fuzzy uncertain decision tree algorithm for classification of uncertain data. Arabian Journal for Science and Engineering. 40(11), 3187-3196 (2015)
  • Ellis, N., Davy, R., & Troccoli, A.: Predicting wind power variability events using different statistical methods driven by regional atmospheric model output. Wind Energy. 18(9), 1611-1628 (2015)
  • Ayaz, Y. Kocamaz, A.F. Karakoç, M.B.: Modelling of compressive strength and UPV of high-volume mineral-admixtured concrete using rule-based M5 rule and tree model M5P classifiers. Constr. Build. Mater. 94, pp. 235-240 (2015)
  • Behnood, A., Behnood, V., Gharehveran, M.M, Alyamac, K.E.: Prediction of the compressive strength of normal and high-performance concretes using M5P model tree algorithm. Construction and Building Materials. 142, 199-207 (2017)
  • Alic, E. Das, M. Kaska, O.: Heat Flux Estimation at Pool Boiling Processes with Computational Intelligence Methods,” Processes. 7(5), 293 (2019)
  • Aggarwal, G., Sabharwal, S., Nagpal, S.: Theoretical and Empirical Validation of Coupling Metrics for Object-Oriented Data Warehouse Design. Arabian Journal for Science and Engineering. 43(2), 675-691 (2018)
  • Wang Y, Witten IH.: Induction of model trees for predicting continuous classes, in: Proc of the Poster Papers of the European Conference on Machine Learning. University of Economics, Faculty of Informatics and Statistics, Prague, (1997)
  • Hourly wind speed data. https://www.mgm.gov.tr/ (2020) Access Date: 14 September 2020
  • Quinlan JR.: Learning with continuous classes, in: Proceedings of the Australian Joint Conference on Artificial Intelligence, World Scientific, Singapore (1992)
  • Zameer A, Khan A, and Javed SG.: Machine Learning based short-term wind power prediction using a hybrid learning model. Computers & Electrical Engineering. 45;122-133 (2015)
  • Petkovic D, Shamshirband S, Anuar NB, Saboohi H, Wahab AWA, Protic M, et al. An appraisal of wind speed distribution prediction by soft computing methodologies: a comparative study. Energy conversion and Management. 84;133-139 (2014)
  • Liu H, Tian HQ, and Li YF.: Four wind speed multi-step forecasting models using extreme learning machines and signal decomposing algorithms. Energy conversion and management. 100, 16-22 (2015)
  • Yuan, X., Chen, C., Yuan, Y., Huang, Y., Tan, Q.: Short-term wind power prediction based on LSSVM–GSA model. Energy Conversion and Management. 101;393-401(2015)
  • Yesilbudak M, Sagiroglu S, and Colak I.: A novel implementation of kNN classifier based on multi-tupled meteorological input data for wind power prediction. Energy Conversion and Management. 135;434-444 (2017)
  • Ouyang T, Zha X, and Qin L.: A combined multivariate model for wind power prediction. Energy Conversion and Management. 144;361-373 (2017)
  • Yuan X, Tan Q, Lei X, Yuan Y, and Wu X. Wind power prediction using hybrid autoregressive fractionally integrated moving average and least square support vector machine. Energy. 129;122-137 (2017)
  • Li N, He F, and Ma W.: Wind Power Prediction Based on Extreme Learning Machine with Kernel Mean p-Power Error Loss. Energies. 12(4);673 (2019)
  • Daş, M., Balpetek, N., Akpınar, E. K., Akpınar, S.: Türkiye'de bulunan farklı illerin rüzgâr enerjisi potansiyelinin incelenmesi ve sonuçların destek vektör makinesi regresyon ile tahminsel modelinin oluşturulması. Journal of the Faculty of Engineering & Architecture of Gazi University, 34(4) (2019)

Modelling Wind Energy Potential in Different Regions with Different Methods

Yıl 2021, Cilt: 34 Sayı: 4, 1128 - 1143, 01.12.2021
https://doi.org/10.35378/gujs.795265

Öz

Processing a lot of data is a very difficult and laborious task. In order to save time and ease the process, computational intelligence method is a very practical method for data processing. In the present study, the potential of wind energy in different regions of Turkey based on the hourly wind speed data in the years 2008-2017 were analysed statistically. Wind power density values have been examined mathematically and statistically and modelled using artificial intelligence methods. During the statistical analysis, maximum wind speed, average wind speed, wind power density, and standard deviation of wind speed have been determined. The cumulative Weibull function was used to determine wind power density and wind speed distribution on an annual basis using hourly wind speed data. Predictive models have been created by using machine learning algorithms which are computational intelligence method for the obtained wind power density values. Decision tree (DT) algorithm and multilayer perceptron (MLP) algorithm have been chosen as machine learning algorithms. Four different error analyses have been performed for DT and MLP estimates. In the machine algorithms used to estimate wind power values, the DT algorithm performed approximately 35% more accurate than the MLP algorithm. As a result, wind power densities for certain regions have been determined by using both mathematical model and computational intelligence methods.

Kaynakça

  • Sahin, A.D.A.: Review of Research and Development of Wind Energy in Turkey, Clean-Soil, Air, Water. 36; 734-742 (2008)
  • Babu, S , Loganathan, A , Vaıravasundaram, I .: Optimizing Electrical Generators of Wind Energy Conversion System for Efficient Power Extraction . Gazi University Journal of Science , 31 (4) , 1141-1154 (2018)
  • Wind Energy potential in Europe. https://windeurope.org/ (2020). Access Date: 14 September 2020
  • Mutlu Ö. Akpınar S. E. ve Balıkçı A.: Power Quality Analysis of Wind Farm Connected to Alaçatı Substation in Turkey. Renewable Energy. 34(5): 1312-1318 (2009)
  • Jaramillo O. A. Borja M. A.: Wind speed analysis in La Ventosa, Mexico: a bimodal probability distribution case. Renewable Energy 29, 1613-1630 (2004)
  • Incecik S, and Erdogmus F.: An Investigation of the Wind Power Potential on the Western Coast of Anatolia. Renewable Energy 6; 863-865 (1995)
  • Kose R, Ozgur MA, Erbas O, and Tugcu, A.: The Analysis of Wind Data and Wind Energy Potential in Kutahya, Turkey. Renewable and Sustainable Energy Reviews 8;277-288 (2004)
  • Akpınar E.K, and Akpınar S.: Determination of the Wind Energy Potential for Maden-Elazig, Turkey. Energy Conversion and Management 45; 2901-2914 (2004)
  • Dorvlo A. S. Estimating wind speed distribution. Energy Conversion and Management 43(17), 2311-2318 (2002)
  • Efe-eyefıa, E , Thomas, J , Zelıbe, S .: Theoretical Analysis of the Weibull Alpha Power Inverted Exponential Distribution: Properties and Applications . Gazi University Journal of Science , 33 (1) , 265-277 (2020)
  • Carta J. A. Ramirez P. Bueno C.: A joint probability density function of wind speed and direction for wind energy analysis. Energy Conversion and Management. 49(6), 1309-1320 (2008)
  • Shu Z. R. Li Q. S. Chan P. W.: Investigation of offshore wind energy potential in Hong Kong based on Weibull distribution function. Applied Energy. 156, 362-373 (2015)
  • Usta I.: An innovative estimation method regarding Weibull parameters for wind energy applications. Energy. 106, 301-314 (2016)
  • Mohammadi K. Alavi O. Mostafaeipour A. Goudarzi N. Jalilvand, M.: Assessing different parameters estimation methods of Weibull distribution to compute wind power density. Energy Conversion and Management. 108, 322-335 (2016)
  • Ramírez P. Carta J. A.: Influence of the data sampling interval in the estimation of the parameters of the Weibull wind speed probability density distribution: a case study. Energy Conversion and Management. 46(15-16), 2419-2438 (2005)
  • Akdağ S. A. Dinler A.: A new method to estimate Weibull parameters for wind energy applications. Energy conversion and management. 50(7), 1761-1766 (2009)
  • Yu C. Li Y. Bao Y. Tang H. Zhai G.: A novel framework for wind speed prediction based on recurrent neural networks and support vector machine. Energy Conversion and Management.178, 137-145 (2018)
  • Cliff, W. C., The Effect of generalized wind characteristics on annual power estimates from wind turbine generators, PNL-2436, Richland, Washington: Battele Pacific Northwest Laboratory (1977)
  • Çelik A. N., A Statistical analysis of wind power density based on the Weibull and Rayleigh models at Southern Region of Turkey. Renewable Energy. 29, 593-604 (2004)
  • Chang T. P.: Performance comparison of six numerical methods in estimating Weibull parameters for wind energy application. Apply Energy. 88, 272-282 (2011)
  • Erdem, O , Kesen, S .:Estimation of Turkey’s Natural Gas Consumption by Machine Learning Techniques. Gazi University Journal of Science, 33 (1), 120-133 (2020)
  • Rumelhart, D. E., Hinton, G. E., Williams, R. J.: Learning representations by back-propagating errors. nature, 323(6088), 533-536 (1986)
  • Reikard, G.: Regime‐switching models and multiple causal factors in forecasting wind speed. Wind Energy. 13(5), 407-.418 (2010)
  • Ballireddy, T. R. R., Modi, P. K.: Reliability evaluation of power system incorporating wind farm for generation expansion planning based on ANLSA approach. Wind Energy. 22(7), 975-991 (2019)
  • Meenakshi, S., Venkatachalam, V.: FUDT: a fuzzy uncertain decision tree algorithm for classification of uncertain data. Arabian Journal for Science and Engineering. 40(11), 3187-3196 (2015)
  • Ellis, N., Davy, R., & Troccoli, A.: Predicting wind power variability events using different statistical methods driven by regional atmospheric model output. Wind Energy. 18(9), 1611-1628 (2015)
  • Ayaz, Y. Kocamaz, A.F. Karakoç, M.B.: Modelling of compressive strength and UPV of high-volume mineral-admixtured concrete using rule-based M5 rule and tree model M5P classifiers. Constr. Build. Mater. 94, pp. 235-240 (2015)
  • Behnood, A., Behnood, V., Gharehveran, M.M, Alyamac, K.E.: Prediction of the compressive strength of normal and high-performance concretes using M5P model tree algorithm. Construction and Building Materials. 142, 199-207 (2017)
  • Alic, E. Das, M. Kaska, O.: Heat Flux Estimation at Pool Boiling Processes with Computational Intelligence Methods,” Processes. 7(5), 293 (2019)
  • Aggarwal, G., Sabharwal, S., Nagpal, S.: Theoretical and Empirical Validation of Coupling Metrics for Object-Oriented Data Warehouse Design. Arabian Journal for Science and Engineering. 43(2), 675-691 (2018)
  • Wang Y, Witten IH.: Induction of model trees for predicting continuous classes, in: Proc of the Poster Papers of the European Conference on Machine Learning. University of Economics, Faculty of Informatics and Statistics, Prague, (1997)
  • Hourly wind speed data. https://www.mgm.gov.tr/ (2020) Access Date: 14 September 2020
  • Quinlan JR.: Learning with continuous classes, in: Proceedings of the Australian Joint Conference on Artificial Intelligence, World Scientific, Singapore (1992)
  • Zameer A, Khan A, and Javed SG.: Machine Learning based short-term wind power prediction using a hybrid learning model. Computers & Electrical Engineering. 45;122-133 (2015)
  • Petkovic D, Shamshirband S, Anuar NB, Saboohi H, Wahab AWA, Protic M, et al. An appraisal of wind speed distribution prediction by soft computing methodologies: a comparative study. Energy conversion and Management. 84;133-139 (2014)
  • Liu H, Tian HQ, and Li YF.: Four wind speed multi-step forecasting models using extreme learning machines and signal decomposing algorithms. Energy conversion and management. 100, 16-22 (2015)
  • Yuan, X., Chen, C., Yuan, Y., Huang, Y., Tan, Q.: Short-term wind power prediction based on LSSVM–GSA model. Energy Conversion and Management. 101;393-401(2015)
  • Yesilbudak M, Sagiroglu S, and Colak I.: A novel implementation of kNN classifier based on multi-tupled meteorological input data for wind power prediction. Energy Conversion and Management. 135;434-444 (2017)
  • Ouyang T, Zha X, and Qin L.: A combined multivariate model for wind power prediction. Energy Conversion and Management. 144;361-373 (2017)
  • Yuan X, Tan Q, Lei X, Yuan Y, and Wu X. Wind power prediction using hybrid autoregressive fractionally integrated moving average and least square support vector machine. Energy. 129;122-137 (2017)
  • Li N, He F, and Ma W.: Wind Power Prediction Based on Extreme Learning Machine with Kernel Mean p-Power Error Loss. Energies. 12(4);673 (2019)
  • Daş, M., Balpetek, N., Akpınar, E. K., Akpınar, S.: Türkiye'de bulunan farklı illerin rüzgâr enerjisi potansiyelinin incelenmesi ve sonuçların destek vektör makinesi regresyon ile tahminsel modelinin oluşturulması. Journal of the Faculty of Engineering & Architecture of Gazi University, 34(4) (2019)
Toplam 42 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Mühendislik
Bölüm Mechanical Engineering
Yazarlar

Mehmet Daş 0000-0002-4143-9226

Ebru Akpınar 0000-0003-0666-9189

Sinan Akpınar 0000-0002-3191-4644

Yayımlanma Tarihi 1 Aralık 2021
Yayımlandığı Sayı Yıl 2021 Cilt: 34 Sayı: 4

Kaynak Göster

APA Daş, M., Akpınar, E., & Akpınar, S. (2021). Modelling Wind Energy Potential in Different Regions with Different Methods. Gazi University Journal of Science, 34(4), 1128-1143. https://doi.org/10.35378/gujs.795265
AMA Daş M, Akpınar E, Akpınar S. Modelling Wind Energy Potential in Different Regions with Different Methods. Gazi University Journal of Science. Aralık 2021;34(4):1128-1143. doi:10.35378/gujs.795265
Chicago Daş, Mehmet, Ebru Akpınar, ve Sinan Akpınar. “Modelling Wind Energy Potential in Different Regions With Different Methods”. Gazi University Journal of Science 34, sy. 4 (Aralık 2021): 1128-43. https://doi.org/10.35378/gujs.795265.
EndNote Daş M, Akpınar E, Akpınar S (01 Aralık 2021) Modelling Wind Energy Potential in Different Regions with Different Methods. Gazi University Journal of Science 34 4 1128–1143.
IEEE M. Daş, E. Akpınar, ve S. Akpınar, “Modelling Wind Energy Potential in Different Regions with Different Methods”, Gazi University Journal of Science, c. 34, sy. 4, ss. 1128–1143, 2021, doi: 10.35378/gujs.795265.
ISNAD Daş, Mehmet vd. “Modelling Wind Energy Potential in Different Regions With Different Methods”. Gazi University Journal of Science 34/4 (Aralık 2021), 1128-1143. https://doi.org/10.35378/gujs.795265.
JAMA Daş M, Akpınar E, Akpınar S. Modelling Wind Energy Potential in Different Regions with Different Methods. Gazi University Journal of Science. 2021;34:1128–1143.
MLA Daş, Mehmet vd. “Modelling Wind Energy Potential in Different Regions With Different Methods”. Gazi University Journal of Science, c. 34, sy. 4, 2021, ss. 1128-43, doi:10.35378/gujs.795265.
Vancouver Daş M, Akpınar E, Akpınar S. Modelling Wind Energy Potential in Different Regions with Different Methods. Gazi University Journal of Science. 2021;34(4):1128-43.