Skip to main content
Top

09-09-2024 | Original Paper

Improving short-term wind power forecasting in Senegal’s flagship wind farm: a deep learning approach with attention mechanism

Authors: Ansumana Badjan, Ghamgeen Izat Rashed, Hashim Ali I. Gony, Hussain Haider, Ahmed O. M. Bahageel, Husam I. Shaheen

Published in: Electrical Engineering

Log in

Activate our intelligent search to find suitable subject content or patents.

search-config
loading …

Abstract

Accurate wind power forecasting assumes an important role in power system operation and economic planning, particularly in Senegal’s flagship wind farm, the largest in West Africa. The fundamental volatility, intermittent nature, and unexpected character of wind power make it difficult to maintain power system stability. To address these challenges, an attention mechanism-based deep learning model is proposed to anticipate wind power in the short term with the goal of improving forecasting accuracy. The dynamic shifts in the wind power dataset are first processed by convolutional neural networks to extract multi-dimensional features. After being extracted, the feature vectors are placed into a long short-term memory (LSTM) network by being transformed into a series structure. Next, to optimize and improve the forecast accuracy of the model, an attention mechanism is included by assigning distinct weights to each hidden layer in the LSTM network. Real operational wind power generation data from the wind farm is utilized to verify the effectiveness of the proposed method. The results show that the proposed method can successfully boost the forecasting accuracy of wind power with better performance compared to other machine learning and deep learning models. This study not only contributes to improving wind power generation management and power system operations in Senegal but also serves as a valuable reference for promoting renewable energy transitions across sub-Saharan Africa.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

  • über 102.000 Bücher
  • über 537 Zeitschriften

aus folgenden Fachgebieten:

  • Automobil + Motoren
  • Bauwesen + Immobilien
  • Business IT + Informatik
  • Elektrotechnik + Elektronik
  • Energie + Nachhaltigkeit
  • Finance + Banking
  • Management + Führung
  • Marketing + Vertrieb
  • Maschinenbau + Werkstoffe
  • Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

  • über 67.000 Bücher
  • über 390 Zeitschriften

aus folgenden Fachgebieten:

  • Automobil + Motoren
  • Bauwesen + Immobilien
  • Business IT + Informatik
  • Elektrotechnik + Elektronik
  • Energie + Nachhaltigkeit
  • Maschinenbau + Werkstoffe




 

Jetzt Wissensvorsprung sichern!

Springer Professional "Wirtschaft"

Online-Abonnement

Mit Springer Professional "Wirtschaft" erhalten Sie Zugriff auf:

  • über 67.000 Bücher
  • über 340 Zeitschriften

aus folgenden Fachgebieten:

  • Bauwesen + Immobilien
  • Business IT + Informatik
  • Finance + Banking
  • Management + Führung
  • Marketing + Vertrieb
  • Versicherung + Risiko




Jetzt Wissensvorsprung sichern!

Literature
1.
go back to reference International Renewable Energy Agency (IRENA) (20200) Africa 2030: Roadmap for a renewable energy Africa 2030 roadmap for a renewable energy future (irena.org) International Renewable Energy Agency (IRENA) (20200) Africa 2030: Roadmap for a renewable energy Africa 2030 roadmap for a renewable energy future (irena.org)
2.
go back to reference African Development Bank Group (2020) Senegal: Taiba N’Diaye wind power project [Press release]. Récupéré de; Ocober 7 2020 African Development Bank Group (2020) Senegal: Taiba N’Diaye wind power project [Press release]. Récupéré de; Ocober 7 2020
3.
go back to reference Mocanu E, Nguyen PH, Gibescu M, Kling WL (2016) Deep learning for estimating building energy consumption. Sustain Energy Grids Netw 6:91–99CrossRef Mocanu E, Nguyen PH, Gibescu M, Kling WL (2016) Deep learning for estimating building energy consumption. Sustain Energy Grids Netw 6:91–99CrossRef
4.
go back to reference Wang Y, Hu Q, Srinivasan D, Wang Z (2018) Wind power curve modeling and wind power forecasting with inconsistent data. IEEE Trans Sustain Energy 10(1):16–25CrossRef Wang Y, Hu Q, Srinivasan D, Wang Z (2018) Wind power curve modeling and wind power forecasting with inconsistent data. IEEE Trans Sustain Energy 10(1):16–25CrossRef
5.
go back to reference Soman SS, Zareipour H, Malik O, Mandal P (2010) A review of wind power and windspeed forecasting methods with different time horizons. North american power symposium (NAPS). IEEE, New Jersy, pp 1–8 Soman SS, Zareipour H, Malik O, Mandal P (2010) A review of wind power and windspeed forecasting methods with different time horizons. North american power symposium (NAPS). IEEE, New Jersy, pp 1–8
6.
go back to reference Jung J, Broadwater RP (2014) Current status and future advances for wind speed and power forecasting. Renew Sustain Energy Rev 31:762–777CrossRef Jung J, Broadwater RP (2014) Current status and future advances for wind speed and power forecasting. Renew Sustain Energy Rev 31:762–777CrossRef
7.
go back to reference Wang Y, Hu Q, Li L, Foley AM, Srinivasan D (2019) Approaches to wind power curve modeling: a review and discussion. Renew Sustain Energy Rev 116:109422CrossRef Wang Y, Hu Q, Li L, Foley AM, Srinivasan D (2019) Approaches to wind power curve modeling: a review and discussion. Renew Sustain Energy Rev 116:109422CrossRef
8.
go back to reference Yan J, Ouyang T (2019) Advanced wind power prediction based on data-driven error correction. Energy Convers Manage 180:302–311CrossRef Yan J, Ouyang T (2019) Advanced wind power prediction based on data-driven error correction. Energy Convers Manage 180:302–311CrossRef
9.
go back to reference Hu J, Heng J, Wen J, Zhao W (2020) Deterministic and probabilistic wind speed forecasting with de-noising-reconstruction strategy and quantile regression based algorithm. Renew Energy 162:1208–1226CrossRef Hu J, Heng J, Wen J, Zhao W (2020) Deterministic and probabilistic wind speed forecasting with de-noising-reconstruction strategy and quantile regression based algorithm. Renew Energy 162:1208–1226CrossRef
10.
go back to reference Lei M, Shiyan L, Chuanwen J, Hongling L, Yan Z (2009) A review on the forecasting of wind speed and generated power. Renew Sustain Energy Rev 13(4):915–920CrossRef Lei M, Shiyan L, Chuanwen J, Hongling L, Yan Z (2009) A review on the forecasting of wind speed and generated power. Renew Sustain Energy Rev 13(4):915–920CrossRef
11.
go back to reference Higashiyama K, Fujimoto Y, Hayashi Y (2018) Feature extraction of NWP data for wind power forecasting using 3D-convolutional neural networks. Energy Procedia 155:350–358CrossRef Higashiyama K, Fujimoto Y, Hayashi Y (2018) Feature extraction of NWP data for wind power forecasting using 3D-convolutional neural networks. Energy Procedia 155:350–358CrossRef
12.
go back to reference Han Q, Meng F, Hu T, Chu F (2017) Non-parametric hybrid models for wind speed forecasting. Energy Convers Manage 148:554–568CrossRef Han Q, Meng F, Hu T, Chu F (2017) Non-parametric hybrid models for wind speed forecasting. Energy Convers Manage 148:554–568CrossRef
13.
go back to reference Yatiyana E, Rajakaruna S, Ghosh A (2017) Wind speed and direction forecasting for wind power generation using ARIMA model. Australasian universities power engineering conference (AUPEC), IEEE Yatiyana E, Rajakaruna S, Ghosh A (2017) Wind speed and direction forecasting for wind power generation using ARIMA model. Australasian universities power engineering conference (AUPEC), IEEE
14.
go back to reference Kavasseri RG, Seetharaman K (2009) Day-ahead wind speed forecasting using f-ARIMA models. Renew energy 34(5):1388–1393CrossRef Kavasseri RG, Seetharaman K (2009) Day-ahead wind speed forecasting using f-ARIMA models. Renew energy 34(5):1388–1393CrossRef
15.
go back to reference Li L-L, Zhao X, Tseng M-L, Tan RR (2020) Short-term wind power forecasting based on support vector machine with improved dragonfly algorithm. J Clean Prod 242:118447CrossRef Li L-L, Zhao X, Tseng M-L, Tan RR (2020) Short-term wind power forecasting based on support vector machine with improved dragonfly algorithm. J Clean Prod 242:118447CrossRef
16.
go back to reference Koo J, Han GD, Choi HJ, Shim JHJE (2015) Wind-speed prediction and analysis based on geological and distance variables using an artificial neural network: a case study in South Korea. Energy 93:1296–1302CrossRef Koo J, Han GD, Choi HJ, Shim JHJE (2015) Wind-speed prediction and analysis based on geological and distance variables using an artificial neural network: a case study in South Korea. Energy 93:1296–1302CrossRef
17.
go back to reference Zhu Q, Li H, Wang Z, Chen J, Wang BJPST (2017) Short-term wind power forecasting based on LSTM. Power Syst Technol 41(12):3797–3802 Zhu Q, Li H, Wang Z, Chen J, Wang BJPST (2017) Short-term wind power forecasting based on LSTM. Power Syst Technol 41(12):3797–3802
18.
go back to reference Qureshi AS, Khan A, Zameer A, Usman AJASC (2017) Wind power prediction using deep neural network based meta regression and transfer learning. Appl Soft Comput 58:742–755CrossRef Qureshi AS, Khan A, Zameer A, Usman AJASC (2017) Wind power prediction using deep neural network based meta regression and transfer learning. Appl Soft Comput 58:742–755CrossRef
19.
go back to reference Liu H, Mi X, Li Y (2018) Smart multi-step deep learning model for wind speed forecasting based on variational mode decomposition, singular spectrum analysis, lstm network and elm. Energy Convers Manage 159:54–64CrossRef Liu H, Mi X, Li Y (2018) Smart multi-step deep learning model for wind speed forecasting based on variational mode decomposition, singular spectrum analysis, lstm network and elm. Energy Convers Manage 159:54–64CrossRef
20.
go back to reference Sadaei HJ, e Silva PCL, Guimaraes FG, Lee MHJE (2019) Short-term load forecasting by using a combined method of convolutional neural networks and fuzzy time series. Energy 175:365–377CrossRef Sadaei HJ, e Silva PCL, Guimaraes FG, Lee MHJE (2019) Short-term load forecasting by using a combined method of convolutional neural networks and fuzzy time series. Energy 175:365–377CrossRef
21.
go back to reference Neshat M, Nezhad MM, Abbasnejad E, Mirjalili S, Tjernberg LB, Garcia DA, Alexander B, Wagner M (2021) A deep learning-based evolutionary model for shortterm wind speed forecasting: a case study of the lillgrund offshore wind farm. Energy Convers Manage 236:114002CrossRef Neshat M, Nezhad MM, Abbasnejad E, Mirjalili S, Tjernberg LB, Garcia DA, Alexander B, Wagner M (2021) A deep learning-based evolutionary model for shortterm wind speed forecasting: a case study of the lillgrund offshore wind farm. Energy Convers Manage 236:114002CrossRef
22.
go back to reference Wan J, Liu J, Ren G, Guo Y, Yu D, Hu Q (2016) Day-ahead prediction of wind speed with deep feature learning. Int J Pattern Recognit Artif Intell 30(05):1650011CrossRef Wan J, Liu J, Ren G, Guo Y, Yu D, Hu Q (2016) Day-ahead prediction of wind speed with deep feature learning. Int J Pattern Recognit Artif Intell 30(05):1650011CrossRef
23.
go back to reference Ding M, Zhou H, Xie H, Wu M, Nakanishi Y, Yokoyama R (2019) A gated recurrent unit neural networks based wind speed error correction model for short-term wind power forecasting. Neurocomputing 365:54–61CrossRef Ding M, Zhou H, Xie H, Wu M, Nakanishi Y, Yokoyama R (2019) A gated recurrent unit neural networks based wind speed error correction model for short-term wind power forecasting. Neurocomputing 365:54–61CrossRef
24.
go back to reference Putz D, Gumhalter M, Auer HJRE (2021) A novel approach to multi-horizon wind power forecasting based on deep neural architecture. Renew Energy 178:494–505CrossRef Putz D, Gumhalter M, Auer HJRE (2021) A novel approach to multi-horizon wind power forecasting based on deep neural architecture. Renew Energy 178:494–505CrossRef
25.
go back to reference J Dou, C Liu, B Wang (Eds.) (2018) Short-term wind power forecasting based on convolutional neural networks. IOP conference series: earth and environmental science, IOP Publishing J Dou, C Liu, B Wang (Eds.) (2018) Short-term wind power forecasting based on convolutional neural networks. IOP conference series: earth and environmental science, IOP Publishing
26.
go back to reference Shi J, Guo J, Zheng S (2012) Evaluation of hybrid forecasting approaches for wind speed and power generation time series. Renew Sustain Energy Rev 16(5):3471–3480CrossRef Shi J, Guo J, Zheng S (2012) Evaluation of hybrid forecasting approaches for wind speed and power generation time series. Renew Sustain Energy Rev 16(5):3471–3480CrossRef
27.
go back to reference Shahid F, Zameer A, Muneeb MJE (2021) A novel genetic LSTM model for wind power forecast. Energy 223:120069CrossRef Shahid F, Zameer A, Muneeb MJE (2021) A novel genetic LSTM model for wind power forecast. Energy 223:120069CrossRef
28.
go back to reference Song J, Wang J, Lu H (2018) A novel combined model based on advanced optimization algorithm for short-term wind speed forecasting. Appl Energy 215:643–658CrossRef Song J, Wang J, Lu H (2018) A novel combined model based on advanced optimization algorithm for short-term wind speed forecasting. Appl Energy 215:643–658CrossRef
29.
go back to reference Jiajun H, Chuanjin Y, Yongle L, Huoyue XJEC (2020) Management. Ultra-short term wind prediction with wavelet transform, deep belief network and ensemble learning. Energy Convers Manag 205:112418CrossRef Jiajun H, Chuanjin Y, Yongle L, Huoyue XJEC (2020) Management. Ultra-short term wind prediction with wavelet transform, deep belief network and ensemble learning. Energy Convers Manag 205:112418CrossRef
30.
go back to reference Qiu D, Yang B (2022) Text summarization based on multi-head self-attention mechanism and pointer network. Complex Intell Syst 8:1–13CrossRef Qiu D, Yang B (2022) Text summarization based on multi-head self-attention mechanism and pointer network. Complex Intell Syst 8:1–13CrossRef
31.
go back to reference Tian C, Niu T, Wei W (2022) Developing a wind power forecasting system based on deep learning with attention mechanism. Energy 257:124750CrossRef Tian C, Niu T, Wei W (2022) Developing a wind power forecasting system based on deep learning with attention mechanism. Energy 257:124750CrossRef
32.
go back to reference Huang B, Liang Y, Qiu XJIA (2021) Wind power forecasting using attention-based recurrent neural networks: a comparative study. IEEE Access 9:40432–40444CrossRef Huang B, Liang Y, Qiu XJIA (2021) Wind power forecasting using attention-based recurrent neural networks: a comparative study. IEEE Access 9:40432–40444CrossRef
33.
go back to reference Li P, Wang X (2019) JJIRPG Yang, Short-term wind power forecasting based on twostage attention mechanism. IET Renew Power Gener 14(2):297–304CrossRef Li P, Wang X (2019) JJIRPG Yang, Short-term wind power forecasting based on twostage attention mechanism. IET Renew Power Gener 14(2):297–304CrossRef
34.
go back to reference Niu Z, Yu Z, Tang W, Wu Q, Reformat MJE (2020) Wind power forecasting using attention-based gated recurrent unit network. Energy 196:117081CrossRef Niu Z, Yu Z, Tang W, Wu Q, Reformat MJE (2020) Wind power forecasting using attention-based gated recurrent unit network. Energy 196:117081CrossRef
35.
go back to reference Road Distance Between Dakar, Senegal and Taiba Ndiaye, Senegal with map (Map). Google Maps. Google. Retrieved 9 May 2022 Road Distance Between Dakar, Senegal and Taiba Ndiaye, Senegal with map (Map). Google Maps. Google. Retrieved 9 May 2022
37.
go back to reference Mainstream renewable power (1 August 2019). First wind turbines rise from Taiba N’Diaye Plain. Kumasi, Ghana: Mainstream renewable power. Retrieved 4 Mar 2020 Mainstream renewable power (1 August 2019). First wind turbines rise from Taiba N’Diaye Plain. Kumasi, Ghana: Mainstream renewable power. Retrieved 4 Mar 2020
38.
go back to reference Panahi M, Sadhasivam N, Pourghasemi HR, Rezaie F, RLee S (2020) Spatial prediction of groundwater potential mapping based on convolutional neural network (CNN) and support vector regression (SVR). J. Hydrol. (Amst) 588:125033CrossRef Panahi M, Sadhasivam N, Pourghasemi HR, Rezaie F, RLee S (2020) Spatial prediction of groundwater potential mapping based on convolutional neural network (CNN) and support vector regression (SVR). J. Hydrol. (Amst) 588:125033CrossRef
39.
go back to reference Xiang S, Qin Y, Zhu C, Wang Y (2020) HJIt Chen, LSTM networks based on attention ordered neurons for gear remaining life prediction, SA. Transactions 106:343–354 Xiang S, Qin Y, Zhu C, Wang Y (2020) HJIt Chen, LSTM networks based on attention ordered neurons for gear remaining life prediction, SA. Transactions 106:343–354
40.
go back to reference Wang J, Chen Q, Gong HJIS (2020) STMAG: a spatial-temporal mixed attention graph-based convolution model for multi-data flow safety prediction. Inf Sci (Ny) 525:16–36CrossRef Wang J, Chen Q, Gong HJIS (2020) STMAG: a spatial-temporal mixed attention graph-based convolution model for multi-data flow safety prediction. Inf Sci (Ny) 525:16–36CrossRef
Metadata
Title
Improving short-term wind power forecasting in Senegal’s flagship wind farm: a deep learning approach with attention mechanism
Authors
Ansumana Badjan
Ghamgeen Izat Rashed
Hashim Ali I. Gony
Hussain Haider
Ahmed O. M. Bahageel
Husam I. Shaheen
Publication date
09-09-2024
Publisher
Springer Berlin Heidelberg
Published in
Electrical Engineering
Print ISSN: 0948-7921
Electronic ISSN: 1432-0487
DOI
https://doi.org/10.1007/s00202-024-02681-5