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Power Prediction of Airborne Wind Energy Systems Using Multivariate Machine Learning

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  • Mostafa A. Rushdi

    (Interdisciplinary Graduate School of Engineering Sciences (IGSES-ESST), Kyushu University, Fukuoka 816-8580, Japan
    Faculty of Engineering and Technology, Future University in Egypt (FUE), New Cairo 11835, Egypt)

  • Ahmad A. Rushdi

    (Sandia National Laboratories, Albuquerque, NM 87123, USA)

  • Tarek N. Dief

    (Research Institute for Applied Mechanics (RIAM), Kyushu University, Fukuoka 816-8580, Japan)

  • Amr M. Halawa

    (Research Institute for Applied Mechanics (RIAM), Kyushu University, Fukuoka 816-8580, Japan)

  • Shigeo Yoshida

    (Research Institute for Applied Mechanics (RIAM), Kyushu University, Fukuoka 816-8580, Japan)

  • Roland Schmehl

    (Faculty of Aerospace Engineering, Delft University of Technology, 2629 HS Delft, The Netherlands)

Abstract

Kites can be used to harvest wind energy at higher altitudes while using only a fraction of the material required for conventional wind turbines. In this work, we present the kite system of Kyushu University and demonstrate how experimental data can be used to train machine learning regression models. The system is designed for 7 kW traction power and comprises an inflatable wing with suspended kite control unit that is either tethered to a fixed ground anchor or to a towing vehicle to produce a controlled relative flow environment. A measurement unit was attached to the kite for data acquisition. To predict the generated tether force, we collected input–output samples from a set of well-designed experimental runs to act as our labeled training data in a supervised machine learning setting. We then identified a set of key input parameters which were found to be consistent with our sensitivity analysis using Pearson input–output correlation metrics. Finally, we designed and tested the accuracy of a neural network, among other multivariate regression models. The quality metrics of our models show great promise in accurately predicting the tether force for new input/feature combinations and potentially guide new designs for optimal power generation.

Suggested Citation

  • Mostafa A. Rushdi & Ahmad A. Rushdi & Tarek N. Dief & Amr M. Halawa & Shigeo Yoshida & Roland Schmehl, 2020. "Power Prediction of Airborne Wind Energy Systems Using Multivariate Machine Learning," Energies, MDPI, vol. 13(9), pages 1-23, May.
    • Handle: RePEc:gam:jeners:v:13:y:2020:i:9:p:2367-:d:355846
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    References listed on IDEAS

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    1. Ti, Zilong & Deng, Xiao Wei & Yang, Hongxing, 2020. "Wake modeling of wind turbines using machine learning," Applied Energy, Elsevier, vol. 257(C).
    2. Tarek N. Dief & Uwe Fechner & Roland Schmehl & Shigeo Yoshida & Mostafa A. Rushdi, 2020. "Adaptive Flight Path Control of Airborne Wind Energy Systems," Energies, MDPI, vol. 13(3), pages 1-29, February.
    3. Licitra, G. & Koenemann, J. & Bürger, A. & Williams, P. & Ruiterkamp, R. & Diehl, M., 2019. "Performance assessment of a rigid wing Airborne Wind Energy pumping system," Energy, Elsevier, vol. 173(C), pages 569-585.
    4. van der Vlugt, Rolf & Bley, Anna & Noom, Michael & Schmehl, Roland, 2019. "Quasi-steady model of a pumping kite power system," Renewable Energy, Elsevier, vol. 131(C), pages 83-99.
    5. Cherubini, Antonello & Papini, Andrea & Vertechy, Rocco & Fontana, Marco, 2015. "Airborne Wind Energy Systems: A review of the technologies," Renewable and Sustainable Energy Reviews, Elsevier, vol. 51(C), pages 1461-1476.
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    9. Bechtle, Philip & Schelbergen, Mark & Schmehl, Roland & Zillmann, Udo & Watson, Simon, 2019. "Airborne wind energy resource analysis," Renewable Energy, Elsevier, vol. 141(C), pages 1103-1116.
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    Cited by:

    1. Axelle Viré & Geert Lebesque & Mikko Folkersma & Roland Schmehl, 2022. "Effect of Chordwise Struts and Misaligned Flow on the Aerodynamic Performance of a Leading-Edge Inflatable Wing," Energies, MDPI, vol. 15(4), pages 1-15, February.
    2. Halil Akbaş & Gültekin Özdemir, 2020. "An Integrated Prediction and Optimization Model of a Thermal Energy Production System in a Factory Producing Furniture Components," Energies, MDPI, vol. 13(22), pages 1-29, November.
    3. Adam Krechowicz & Maria Krechowicz & Katarzyna Poczeta, 2022. "Machine Learning Approaches to Predict Electricity Production from Renewable Energy Sources," Energies, MDPI, vol. 15(23), pages 1-41, December.
    4. Mostafa A. Rushdi & Tarek N. Dief & Shigeo Yoshida & Roland Schmehl, 2020. "Towing Test Data Set of the Kyushu University Kite System," Data, MDPI, vol. 5(3), pages 1-18, August.
    5. Galih Bangga, 2022. "Progress and Outlook in Wind Energy Research," Energies, MDPI, vol. 15(18), pages 1-5, September.
    6. István G. Balázs & Attila Fodor & Attila Magyar, 2021. "Quantification of the Flexibility of Residential Prosumers," Energies, MDPI, vol. 14(16), pages 1-21, August.
    7. Rushdi, Mostafa A. & Yoshida, Shigeo & Watanabe, Koichi & Ohya, Yuji, 2021. "Machine learning approaches for thermal updraft prediction in wind solar tower systems," Renewable Energy, Elsevier, vol. 177(C), pages 1001-1013.
    8. Ashok Bhansali & Namala Narasimhulu & Rocío Pérez de Prado & Parameshachari Bidare Divakarachari & Dayanand Lal Narayan, 2023. "A Review on Sustainable Energy Sources Using Machine Learning and Deep Learning Models," Energies, MDPI, vol. 16(17), pages 1-18, August.

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