Maximum power point tracking coordination control for fully controlled doubly fed induction generator wind power systems

Authors

Yongshu Li, Weiwei Sun, Dehai Yu, Yashu Liu, Xinyu Lv

Abstract

This paper presents a maximum power point tracking (MPPT) coordination control strategy for fully controlled doubly fed induction generator (FC-DFIG) wind power systems, integrating Hamilton-Jacobi Inequality (HJI) sliding mode control (SMC) and port-controlled Hamiltonian (PCH) control.SMC is noted for its rapid dynamic response but is prone to chattering, whereas PCH demonstrates significant stability despite its slower dynamic response. By integrating a coordination controller, the SMC enhances responsiveness in transient state, while the PCH control ensures stability in steady state. Together, they collectively achieve MPPT control for FC-DFIG systems. The effectiveness and advantages of the proposed control strategy are validated through simulation and experiment.

Keywords

coordination control, doubly fed induction generator, maximum power point tracking, port-controlled hamiltonian control, sliding mode control

Citation

• Journal: Nonlinear Dynamics
• Year: 2025
• Volume: 113
• Issue: 20
• Pages: 27705–27722
• Publisher: Springer Science and Business Media LLC
• DOI: 10.1007/s11071-025-11531-3

BibTeX

@article{Li_2025,
  title={{Maximum power point tracking coordination control for fully controlled doubly fed induction generator wind power systems}},
  volume={113},
  ISSN={1573-269X},
  DOI={10.1007/s11071-025-11531-3},
  number={20},
  journal={Nonlinear Dynamics},
  publisher={Springer Science and Business Media LLC},
  author={Li, Yongshu and Sun, Weiwei and Yu, Dehai and Liu, Yashu and Lv, Xinyu},
  year={2025},
  pages={27705--27722}
}

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