AN ADAPTIVE CONTROL ALGORITHM OF TETHERED UNMANNED AERIAL VEHICLE, 11-17.

Xiang Huang, Xu Gu, Biao Du, and Danjiang Huo

References

  1. [1] B. Qiu, G. Wang, Y. Fan, D. Mu, and X. Sun, Robust coursecontroller based trajectory linearization control for unmannedsurface vehicle with input saturation, Mechatronic Systemsand Control, 47, 2019, 187–193, doi: 10.2316/J.2019.201-0023.
  2. [2] S.M. Jiao, D.P. Liu, and X.K. Zheng, Attitude control ofquadcopter based on self-tuning linear active disturbancerejection, Mechatronic Systems and Control, 48(2), 2020,102–109, doi: 10.2316/J.2020.201-0022.
  3. [3] H. Jiang, Q. Chang, Y. Wang, and X. Xie, Optimisationof the active disturbance rejection control of a four-rotoraircraft, Mechatronic Systems and Control, 48, 2020, 87–93,doi: 10.2316/J.2020.201-0017.
  4. [4] M.M. Nicotra, R. Naldi, and E. Garone, Taut cable control of atethered UAV, IFAC Proceedings Volume, 19, 2014, 3190–3195,doi: 10.3182/20140824-6-za-1003.02581.
  5. [5] L. Zikou, C. Papachristos, and A. Tzes, The power-over-tether system for powering small UAVs: Tethering-line tensioncontrol synthesis, Proc. 2015 23rd Mediterranean Conf. onControl and Automation, MED 2015 - Conference Proceedings,Torremolinos, 2015, 681–687, doi: 10.1109/MED.2015.7158825.
  6. [6] T. Lee, Geometric controls for a tethered quadrotor UAV, Proc.of the IEEE Conf. on Decision and Control, 54rd IEEE Conf.on Decision and Control, CDC 2015, Osaka, 2015, 2749–2754,doi: 10.1109/CDC.2015.7402632.
  7. [7] M.M. Nicotra, R. Naldi, and E. Garone, Nonlinear control ofa tethered UAV: The taut cable case, Automatic, 78, 174–184.
  8. [8] Y. Gao, Research on automatic cable retraction and releasecontrol system of tethered UAV, (Harbin: Harbin EngineeringUniversity, 2018).
  9. [9] J. Luo, Payoff length control device, winch device and UAVsystem for mooring UAV: China, CN109911239A, 2019.
  10. [10] L. Ding, K. Yu, C. Liu, and X. Zheng, Trajectory trackingcontrol for a tethered UAV with disturbance rejection technique,Electronics Optics and Control, 27, 2020, 95–100.
  11. [11] D. Cheng and T. Zhang, Interactive synchronous automaticretracting and paying off system for tethering UAV and winch:China, CN113492994A, 2021.
  12. [12] J. Hou and G. Sun, Design and research of automatic retrievingand paying off equipment for stranded UAV, EquipmentManagement and Maintenance, 1, 2022, 126–128.
  13. [13] A.H.C. Abantas, W.A. Sabellona, and C.J.O. Salaan, Designof a rule-based tuned PID controller for tether managementof a suspended tethered UAV, Proc. 2022 IEEE 14thInternational Conf. on Humanoid, Nanotechnology, Informa-tion Technology, Communication and Control, Environment,and Management, HNICEM 2022, Boracay Island, 2022,doi: 10.1109/HNICEM57413.2022.10109555.
  14. [14] X. Zhang, F. Zhang, and P. Huang, Formation planningfor tethered multirotor UAV cooperative transportation withunknown payload and cable length, IEEE Transactionson Automation Science and Engineering, 2023, 1–12,doi: 10.1109/TASE.2023.3279827.
  15. [15] T. Zheng, Research and design of tethered UAV winding system,(Mianyang: Southwest University of Science and Technology,2019).
  16. [16] W. Zeng and X. Zhou, Force analysis of mooring cable based onlumped mass method, Scientific and Technological EconomicMarket, 4, 2019, 21–22.
  17. [17] H. Lin, et al., Research on the positioning method of tetheredUAV using force sensing, CAAI Transactions on IntelligentSystems, 15, 2020, 672–678.
  18. [18] X. Tang, Research on chain length variation of scraperconveying system based on catenary and newton iterationmethod, Coal Engineering, 49, 2017, 123–126.
  19. [19] Y. Ma, et al., Function transfer method for solving catenaryproblem, Journal of Beijing University of Aeronautics andAstronautics, 47, 2021, 1933–1940.

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