ROBUST ADAPTIVE FAULT-TOLERANT CONTROL BASED ON GBF-CMAC NEURAL NETWORK FOR LOW-ALTITUDE UAV, 267-276.

Xingjian Fu and Hongmei Guo

References

1. [1] J.S. Albus, Data storage in the cerebellar model articulationcontroller (CMAC), Journal of Dynamic Systems, Measure-ment, and Control, 97(3), 1975, 228–233.
2. [2] C.-T. Chiang and C.-S. Lin, CMAC with general basis functions,Neural Networks, 9(7), 1996, 1199–1211.
3. [3] F.J. Gonz´alez-Serrano, A.R. Figueiras-Vidal, A. Art´es-Rodriguez, Fourier analysis of the generalized CMAC neuralnetwork, Neural Networks, 11(3), 1998, 391–396.
4. [4] Nie Junhong and D.A. Linkens, FCMAC: A fuzzified cerebellarmodel articulation controller with self-organizing capacity,Automatica, 30(4), 1994, 655–664.
5. [5] T.Q. Ngo and T.V. Phuong, Robust adaptive self-organizingwavelet fuzzy CMAC tracking control for deicing robot manip-ulator, International Journal of Computers Communications& Control. 10(4), 2015, 567–578.
6. [6] C.-M. Lin and H.-Y. Li, Intelligent control using the waveletfuzzy CMAC backstepping control system for two-axis linearpiezoelectric ceramic motor drive systems, IEEE Transactionson Fuzzy Systems, 22(4), 2014, 791–802.
7. [7] L. Chih-Min, H. Tuan-Tu, and L. Tien-Loc, Adaptive TOPSISfuzzy CMAC back-stepping control system design for nonlinearsystems, Soft Computing, 23, 2018, 6947–6966.
8. [8] Y. Liao, K. Koiwai, and T. Yamamoto, Design andimplementation of a hierarchical-clustering CMAC PIDcontroller, Asian Journal of Control, 21(3), 2019, 1077–1087.
9. [9] H. Ma, T. Ying-Chih, and L.-I. Chen, A CMAC-based schemefor determining membership with classification of text strings,Neural Computing and Applications, 27(7), 2016, 1–9.
10. [10] A. Niederlinski, A heuristic approach to the design of linearmultivariable interacting control systems, Automatica, 7(4),1971, 691–701.
11. [11] D.D. ˇSaljak, Reliable control using multiple control systems,International Journal of Control, 31(2), 1980, 303–329.
12. [12] A. Levis, Challenges to control: A collective view–report of theworkshop held at the University of Santa Clara on September18–19, 1986, IEEE Transaction on Automatic Control, 32(4),1987, 274–285.
13. [13] Z. Wang, H. Shu, and X. Liu, Reliable stabilization of stochastictime-delay systems with nonlinear disturbances, InternationalJournal of General Systems, 34(5), 2005, 523–535.
14. [14] M.S. Mahmoud and H.M. Khalid, Model prediction-basedapproach to fault-tolerant control with applications, IMAJournal of Mathematical Control & Information, 21(2), 2018,217–244.
15. [15] L.L. Li, J. Zhao, and G.M. Dimirovski, Observer-basedreliable exponential stabilization and H∞ control for switchedsystems with faulty actuators: An average dwell-timeapproach, Nonlinear Analysis: Hybrid Systems, 5(3), 2011,479–491.
16. [16] L.-B. Wu and G.-H. Yang, Robust adaptive fault-toleranttracking control of multiple time-delays systems withmismatched parameter uncertainties and actuator failures,International Journal of Robust & Nonlinear Control, 25(16),2015, 2922–2938.
17. [17] C. Deng and G.H. Yang, Cooperative adaptive output feedbackcontrol for nonlinear multi-agent systems with actuator failures,Neurocomputing, 199(c), 2016, 50–57.
18. [18] Y.H. Choi and S.J. Yoo, Event-triggered decentralized adaptivefault-tolerant control of uncertain interconnected nonlinearsystems with actuator failures, ISA Transactions, 77(5), 2018,77–89.
19. [19] Z. Shilei, Z. Tiejun, and L. Yupeng, Fault-tolerant controlbased on iterative learning observer: A descriptor approach,International Journal of Robotics and Automation, 32(2), 2017,176–185.
20. [20] W. Wang, C. Li, Y. Sun, and G. Ma, Distributed coordinatedattitude tracking control for spacecraft formation withcommunication delays, ISA Transactions, 85(3), 2019, 97–106.
21. [21] C. Liu, B. Jiang, and K. Zhang, Adaptive fault-tolerantH∞ output feedback control for lead–wing close formationflight, IEEE Transactions on Systems, Man, and Cybernetics:Systems, 50(8), 2020, 2804–2814.
22. [22] Z.-Q. Yu, Z.-X. Liu, Y.-M. Zhang, Y.-H. Qu, and C.-Y. Su,Decentralized fault-tolerant cooperative control of multipleUAVs with prescribed attitude synchronization trackingperformance under directed communication topology, Frontiersof Information Technology & Electronic Engineering, 20(5),2019, 685–700.
23. [23] A. Khosravian and M. Namvar, Rigid body attitude controlusing a single vector measurement and gyro, IEEE Transactionson Automatic Control, 57(5), 2012, 1273–1279.
24. [24] M. Jiadong and Z. Zhigang, Modeling and control simulation ofsmall quadrotor UAV, Journal of Lanzhou Jiaotong University,32(1), 2013, 63–67.
25. [25] S. Yu, Design and simulation of attitude stabilization controllerfor quadrotor UAV, Computer Simulation, 34(8), 2017, 85–88.
26. [26] M.F. Yeh, Single-input CMAC control system, Neurocomput-ing, 70(16), 2007, 2638–2644.275
27. [27] Q. Zhang, H.L. Yu, and D.Z. Xu, Robust adaptive terminalsliding mode control for uncertain nonlinear systems basedon self-organizing wavelet cerebellar model joint controller,Control Theory and Applications, 33(3), 2016, 387–397.
28. [28] X. Qiaolin, Research on robust and adaptive fault tolerantcontrol technology for unmanned helicopter. (Nanjing: NanjingUniversity of Science and Technology), 2012.
29. [29] H.X. Yang, X.X. Yang, and W.H. Zhang, Distributed controlof spacecraft formation using improved cyclic pursuit withbeacon guidance, Applied Mechanics and Materials, 138, 2011,38–43.
30. [30] K.K. Zhang, B. Jiang, X.-G. Yan, and Z.H. Mao, Adaptiverobust fault-tolerant control for linear MIMO systems withunmatched uncertainties, International Journal of Control,90(10), 2017, 2253–2269.

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• Abstract
• DOI: 10.2316/J.2023.206-0715
• From Journal (206) International Journal of Robotics and Automation - 2023

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