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Neural Computing and Applications
Erschienen in: Neural Computing and Applications 23/2021

18.06.2021 | Original Article

Adaptive neural control for a tilting quadcopter with finite-time convergence

verfasst von: Meichen Liu, Ruihang Ji, Shuzhi Sam Ge, Fellow, IEEE

Erschienen in: Neural Computing and Applications | Ausgabe 23/2021

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Abstract

This paper addresses the tracking control problem of the tilting quadcopter with unknown nonlinearities. A novel tilting quadcopter conception is proposed with a fully actuated version, which suggests that the translational and rotational movements can be controlled independently. Based on the Euler-Lagrange equations, the dynamics of tilting quadcopter is developed with uncertainties, where Neural Networks (NNs) are utilized to approximate the unknown nonlinearities in systems. We construct a novel auxiliary filter to obtain the estimation errors explicitly to achieve better approximation ability of NNs. By introducing new leakage terms in the adaptive scheme, the weights of identifier of NNs can converge to their optimal values. And a simple online verification is provided to test the parameter estimation convergence, which relaxes the requirement of persistent excitation condition. Moreover, we propose an Adaptive Finite-time Neural Control for the tilting quadcopter, where all the tracking errors can converge to a small neighborhood around zero in finite time as well as the estimation errors. Finally, comparative simulation results are presented to illustrate the effectiveness and superiority of our proposed control.
Vorheriger Artikel On the modeling of the annual corrosion rate in main cables of suspension bridges using combined soft computing model and a novel nature-inspired algorithm
Nächster Artikel A structure distinguishable graph attention network for knowledge base completion

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Literatur
1.
Yao H, Qin R, Chen X (2019) Unmanned aerial vehicle for remote sensing applications-a review. Remote Sens 11(12):1443CrossRef
2.
Yu H, Li G, Zhang W, Huang Q, Du D, Tian Q, Sebe N (2020) The unmanned aerial vehicle benchmark: Object detection, tracking and baseline. Int J Comput Vis 128(5):1141–1159CrossRef
3.
Zhou F, Hu RQ, Li Z, Wang Y (2020) Mobile edge computing in unmanned aerial vehicle networks. IEEE Wirel Commun 27(1):140–146CrossRef
4.
Zhao W, Liu H, Lewis FL, Wang X (2021) Data-driven optimal formation control for quadrotor team with unknown dynamics. IEEE Trans Cybern
5.
Labbadi M, Cherkaoui M (2020) Robust adaptive nonsingular fast terminal sliding-mode tracking control for an uncertain quadrotor uav subjected to disturbances. ISA Trans 99:290–304CrossRef
6.
Zhang X, Wang Y, Zhu G, Chen X, Li Z, Wang C, Su CY (2020) Compound adaptive fuzzy quantized control for quadrotor and its experimental verification. IEEE Trans Cybern
7.
8.
Nemati A, Kumar M (2014) Modeling and control of a single axis tilting quadcopter. In: American Control Conf. IEEE pp. 3077–3082
9.
Ji R, Ma J, Ge SS (2019) Modeling and control of a tilting quadcopter. IEEE Trans Aerosp Electron Syst 56(4):2823–2834CrossRef
10.
11.
Romero H, Salazar S, Sanchez A, Lozano R (2007) A new uav configuration having eight rotors: dynamical model and real-time control. In: 2007 46th IEEE conference on decision and control. IEEE, pp. 6418–6423
12.
Giménez R (2020) Research on a quad tilt wing uav, Ph.D. dissertation
13.
Anderson RB, Marshall JA, L’Afflitto A (2020) Constrained robust model reference adaptive control of a tilt-rotor quadcopter pulling an unmodeled cart. IEEE Trans Aerosp Electron Syst
14.
Simmons BM, Murphy PC (2021) Wind tunnel-based aerodynamic model identification for a tilt-wing, distributed electric propulsion aircraft. In: AIAA SciTech 2021 Forum, 2021, p. 1298
15.
Ryll M, Bülthoff HH, Giordano PR (2012) Modeling and control of a quadrotor uav with tilting propellers. In: IEEE international conference on robotics and automation. IEEE, pp. 4606–4613
16.
Ryll M, Bülthoff HH, Giordano PR (2013) First flight tests for a quadrotor uav with tilting propellers. In: 2013 IEEE International Conference on Robotics and Automation. IEEE, pp. 295–302
17.
Oosedo A, Abiko S, Narasaki S, Kuno A, Konno A, Uchiyama M (2016) Large attitude change flight of a quad tilt rotor unmanned aerial vehicle. Adv. Robotics 30(5):326–337CrossRef
18.
Segui-Gasco P, Al-Rihani Y, Shin H-S, Savvaris A (2014) A novel actuation concept for a multi rotor uav. J. Intell. Robotic Syst. 74(1–2):173–191CrossRef
19.
Elfeky M, Elshafei M, Saif A-WA, Al-Malki MF (2016) Modeling and simulation of quadrotor uav with tilting rotors. Int J Control Autom Syst 14(4):1047–1055CrossRef
20.
Bin Junaid A, Diaz De Cerio, Sanchez A, Betancor Bosch J, Vitzilaios N, Zweiri Y (2018) Design and implementation of a dual-axis tilting quadcopter. Robotics 7(4):65CrossRef
21.
Freddi A, Lanzon A, Longhi S (2011) A feedback linearization approach to fault tolerance in quadrotor vehicles. IFAC Proc Vol 44(1):5413–5418CrossRef
22.
23.
Badr S, Mehrez O, Kabeel A (2016) A novel modification for a quadrotor design. In: 2016 international conference on unmanned aircraft systems. IEEE, pp. 702–710
24.
Nemati A, Kumar M (2014) Non-linear control of tilting-quadcopter using feedback linearization based motion control. In: ASME dynamic systems and control conference. American Society of Mechanical Engineers, pp. V003T48A005–V003T48A005
25.
Alkamachi A, Ercelebi E (2018) H\(\infty\) control of an overactuated tilt rotors quadcopter. J Cent South Univ 25(3):586–599CrossRef
26.
Yih CC (2016) Flight control of a tilt-rotor quadcopter via sliding mode. In: 2016 international automatic control conference (CACS). IEEE, pp. 65–70
27.
Nemati A, Kumar R, Kumar M (2020) Stability and control of tilting-rotor quadcopter in case of a propeller failure. In: American control conference (ACC)
28.
Wang T, Wang J, Wu C, Zhao M, Ge T (2018) Disturbance-rejection control for the hover and transition modes of a negative-buoyancy quad tilt-rotor autonomous underwater vehicle. Appl Sci 8(12):2459CrossRef
29.
Papachristos C, Alexis K, Tzes A (2016) Dual-authority thrust-vectoring of a tri-tiltrotor employing model predictive control. J Intell Robotic Syst 81(3–4):471–504CrossRef
30.
Tran AT, Sakamoto N, Sato M, Muraoka K (2017) Control augmentation system design for quad-tilt-wing unmanned aerial vehicle via robust output regulation method. IEEE Trans Aerosp Electron Syst 53(1):357–369CrossRef
31.
Ryll M, Bülthoff HH, Giordano PR (2014) A novel overactuated quadrotor unmanned aerial vehicle: Modeling, control, and experimental validation. IEEE Trans Control Syst Technol 23(2):540–556CrossRef
32.
Ioannou PA, Sun J (2012) Robust adaptive control. Courier Corporation
33.
Slotine JJE, Li W et al (1991) Applied nonlinear control. Prentice hall Englewood Cliffs, NJMATH
34.
Wang S, Na J (2020) Parameter estimation and adaptive control for servo mechanisms with friction compensation. IEEE Trans Industr Inf 16(11):6816–6825CrossRef
35.
Mofid O, Mobayen S (2018) Adaptive sliding mode control for finite-time stability of quad-rotor uavs with parametric uncertainties. ISA Trans 72:1–14CrossRef
36.
Tran T-T, Ge SS, He W (2018) Adaptive control of a quadrotor aerial vehicle with input constraints and uncertain parameters. Int J Control 91(5):1140–1160MathSciNetMATHCrossRef
37.
Wang B, Yu X, Mu L, Zhang Y (2019) Disturbance observer-based adaptive fault-tolerant control for a quadrotor helicopter subject to parametric uncertainties and external disturbances. Mech Syst Signal Process 120:727–743CrossRef
38.
Tong S, Li Y, Shi P (2012) Observer-based adaptive fuzzy backstepping output feedback control of uncertain mimo pure-feedback nonlinear systems. IEEE Trans Fuzzy Syst 20(4):771–785CrossRef
39.
Ding S, Li S, Zheng WX (2012) Nonsmooth stabilization of a class of nonlinear cascaded systems. Automatica 48(10):2597–2606MathSciNetMATHCrossRef
40.
Yang C, Jiang Y, Na J, Li Z, Cheng L, Su C-Y (2018) Finite-time convergence adaptive fuzzy control for dual-arm robot with unknown kinematics and dynamics. IEEE Trans Fuzzy Syst 27(3):574–588CrossRef
41.
Wang H, Liu PX, Zhao X, Liu X (2019) Adaptive fuzzy finite-time control of nonlinear systems with actuator faults. IEEE Trans Cybern
42.
Wu J, Chen W, Li J (2016) Global finite-time adaptive stabilization for nonlinear systems with multiple unknown control directions. Automatica 69:298–307MathSciNetMATHCrossRef
43.
Chen B, Liu XP, Ge SS, Lin C (2012) Adaptive fuzzy control of a class of nonlinear systems by fuzzy approximation approach. IEEE Trans Fuzzy Syst 20(6):1012–1021CrossRef
44.
Yang Y, Hua C, Guan X (2013) Adaptive fuzzy finite-time coordination control for networked nonlinear bilateral teleoperation system. IEEE Trans Fuzzy Syst 22(3):631–641CrossRef
45.
Xu P, Li Y, Tong S (2019) Fuzzy adaptive finite time fault-tolerant control for multi-input and multi-output nonlinear systems with actuator faults. Int J Control Autom Syst 17(7):1655–1665CrossRef
46.
Jiang F, Pourpanah F, Hao Q (2019) Design, implementation and evaluation of a neural network based quadcopter uav system. IEEE Trans Indu Electron 67(3):2076–2085CrossRef
47.
He W, Sun Y, Yan Z, Yang C, Li Z, Kaynak O (2019) Disturbance observer-based neural network control of cooperative multiple manipulators with input saturation. IEEE Trans Neural Netw Learn Syst 1(5):1735–1746MathSciNetCrossRef
48.
Na J, Wang S, Liu YJ, Huang Y, Ren X (2019) Finite-time convergence adaptive neural network control for nonlinear servo systems. IEEE Trans Cybern 50(6):2568–2579CrossRef
49.
50.
Ji R, Ma J, Li D, Ge SS (2020) Finite-time adaptive output feedback control for mimo nonlinear systems with actuator faults and saturations. IEEE Trans Fuzzy Syst
51.
Han Y, Yu J, Zhao L, Yu H, Lin C (2018) Finite-time adaptive fuzzy control for induction motors with input saturation based on command filtering. IET Control Theory Appl 12(15):2148–2155MathSciNetCrossRef
52.
Zhang J, Ren Z, Deng C, Wen B (2019) Adaptive fuzzy global sliding mode control for trajectory tracking of quadrotor uavs. Nonlinear Dyn 1–19
53.
Chowdhary G, Yucelen T, Mühlegg M, Johnson EN (2013) Concurrent learning adaptive control of linear systems with exponentially convergent bounds. Int J Adapt Control Signal Process 27(4):280–301MathSciNetMATHCrossRef
54.
Hsu L, Costa R (1987) Bursting phenomena in continuous-time adaptive systems with a \(\sigma\)-modification. IEEE Trans Autom Control 32(1):84–86MathSciNetMATHCrossRef
55.
Liu YJ, Lu S, Tong S, Chen X, Chen CP, Li D-J (2018) Adaptive control-based barrier lyapunov functions for a class of stochastic nonlinear systems with full state constraints. Automatica 87:83–93MathSciNetMATHCrossRef
56.
Wu J, Hu Y, Huang Y (2021) Indirect adaptive robust control of nonstrict feedback nonlinear systems by a fuzzy approximation strategy. ISA Trans 108:10–17CrossRef
57.
Zhao D, Wang Y, Xu L, Wu H (2021) Adaptive robust control for a class of uncertain neutral systems with time delays and nonlinear uncertainties. Int J Control Autom Syst 1–13
58.
Zhang X, Lu Z, Yuan X, Wang Y, Xuejun S (2020) L2-gain adaptive robust control for hybrid energy storage system in electric vehicles. IEEE Trans Power Electron
59.
Sun W, Wu YQ, Sun ZY (2020) Command filter-based finite-time adaptive fuzzy control for uncertain nonlinear systems with prescribed performance. IEEE Trans Fuzzy Syst 28(12):3161–3170CrossRef
60.
Zhao NN, Ouyang XY, Wu LB, Shi FR (2021) Event-triggered adaptive prescribed performance control of uncertain nonlinear systems with unknown control directions. ISA Trans 108:121–130CrossRef
61.
Zhang G, Chen J, Li Z (2009) An adaptive robust control for linear motors based on composite adaptation. Control Theory Appl 26(8):833–837
62.
Adetola V, Guay M (2008) Finite-time parameter estimation in adaptive control of nonlinear systems. IEEE Trans Autom Control 53(3):807–811MathSciNetMATHCrossRef
63.
Adetola V, Guay M (2010) Performance improvement in adaptive control of linearly parameterized nonlinear systems. IEEE Trans Autom Control 55(9):2182–2186MathSciNetMATHCrossRef
64.
Xia Y, Zhang J, Lu K, Zhou N (2019) Adaptive attitude tracking control for rigid spacecraft with finite-time convergence. Finite time and cooperative control of flight vehicles. Springer, New York, pp 51–69MATH
65.
Owolabi KM, Atangana A, Akgul A (2020) Modelling and analysis of fractal-fractional partial differential equations: application to reaction-diffusion model. Alex Eng J 59(4):2477–2490CrossRef
66.
Akgül A (2018) A novel method for a fractional derivative with non-local and non-singular kernel. Chaos Solitons Fractals 114:478–482MathSciNetMATHCrossRef
67.
Atangana A, Akgül A, Owolabi KM (2020) Analysis of fractal fractional differential equations. Alex Eng J 59(3):1117–1134CrossRef
68.
Atangana A, Akgül A (2020) Can transfer function and bode diagram be obtained from sumudu transform. Alex Eng J 59(4):1971–1984CrossRef
69.
Akgül EK (2019) Solutions of the linear and nonlinear differential equations within the generalized fractional derivatives. Chaos Interdiscip J Nonlinear Sci 29(2):023108MathSciNetMATHCrossRef
70.
Atangana A, Akgül A (2020) Analysis of new trends of fractional differential equations. Fract Order Anal Theory Methods Appl 91–111, 2020
71.
Atangana A, Akgül A (2020) On solutions of fractal fractional differential equations. Discrete Contin Dyn Syst-S
72.
Sun ZY, Shao Y, Chen CC, Meng Q (2018) Global output-feedback stabilization for stochastic nonlinear systems: a double-domination approach. Int J Robust Nonlinear Control 28(15):4635–4646MathSciNetMATH
73.
Du H, Li S (2012) Finite-time attitude stabilization for a spacecraft using homogeneous method. J. Guidance Control Dyn 35(3):740–748CrossRef
74.
Venkataraman S, Gulati S (1991) Terminal sliding modes: a new approach to nonlinear control synthesis. In: Fifth international conference on advanced robotics’ robots in unstructured environments. IEEE, pp. 443–448
75.
76.
Yu X, Zhihong M (2002) Fast terminal sliding-mode control design for nonlinear dynamical systems. IEEE Trans Circuits Syst I Fundam Theory Appl 49(2):261–264MathSciNetMATHCrossRef
77.
Lu K, Xia Y (2013) Adaptive attitude tracking control for rigid spacecraft with finite-time convergence. Automatica 49(12):3591–3599MathSciNetMATHCrossRef
78.
Moulay E, Perruquetti W (2008) Finite time stability conditions for non-autonomous continuous systems. Int J Control 81(5):797–803MathSciNetMATHCrossRef
79.
Sun ZY, Shao Y, Chen CC (2019) Fast finite-time stability and its application in adaptive control of high-order nonlinear system. Automatica 106:339–348MathSciNetMATHCrossRef
80.
Yu S, Yu X, Shirinzadeh B, Man Z (2005) Continuous finite-time control for robotic manipulators with terminal sliding mode. Automatica 41(11):1957–1964MathSciNetMATHCrossRef
81.
Badr S, Mehrez O, Kabeel A (2019) A design modification for a quadrotor uav: modeling, control and implementation. Adv Robot 33(1):13–32CrossRef
82.
Odelga M, Stegagno P, Bülthoff HH (2016) A fully actuated quadrotor uav with a propeller tilting mechanism: modeling and control. In 2016 IEEE international conference on advanced intelligent mechatronics (AIM). IEEE, pp. 306–311
83.
Diogenes HB, dos Santos DA (2016) Modelling, design and simulation of a quadrotor with tilting rotors actuated by a memory shape wire. In: Congresso brasileiro de engenharia mecnica (CONEM)
84.
Xia J, Zhang J, Sun W, Zhang B, Wang Z (2018) Finite-time adaptive fuzzy control for nonlinear systems with full state constraints. IEEE Trans Syst Man Cybern Syst 99:1–8
85.
Qian C, Lin W (2001) A continuous feedback approach to global strong stabilization of nonlinear systems. IEEE Trans Autom Control 46(7):1061–1079MathSciNetMATHCrossRef
86.
Ge SS, Wang C (2004) Adaptive neural control of uncertain mimo nonlinear systems. IEEE Trans Neural Netw 15(3):674–692CrossRef
87.
Lv W, Wang F (2018) Finite-time adaptive fuzzy tracking control for a class of nonlinear systems with unknown hysteresis. Int J Fuzzy Syst 20(3):782–790MathSciNetCrossRef
88.
Na J (2013) Adaptive prescribed performance control of nonlinear systems with unknown dead zone. Int J Adapt Control Signal Process 27(5):426–446MathSciNetMATHCrossRef
89.
Skjetne R, Fossen TI (2004) On integral control in backstepping: analysis of different techniques. In: Proceedings of the 2004 American control conference, vol 2. IEEE, pp. 1899–1904
Metadaten
Titel
Adaptive neural control for a tilting quadcopter with finite-time convergence
verfasst von
Meichen Liu
Ruihang Ji
Shuzhi Sam Ge
Fellow, IEEE
Publikationsdatum
18.06.2021
Verlag
Springer London
Erschienen in
Neural Computing and Applications / Ausgabe 23/2021
Print ISSN: 0941-0643
Elektronische ISSN: 1433-3058
DOI
https://doi.org/10.1007/s00521-021-06215-z

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