Tower cranes are typical underactuated systems, characterized by high-state coupling and lack of available control inputs, resulting in major challenges for the dynamics analysis. A dynamic model of tower cranes without simplifications is established, where the nonlinearities, unknown frictions, and wind disturbances are emphatically considered. Based on the developed model, an adaptive robust sliding mode control (ARSMC) scheme is proposed, which can achieve accurate payload positioning and sufficient swings suppression, even in the presence of unknown frictions and wind disturbances. Specifically, a sliding mode surface and a suppression function are designed to eliminate payload swings; a sliding mode convergence law is constructed to alleviate the chattering problem; the robustness of the controller is enhanced by designing an estimation strategy of wind disturbances; an effective parameter estimation is presented to improve the adaptive ability of unknown parameters. The stability of the closed-loop system is proved by utilizing the Lyapunov technique and LaSalle’s invariance principle. Finally, the effectiveness of the tower crane model and the superiority of the ARSMC are verified by multiple comparative simulations.
AboserreLTEl-BadawyAA (2021) Robust integral sliding mode control of tower cranes. Journal of Vibration and Control27: 1171–1183.
2.
BockMKugiA (2014) Real-time nonlinear model predictive path-following control of a laboratory tower crane. IEEE Transactions on Control Systems Technology22: 1461–1473.
3.
ChenHFangYSunN (2019) An adaptive tracking control method with swing suppression for 4-DOF tower crane systems. Mechanical Systems and Signal Processing123: 426–442.
4.
Coral-EnriquezHPulido-GuerreroSCortés-RomeroJ (2019) Robust disturbance rejection based control with extended-state resonant observer for sway reduction in uncertain tower-cranes. International Journal of Automation and Computing16: 812–827.
5.
FasihUrRehmanSMMohamedZHusainAR, et al. (2022) Input shaping with an adaptive scheme for swing control of an underactuated tower crane under payload hoisting and mass variations. Mechanical Systems and Signal Processing175: 109106.
6.
GuXZhouHHongM, et al. (2022) Adaptive hierarchical sliding mode controller for tower cranes based on finite time disturbance observer. International Journal of Adaptive Control and Signal Processing36: 2319–2340.
7.
GutierrezRMagallonMHernandezDC (2021) Vision-based system for 3D tower crane monitoring. IEEE Sensors Journal21: 11935–11945.
8.
HuangJZhaoZ (2023) Synchronous slew/translation positioning and swing suppression control for 4-DOF tower crane system. Transactions of the Institute of Measurement and Control45: 3077–3091.
9.
IlešŠMatuškoJKolonićF (2018) Sequential distributed predictive control of a 3D tower crane. Control Engineering Practice79: 22–35.
10.
LeATLeeS (2017) 3D cooperative control of tower cranes using robust adaptive techniques. Journal of the Franklin Institute354: 8333–8357.
11.
LeTADangVKoDH, et al. (2013) Nonlinear controls of a rotating tower crane in conjunction with trolley motion. Proceedings of the Institution of Mechanical Engineers, Part I: Journal of Systems and Control Engineering227: 451–460.
12.
LiuZSunNWuY, et al. (2021) Nonlinear sliding mode tracking control of underactuated tower cranes. International Journal of Control, Automation and Systems19: 1065–1077.
13.
LiuZYangTSunN, et al. (2019) An antiswing trajectory planning method with state constraints for 4-DOF tower cranes: Design and experiments. IEEE Access7: 62142–62151.
14.
LuBFangYSunN (2017) Sliding mode control for underactuated overhead cranes suffering from both matched and unmatched disturbances. Mechatronics47: 116–125.
15.
NguyenVTYangCDuC, et al. (2022) Design and implementation of finite time sliding mode controller for fuzzy overhead crane system. ISA Transactions124: 374–385.
16.
OuyangHTianZYuL, et al. (2020a) Load swing rejection for double-pendulum tower cranes using energy-shaping-based control with actuator output limitation. ISA Transactions101: 246–255.
17.
OuyangHTianZYuL, et al. (2020b) Motion planning approach for payload swing reduction in tower cranes with double-pendulum effect. Journal of the Franklin Institute357: 8299–8320.
18.
OuyangHXuXZhangG (2020c) Energy-shaping-based nonlinear controller design for rotary cranes with double-pendulum effect considering actuator saturation. Automation in Construction111: 103054.
19.
RamliLMohamedZAbdullahiAM, et al. (2017) Control strategies for crane systems: A comprehensive review. Mechanical Systems and Signal Processing95: 1–23.
20.
ShiHHuangJBaiX, et al. (2021) Nonlinear anti-swing control of underactuated tower crane based on improved energy function. International Journal of Control, Automation and Systems19: 3967–3982.
21.
SunNFangYChenH, et al. (2016) Slew/translation positioning and swing suppression for 4-DOF tower cranes with parametric uncertainties: Design and hardware experimentation. IEEE Transactions on Industrial Electronics63: 6407–6418.
22.
SunZOuyangH (2022) Adaptive fuzzy tracking control for vibration suppression of tower crane with distributed payload mass. Automation in Construction142: 104521.
23.
TianZYuLOuyangH, et al. (2021) Sway and disturbance rejection control for varying rope tower cranes suffering from friction and unknown payload mass. Nonlinear Dynamics105: 3149–3165.
24.
TuanLA (2021) Neural observer and adaptive fractional-order backstepping fast-terminal sliding-mode control of RTG cranes. IEEE Transactions on Industrial Electronics68: 434–442.
25.
Van TrieuPCuongHMDongHQ, et al. (2021) Adaptive fractional-order fast terminal sliding mode with fault-tolerant control for underactuated mechanical systems: Application to tower cranes. Automation in Construction123: 103533.
26.
WuTKarkoubMYuW, et al. (2016) Anti-sway tracking control of tower cranes with delayed uncertainty using a robust adaptive fuzzy control. Fuzzy Sets and Systems290: 118–137.
27.
WuYSunNChenH, et al. (2021) Adaptive output feedback control for 5-DOF varying-cable-length tower cranes with cargo mass estimation. IEEE Transactions on Industrial Informatics17: 2453–2464.
28.
YangTSunNChenH, et al. (2020) Neural network-based adaptive antiswing control of an underactuated ship-mounted crane with roll motions and input dead zones. IEEE Transactions on Neural Networks and Learning Systems31: 901–914.
29.
YangTSunNChenH, et al. (2021) Observer-based nonlinear control for tower cranes suffering from uncertain friction and actuator constraints with experimental verification. IEEE Transactions on Industrial Electronics68: 6192–6204.
30.
YeJHuangJ (2021) Analytical analysis and oscillation control of payload twisting dynamics in a tower crane carrying a slender payload. Mechanical Systems and Signal Processing158: 107763.
31.
ZhangMJingXZhuZ (2021) Disturbance employment-based sliding mode control for 4-DOF tower crane systems. Mechanical Systems and Signal Processing161: 107946.
32.
ZhangMZhangYChenH, et al. (2019) Model-independent PD-SMC method with payload swing suppression for 3D overhead crane systems. Mechanical Systems and Signal Processing129: 381–393.
33.
ZhangMZhangYJiB, et al. (2020a) Adaptive sway reduction for tower crane systems with varying cable lengths. Automation in Construction119: 103342.
34.
ZhangMZhangYOuyangH, et al. (2020b) Adaptive integral sliding mode control with payload sway reduction for 4-DOF tower crane systems. Nonlinear Dynamics99: 2727–2741.
35.
ZhangWChenHYaoX, et al. (2022) Adaptive tracking of double pendulum crane with payload hoisting/lowering. Automation in Construction141: 104368.
