无人机集群吊挂的预设性能抗干扰协同控制-自主智能无人系统专刊

doi:10.7527/S1000-6893.2026.33184

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无人机集群吊挂的预设性能抗干扰协同控制-自主智能无人系统专刊

陈欣宇¹,李海旭²,张霄宁¹,刘鹏¹,范云生¹

1. 大连海事大学
2. 中国船舶集团系统工程研究院

收稿日期:2025-12-03 修回日期:2026-04-08 出版日期:2026-04-09 发布日期:2026-04-09
通讯作者: 范云生
基金资助:
国家基础科研重点项目;国家重点研发计划项目;国家自然科学基金项目;辽宁省中试基地中试验证类科技项目;大连市揭榜挂帅技术攻关项目;中央高校基本科研业务费专项基金资金

Prescribed Performance and Anti-Disturbance Formation Control for Multi-UAV Cooperative Slung-Load System

Received:2025-12-03 Revised:2026-04-08 Online:2026-04-09 Published:2026-04-09

摘要/Abstract

摘要： 针对无人机集群吊挂系统在执行器故障、输入饱和及负载质量变化等内部状态约束，以及风场扰动和下洗气流等外部扰动作用下的多机协同稳定控制问题，提出了一种基于改进预设性能控制（Improved Prescribed Performance Control, IPPC）、积分反步滑模控制与扩展干扰观测器（Extended Disturbance Observer, EDO）相结合的集群吊挂抗干扰协同控制方法。首先，利用Udwadia-Kalaba方程建立了无人机集群吊挂系统的约束动力学模型，实现了无人机集群协同与吊挂负载之间的解耦。其次，基于图论方法将吊挂负载等效为虚拟领航者，设计无人机集群的期望轨迹，以实现系统在空间上的一致性与协同性。同时引入改进预设性能控制策略，将系统误差动态约束在预定范围内，从而有效防止无人机间的碰撞并保持协同控制的稳定性。进一步地，设计了积分反步滑模控制器，结合EDO对模型不确定性和外部扰动进行在线估计与补偿，提高了系统的鲁棒性与抗干扰能力。最后，通过李雅普诺夫稳定性分析严格证明了所提控制策略的全局稳定性，并通过仿真实验验证了该方法在执行器故障、输入饱和及风场干扰条件下的优越跟踪性能与协同控制效果。

关键词: 无人机集群, 协同吊挂, 预设性能控制, 积分反步滑模控制, 扩展干扰观测器

Abstract: In this paper, a cooperative control strategy that integrates Improved Prescribed Performance Control (IPPC), Integral Backstepping Sliding Mode Control (IBSMC), and an Extended Disturbance Observer (EDO) is proposed to address the stable control problem of a multi-UAV cooperative slung-load system subject to internal state constraints, such as actuator faults, input saturation, and varying payload mass, as well as external disturbances including wind field effects and downwash airflow. First, the Udwadia–Kalaba equation is employed to establish the constrained dynamic model of the multi-UAV cooperative slung-load system, accurately capturing the coupling relationship between the quadrotors and the slung-load. Then, based on graph theory, the slung-load is regarded as a virtual leader, and the desired trajectories of each quadrotor are generated to ensure spatial consistency and coordination of the system. Meanwhile, an improved prescribed performance control strategy is introduced to dynamically constrain the system error within predefined bounds, effectively preventing inter-quadrotor collisions and maintaining formation stability. Furthermore, an integral backstepping sliding mode controller is designed and combined with the EDO to achieve online estimation and compensation of model uncertainties and external disturbances, thereby enhancing the system’s robustness and disturbance rejection capability. Finally, Lyapunov-based stability analysis rigorously proves the global stability of the proposed control strategy, and simulation results demonstrate its superior tracking accuracy and cooperative performance under actuator faults, input saturation, and wind field disturbances.

Key words: Multi-UAV, cooperative slung-load, prescribed performance control, integral backstepping sliding mode control, extended disturbance observer

中图分类号:

陈欣宇李海旭张霄宁刘鹏范云生. 无人机集群吊挂的预设性能抗干扰协同控制-自主智能无人系统专刊[J]. 航空学报, doi: 10.7527/S1000-6893.2026.33184.

参考文献

[1] SONG X, WU C, SONG S, et al. Fuzzy wavelet neural adaptive finite-time self-triggered fault-tolerant control for a quadrotor unmanned aerial vehicle with scheduled performance[J]. Engineering Applications of Artificial Intelligence, 2024, 131: 107832.
[2] LI B, LIU H, AHN C K, et al. Optimized intelligent tracking control for a quadrotor unmanned aerial vehicle with actuator failures[J]. Aerospace Science and Technology, 2024, 144: 108803.
[3] 陈涛,陈建.基于学习观测器的无人机故障弹性容错控制[J].航空学报,2025,46(11):485-497.
CHEN T, CHEN J. Learning-observer-based resilient fault-tolerant control for quadrotor unmanned aerial vehicles[J]. Acta Aeronautica et Astronautica Sinica, 2025, 46(11):485-497 (in Chinese).
[4] HAMROUNI A, GHAZZAI H, MENOUAR H, et al. Multi-rotor UAVs in crowd management systems: Opportunities and challenges[J]. IEEE Internet of Things Magazine, 2023, 6(4): 74-80.
[5] REJEB A, REJEB K, SIMSKE S J, et al. Drones for supply chain management and logistics: a review and research agenda[J]. International Journal of Logistics Research and Applications, 2023, 26(6): 708-731.
[6] CHEN H, LAN Y, FRITZ B K, et al. Review of agricultural spraying technologies for plant protection using unmanned aerial vehicle (UAV)[J]. International Journal of Agricultural and Biological Engineering, 2021, 14(1): 38-49.
[7] 郭洪振,陈谋,戴永东,等.分布式自适应事件触发四旋翼无人机编队控制[J].航空学报,2023,44(S2):491-500.
GUO H Z, CHEN M, DAI Y D, et al. Distributed adaptive event-triggered formation control for QUAVs[J]. Acta Aeronautica et Astronautica Sinica,2023,44(S2): 729917 (in Chinese).
[8] DING F, HUANG J, SUN C, et al. Adaptive dynamic surface control for quadrotor-slung load transportation system with uncertainties[J]. Science China Technological Sciences, 2023, 66(10): 2917-2929.
[9] PERIS C, NORTON M, KHOO S. Adaptive multi-surface sliding mode control with radial basis function neural networks and reinforcement learning for multirotor slung load systems[J]. Electronics, 2024, 13(12): 2424.
[10] 梁潇,刘冰冰,叶慧樱,等.旋翼无人机吊运系统研究综述[J].控制与决策,2025,40(04):1079-1097.
LIANG X, LIU B B, YE H Y, et al. A review of research on cable-suspended payload transportation systemsby rotorcraft unmanned aerial vehicles[J]. Control and Decision, 2025,40(04):1079-1097 (in Chinese).
[11] YANG S, XIAN B, CAI J, et al. Finite-time convergence control for a quadrotor unmanned aerial vehicle with a slung load[J]. IEEE Transactions on Industrial Informatics, 2023, 20(1): 605-614.
[12] ARIYIBI S O, TEKINALP O. Quaternion-based nonlinear attitude control of quadrotor formations carrying a slung load[J]. Aerospace Science and Technology, 2020, 105: 105995.
[13] JACKSON B E, HOWELL T A, SHAH K, et al. Scalable cooperative transport of cable-suspended loads with UAVs using distributed trajectory optimization[J]. IEEE Robotics and Automation Letters, 2020, 5(2): 3368-3374.
[14] LIANG X, ZHANG Z, YU H, et al. Antiswing control for aerial transportation of the suspended cargo by dual quadrotor UAVs[J]. IEEE/ASME Transactions on Mechatronics, 2022, 27(6): 5159-5172.
[15] MOREIRA M S M, VILLA D K D, SARCINELLI-FILHO M. Null space-based behavioral control applied to a formation of two quadrotors transporting a cable suspended load[J]. ISA transactions, 2025, 156: 620-631.
[16] LEE T, SREENATH K, KUMAR V. Geometric control of cooperating multiple quadrotor UAVs with a suspended payload[C]//52nd IEEE conference on decision and control. IEEE, 2013: 5510-5515.
[17] TAN Y H, LAI S, WANG K, et al. Cooperative control of multiple unmanned aerial systems for heavy duty carrying[J]. Annual Reviews in Control, 2018, 46: 44-57.
[18] CARDONA G A, TELLEZ-CASTRO D, MOJICA-NAVA E. Cooperative transportation of a cable-suspended load by multiple quadrotors[J]. IFAC-PapersOnLine, 2019, 52(20): 145-150.
[19] LI X, ZHANG J, HAN J. Trajectory planning of load transportation with multi-quadrotors based on reinforcement learning algorithm[J]. Aerospace Science and Technology, 2021, 116: 106887.
[20] JIN X, HU Z. Constrained load transportation by a team of quadrotors[C]//2022 IEEE 61st Conference on Decision and Control (CDC). IEEE, 2022: 6580-6585.
[21] UDWADIA F E, KALABA R E. A new perspective on constrained motion[J]. Proceedings of the Royal Society of London. Series A: Mathematical and Physical Sciences, 1992, 439(1906): 407-410.
[22] UDWADIA F E, KALABA R E. On the foundations of analytical dynamics[J]. International Journal of non-linear mechanics, 2002, 37(6): 1079-1090.
[23] KLAUSEN K, MEISSEN C, FOSSEN T I, et al. Cooperative control for multirotors transporting an unknown suspended load under environmental disturbances[J]. IEEE Transactions on Control Systems Technology, 2018, 28(2): 653-660.
[24] SHIRANI B, NAJAFI M, IZADI I. Cooperative load transportation using multiple UAVs[J]. Aerospace Science and Technology, 2019, 84: 158-169.
[25] LI Z, HAN L, DONG X, et al. Observer based control for load transportation system using multiple quadrotors[C]//2021 China Automation Congress (CAC). IEEE, 2021: 6995-7000.
[26] ARAB F, SHIRAZI F A, YAZDI M R H. Planning and distributed control for cooperative transportation of a non-uniform slung-load by multiple quadrotors[J]. Aerospace Science and Technology, 2021, 117: 106917.
[27] LIANG X, SU Z, ZHOU W, et al. Fault-tolerant control for the multi-quadrotors cooperative transportation under suspension failures[J]. Aerospace Science and Technology, 2021, 119: 107139.
[28] 范云生,陈欣宇,赵永生,等.基于扩张状态观测器的四旋翼吊挂飞行系统非线性控制[J].自动化学报,2023,49(08):1758-1770.
FAN Y, CHEN X, ZHAO Y, et al. Nonlinear Control of Quadrotor Suspension System Based on Extended State Observer[J]. Acta Automatica Sinica, 2023, 49(8): 1758-1770(in Chinese).
[29] CHEN X, FAN Y, WANG G, et al. Improved extended disturbance observer-based integral backstepping sliding mode control for quadrotor slung-load system[J]. Aerospace Science and Technology, 2025, 160: 110042.
[30] ARAB F, SHIRAZI F A, YAZDI M R H. Planning and distributed control for cooperative transportation of a non-uniform slung-load by multiple quadrotors[J]. Aerospace Science and Technology, 2021, 117: 106917.

E-mail：hkxb@buaa.edu.cn

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主管单位：中国科学技术协会主办单位：中国航空学会北京航空航天大学

无人机集群吊挂的预设性能抗干扰协同控制-自主智能无人系统专刊

Prescribed Performance and Anti-Disturbance Formation Control for Multi-UAV Cooperative Slung-Load System

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