一种无人机⁃无人车编队系统容错控制方法

doi:10.7527/S1000-6893.2022.27216

Abstract

Abstract:

To compensate for the problem of communication link additive faults of Unmanned Aerial Vehicles (UAVs)-Unmanned Ground Vehicles (UGVs) formation system, a fault-tolerant formation control algorithm is proposed based on distributed adaptive observers. The models of quad-rotor UAV and two-wheeled mobile robot control systems are transformed, and the model for the UAVs-UGVs formation system is further constructed. Based on the "virtual leader-followers" topology, distributed adaptive observers are designed by using the local information of adjacent agents to realize the observation of virtual leader's states with communication link additive faults. The adaptive fault-tolerant formation controllers of UAVs-UGVs system are designed based on the backstepping method. Finally, the effectiveness of the designed observers and controllers is verified by simulation of the formation system composed of three quad-rotor UAVs and three two-wheeled mobile robots.

Key words: heterogeneous multi-agent system, UAVs-UGVs formation system, communication link additive fault, fault-tolerant formation tracking, adaptive control

CLC Number:

V219

Yajie MA, Juan WANG, Bin JIANG, Jianye GONG. A fault⁃tolerant control scheme for UAVs-UGVs formation systems[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2023, 44(8): 327216-327216.

Figures/Tables 12

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References 26

1	TANNER H G， JADBABAIE A， PAPPAS G J. Stable flocking of mobile agents， Part I： Fixed topology［C］∥ 42nd IEEE International Conference on Decision and Control （IEEE Cat. No.03CH37475）. Piscataway： IEEE Press， 2004： 2010-2015.
2	ZHOU N， CHENG X D， XIA Y Q， et al. Fully adaptive-gain-based intelligent failure-tolerant control for spacecraft attitude stabilization under actuator saturation［J］. IEEE Transactions on Cybernetics， 2022， 52（1）： 344-356.
3	陈严波，黄金龙，汪志军，等. 基于有向图的蜂群无人机故障影响［J］. 航空学报， 2020， 41（S2）： 724287.
	CHEN Y B， HUANG J L， WANG Z J， et al. Influences of drone swarm failure based on directed graph［J］. Acta Aeronautica et Astronautica Sinica， 2020， 41（S2）： 724287 （in Chinese）.
4	CHEN H T， YI H， JIANG B， et al. Data-driven detection of hot spots in photovoltaic energy systems［J］. IEEE Transactions on Systems， Man， and Cybernetics： Systems， 2019， 49（8）： 1731-1738.
5	LI F， DING Y S， ZHOU M C， et al. An affection-based dynamic leader selection model for formation control in multirobot systems［J］. IEEE Transactions on Systems， Man， and Cybernetics： Systems， 2017， 47（7）： 1217-1228.
6	张普，薛惠锋，高山. 基于分布式自适应的多智能体容错一致性控制［J］. 航空学报， 2020， 41（3）： 323539.
	ZHANG P， XUE H F， GAO S. Distributed adaptive fault-tolerance consensus control for multi-agent system［J］. Acta Aeronautica et Astronautica Sinica， 2020， 41（3）： 323539 （in Chinese）.
7	ZUO Z Q， ZHANG J， WANG Y J. Adaptive fault-tolerant tracking control for linear and lipschitz nonlinear multi-agent systems［J］. IEEE Transactions on Industrial Electronics， 2015， 62（6）： 3923-3931.
8	GE X H， HAN Q L， YANG F W. Event-based set-membership leader-following consensus of networked multi-agent systems subject to limited communication resources and unknown-but-bounded noise［J］. IEEE Transactions on Industrial Electronics， 2017， 64（6）： 5045-5054.
9	HOU W Y， FU M Y， ZHANG H S， et al. Consensus conditions for general second-order multi-agent systems with communication delay［J］. Automatica， 2017， 75： 293-298.
10	LI X L， WEN C Y， CHEN C， et al. Adaptive resilient secondary control for microgrids with communication faults［J］. IEEE Transactions on Cybernetics， 2022， 52（8）： 8493-8503.
11	YU L Y， YE D， SUN Z W. Finite-time resilient attitude coordination control for multiple rigid spacecraft with communication link faults［J］. Aerospace Science and Technology， 2021， 111： 106560.
12	郜晨，何潇. 执行器饱和的多智能体一致性控制［J］. 航空学报， 2020， 41（S1）： 110-118.
	GAO C， HE X. Consensus control for multi-agent systems subject to actuator saturations［J］. Acta Aeronautica et Astronautica Sinica， 2020， 41（S1）： 110-118 （in Chinese）.
13	姜斌，张柯，杨浩，等. 卫星姿态控制系统容错控制综述［J］. 航空学报， 2021， 42（11）： 524662.
	JIANG B， ZHANG K， YANG H， et al. Fault-tolerant control of satellite attitude control systems： Review［J］. Acta Aeronautica et Astronautica Sinica， 2021， 42（11）： 524662 （in Chinese）.
14	ZHANG K， JIANG B， SHI P. Adjustable parameter-based distributed fault estimation observer design for multiagent systems with directed graphs［J］. IEEE Transactions on Cybernetics， 2017， 47（2）： 306-314.
15	闫实，吴修振，王帅磊，等. 有向切换拓扑下非线性多智能体系统的一致性控制［J］. 航空学报， 2020， 41（S2）： 724295.
	YAN S， WU X Z， WANG S L， et al. Consensus of nonlinear multi-agent systems with directed switching topologies［J］. Acta Aeronautica et Astronautica Sinica， 2020， 41（S2）： 724295 （in Chinese）.
16	ZHENG D H， ZHANG H B， ZHANG J A， et al Consensus of multi-agent systems with faults and mismatches under switched topologies using a delta operator method［J］. Neurocomputing， 2018， 315： 198-209.
17	QIN J H， GAO H J， YU C B. On discrete-time convergence for general linear multi-agent systems under dynamic topology［J］. IEEE Transactions on Automatic Control， 2014， 59（4）： 1054-1059.
18	曹伟，孙明. 离散时变多智能体系统有限时间一致性迭代学习控制［J］. 控制与决策， 2019， 34（4）： 891-896.
	CAO W， SUN M. Finite-time consensus iterative learning control of discrete time-varying multi-agent systems［J］. Control and Decision， 2019， 34（4）： 891-896 （in Chinese）.
19	YAGHMAIE F A， LEWIS F L， SU R. Output regulation of linear heterogeneous multi-agent systems via output and state feedback［J］. Automatica， 2016， 67： 157-164.
20	田磊，赵启伦，董希旺，等. 异构多智能体系统分组输出时变编队跟踪控制［J］. 航空学报， 2020， 41（7）： 323727.
	TIAN L， ZHAO Q L， DONG X W， et al. Time-varying output group formation tracking for heterogeneous multi-agent systems［J］. Acta Aeronautica et Astronautica Sinica， 2020， 41（7）： 323727 （in Chinese）.
21	HAN J， ZHANG H G， JIANG H， et al. H_∞ consensus for linear heterogeneous multi-agent systems with state and output feedback control［J］. Neurocomputing， 2018， 275： 2635-2644.
22	REN Y， ZHANG K， JIANG B， et al. Distributed fault-tolerant time-varying formation control of heterogeneous multi-agent systems［J］. International Journal of Robust and Nonlinear Control， 2022， 32（5）： 2864-2882.
23	RAHIMI R， ABDOLLAHI F， NAQSHI K. Time-varying formation control of a collaborative heterogeneous multi agent system［J］. Robotics and Autonomous Systems， 2014， 62（12）： 1799-1805.
24	LI Z K， WEN G H， DUAN Z S， et al. Designing fully distributed consensus protocols for linear multi-agent systems with directed graphs［J］. IEEE Transactions on Automatic Control， 2015， 60（4）： 1152-1157.
25	CHEN C， XIE K， LEWIS F L， et al. Adaptive synchronization of multi-agent systems with resilience to communication link faults［J］. Automatica， 2020， 111： 108636.
26	CAI H， LEWIS F L， HU G Q， et al. The adaptive distributed observer approach to the cooperative output regulation of linear multi-agent systems［J］. Automatica， 2017， 75： 299-305.

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A fault⁃tolerant control scheme for UAVs-UGVs formation systems

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