Design and Trajectory Linearization Geometric Control of Multiple Aerial Vehicles Assembly

doi:10.3901/JME.2022.21.016

Abstract

Abstract: An assembly composed of multiple aerial vehicles is capable of achieving omnidirectional motion in SE(3). Meanwhile, such assembly has advantages in payload and fault tolerance capacity compared with a single aircraft. Because of these characteristics, it has the potential to become an ideal platform for manipulation and observation. The mechanism and structure of the assembly aerial platform is designed. Such a platform has the ability to adjust its six-dimensional pose simultaneously. The dynamics of the overall system is investigated. Using singular perturbation theory, the entire system is partitioned into two subsystems, the fast varying system which represents the rotational motion of each aircraft, and the slowly varying system which represents the overall motion of the integrated assembly. Since the configuration space of the aircraft is non-Euclidean space, the controller of the slowly varying subsystem is designed using the trajectory linearization control on the manifold. On this basis, the stability of the overall closed loop system is proved using the Lyapunov theory. The real time communication architecture among the different sub-aircraft is designed. Furthermore, the software and the hardware of the real world protype is developed. Both simulation and real-world tests are conducted, validating the feasibility of the mechanism and control design for the novel assembly containing multiple aerial vehicles proposed.

Key words: aerial vehicles assembly, omnidirectional motion, geometric control, bus communication, real-world flight

CLC Number:

TP242

YU Yushu, WANG Kaidi, DU Jianrui, XU Bin, XIANG Changle. Design and Trajectory Linearization Geometric Control of Multiple Aerial Vehicles Assembly[J]. Journal of Mechanical Engineering, 2022, 58(21): 16-26.

References

[1] RUGGIERO F, LIPPIELLPO V, OLLERO A. Aerial manipulation:A literature review[J]. IEEE Robotics and Automation Letters, 2018, 3(3):1957-1964.
[2] MENG X D, HE Y Q, HAN J D. Survey on aerial manipulator:System, modeling, and control[J]. Robotica, 2020, 38(7):1288-1317.
[3] DING X L, GUO P, XU K, et al. A review of aerial manipulation of small-scale rotorcraft unmanned robotic systems[J]. Chinese Journal of Aeronautics, 2019, 32(1):200-214.
[4] 鲜斌, 刘洋, 张旭, 等. 基于视觉的小型四旋翼无人机自主飞行控制[J]. 机械工程学报, 2015, 51(9):58-63. XIAN Bin, LIU Yang, ZHANG Xu, et al. Autonomous control of a micro quadrotor unmanned aerial vehicle using optical flow using optical flow[J]. Journal of Mechanical Engineering, 2015, 51(9):58-63.
[5] 王营华, 宋光明, 刘盛松, 等. 一种视觉引导的作业型飞行机器人设计[J]. 机器人, 2019, 41(3):353-361. WANG Yinghua, CONG Guangming, LIU Shengsong, et al. Design of a vision-guided aerial manipulator[J]. Robot, 2019, 41(3):353-361.
[6] 刘云平, 周玉康, 张永宏, 等. 基于滑模PID的飞行机械臂稳定性控制[J]. 南京理工大学学报, 2018, 42(5):525-532. LIU Yunping, ZHOU Yukang, ZHANG Yonghong, et al. Research on stability control of flight manipulator based on sliding mode PID[J]. Journal of Nanjing University of Science and Technology, 2018, 42(5):525-532.
[7] SUTHAR B, JUNG S. Design and feasibility analysis of a foldable robot arm for drones using a twisted string actuator:FRAD-TSA[J]. IEEE Robotics and Automation Letters, 2021, 6(3):5769-5775.
[8] KIM S J, LEE D Y, JUNG G P, et al. An origami-inspired, self-locking robotic arm that can be folded flat[J]. IEEE Transactions on Industrial Electronics, Science Robotics, 2018, 3(16):1-10.
[9] ZHANG G, HE Y, DAI B, et al. Grasp a moving target from the air:System & control of an aerial manipulator[C]//2018 IEEE International Conference on Robotics and Automation (ICRA), Brisbane, QLD, 2018:1681-1687.
[10] ESTRADA M A, MINTCHEV S, CHRISTENSEN D L, et al. Forceful manipulation with micro air vehicles[J]. Science Robotics, 2018, 23(3):1-7.
[11] ORSAG M, KORPELA C, BOGDAN S, et al. Dexterous aerial robots mobile manipulation using unmanned aerial systems[J]. IEEE Transactions on Robotics, 2017, 33(6):1453-1466.
[12] LIPPIELLPO V, FONTANELLI G A, RUGGIERO F. Image-based visual-impedance control of a dual-arm aerial manipulator[J]. IEEE Robotics and Automation Letters, 2018, 3(3):1856-1863.
[13] WELDE J, PAULOS J, KUMAR V. Dynamically feasible task space planning for underactuated aerial manipulators[J]. IEEE Robotics and Automation Letter, 2021, 6(2):3232-3239.
[14] 史振庆, 梁晓龙, 张佳强, 等. 基于协同攻击区的航空集群最优空间构型研究[J]. 兵工学报, 2019, 40(4):788-798. SHI Zhenqing, LIANG Xiaolong, ZHANG Jiaqiang, et al. Study of optimal spatial configuration of aircraft swarm based on cooperative attack zone[J]. Acta Armamentarii, 2019, 40(4):788-798.
[15] SANALITROL D, SAVINO H J, TOGNONL M, et al. Full-pose manipulation control of a cable-suspended load with multiple UAVs under uncertainties[J]. IEEE Robotics and Automation Letters, 2020, 5(2), 2185-2191.
[16] PARK S, LEE Y H, HEO J, et al. Pose and posture estimation of aerial skeleton systems for outdoor flying[C]//2019 International Conference on Robotics and Automation (ICRA), Montreal, QC, Canada, 704-710, 2019.
[17] PARK S, LEE J, AHN J, et al. ODAR:Aerial manipulation platform enabling omni-directional wrench generation[J]. IEEE/ASME Transactions on Mechatronics, 2018, 23(4):1907-1918.
[18] YU Y, DING X. A global tracking controller for underactuated aerial vehicles:Design, analysis, and experimental tests on quadrotor[J]. IEEE/ASME Transactions on Mechatronics, 2016, 21(5):2499-2511.
[19] YU Y, LI P, GONG P. Finite-time geometric control for underactuated aerial manipulators with unknown disturbances[J]. International Journal of Robust and Nonlinear Control, 2020, 30(13):5040-5061.