[1]秦新燕,李惠东,冯天明,等.飞走巡线机器人多模式切换混杂控制方法[J].智能系统学报,2023,18(6):1243-1258.[doi:10.11992/tis.202211011]
QIN Xinyan,LI Huidong,FENG Tianming,et al.Hybrid control method of multimode switching for flying-walking power-line inspection robots[J].CAAI Transactions on Intelligent Systems,2023,18(6):1243-1258.[doi:10.11992/tis.202211011]
点击复制
QIN Xinyan,LI Huidong,FENG Tianming,et al.Hybrid control method of multimode switching for flying-walking power-line inspection robots[J].CAAI Transactions on Intelligent Systems,2023,18(6):1243-1258.[doi:10.11992/tis.202211011]
飞走巡线机器人多模式切换混杂控制方法
《智能系统学报》[ISSN 1673-4785/CN 23-1538/TP] 卷:
18
期数:
2023年第6期
页码:
1243-1258
栏目:
学术论文—机器人
出版日期:
2023-11-05
- Title:
- Hybrid control method of multimode switching for flying-walking power-line inspection robots
- Keywords:
- power line; flying-walking power-line inspection robot; multimode switching; hybrid control; automata; monitoring; variable universe fuzzy control; model predictive
- 分类号:
- TP242.6
- 摘要:
- 电力线所处环境恶劣,工况复杂,具柔索特性,对巡线机器人的稳定性和可靠性提出较大挑战,因此以飞走巡线机器人(flying-walking power line inspection robot,FPLIR)为研究对象,提出了一种多模式切换混杂控制方法。在FPLIR巡检工作原理基础上,建立4种控制模式的混杂自动机模型和相互切换的监测器模型;利用Lyapunov函数法和力角稳定性判据(force-angle stability margin,FASM)法分析FPLIR多模式切换和力学特性的稳定性;基于各模式的控制目标,提出了对应的控制策略,尤其结合FPLIR的结构和工况特点,设计变论域模糊控制器,提高FPLIR线上行走的稳定性,设计模型预测控制器,提高FPLIR落线的安全性。最后通过仿真和实验验证了多模式切换混杂控制方法的有效性和可行性,提升了FPLIR在复杂电力线环境下的适应性,为未来机器人智能巡检提供理论参考。
- Abstract:
- The stability and reliability of power-line inspection robots are greatly affected by harsh environments, complex working conditions, and flexible characteristics of the power line. Therefore, a hybrid automata model of multimode switching is proposed for flying-walking power-line inspection robots (FPLIRs). Herein, a hybrid automata model and multimode-switching monitoring model for four control modes were established based on the operating principles of FPLIR inspection, and the Lyapunov function method and force-angle stability margin were used to analyze the stability of multimode switching and mechanical properties. Based on the control objective of each mode, corresponding control strategies were proposed. In particular, combined with the structure and working condition characteristics of FPLIRs, the variable universe fuzzy controller and model prediction controller were designed to improve the stability of FPLIRs walking along a line and the safety of FPLIR flight-line falling, respectively. Finally, the effectiveness and feasibility of the multimode switching hybrid control method were verified through simulations and experiments. The adaptability of FPLIRs in complex power-line environments was improved, providing a theoretical reference for future intelligent inspection using robots.
- 参考文献/References:
-
[1] QIN Xinyan, JIA Bo, LEI Jin, et al. A novel flying–walking power line inspection robot and stability analysis hanging on the line under wind loads[J]. Mechanical sciences, 2022, 13(1): 257–273.
[2] KATRASNIK J, PERNUS F, LIKAR B. A climbing-flying robot for power line inspection[M]//Climbing and Walking Robots. [S. l.]: InTech, 2010.
[3] 张运楚, 梁自泽, 谭民. 架空电力线路巡线机器人的研究综述[J]. 机器人, 2004, 26(5): 467–473
ZHANG Yunchu, LIANG Zize, TAN Min. Mobile robot for overhead powerline inspection-a review[J]. Robot, 2004, 26(5): 467–473
[4] 王婕, 马晓, 宗群, 等. 四旋翼无人飞行器的轨迹跟踪与滑模事件驱动控制[J]. 控制理论与应用, 2019, 36(7): 1083–1089
WANG Jie, MA Xiao, ZONG Qun, et al. Trajectory tracking and sliding mode event-triggered control for a quadrotor unmanned aerial vehicle[J]. Control theory & applications, 2019, 36(7): 1083–1089
[5] 吴华, 宋自立, 李国栋, 等. 电力巡检飞行机器人抗风控制器设计[J]. 华中科技大学学报(自然科学版), 2013, 41(S1): 443–446
WU Hua, SONG Zili, LI Guodong, et al. Wind resistant controller for flying robot of power line inspection[J]. Journal of Huazhong University of Science and Technology (natural science edition), 2013, 41(S1): 443–446
[6] 赵振华, 肖亮, 姜斌, 等. 基于扩张状态观测器的四旋翼无人机快速非奇异终端滑模轨迹跟踪控制[J]. 控制与决策, 2022, 37(9): 2201–2210
ZHAO Zhenhua, XIAO Liang, JIANG Bin, et al. Fast nonsingular terminal sliding mode trajectory tracking control of a quadrotor UAV based on extended state observers[J]. Control and decision, 2022, 37(9): 2201–2210
[7] CHEN Yanmin, HE Yongling, ZHOU Minfeng. Modeling and control of a quadrotor helicopter system under impact of wind field[J]. Research journal of applied sciences, engineering and technology, 2013, 6(17): 3214–3221.
[8] 沈智鹏, 曹晓明. 输入受限四旋翼飞行器的模糊自适应动态面轨迹跟踪控制[J]. 控制与决策, 2019, 34(7): 1401–1408
SHEN Zhipeng, CAO Xiaoming. Fuzzy adaptive dynamic surface trajectory tracking control for quadrotor UAV with input constraints[J]. Control and decision, 2019, 34(7): 1401–1408
[9] LI Cai, LIANG Zize, HOU Zengguang, et al. Fuzzy control of the inspection robot for obstacle-negotiation[C]//2008 IEEE International Conference on Networking, Sensing and Control. Sanya: IEEE, 2008: 117-122.
[10] 王鲁单, 王洪光, 房立金, 等. 一种输电线路巡检机器人控制系统的设计与实现[J]. 机器人, 2007, 29(1): 7–11,17
WANG Ludan, WANG Hongguang, FANG Lijin, et al. Design and implementation of the control system of a power transmission line inspection robot[J]. Robot, 2007, 29(1): 7–11,17
[11] 严宇. 高压输电线路巡线机器人越障与打滑控制[D]. 武汉: 武汉大学, 2014.
YAN Yu. Obstacle crossing and anti-slide control of high voltage transmission line inspection robot[D]. Wuhan: Wuhan University, 2014.
[12] 裴晓飞, 刘昭度, 马国成, 等. 汽车自适应巡航系统的多模式切换控制[J]. 机械工程学报, 2012, 48(10): 96–102
PEI Xiaofei, LIU Zhaodu, MA Guocheng, et al. Multi-mode switching controller for vehicle adaptive cruise control system[J]. Journal of mechanical engineering, 2012, 48(10): 96–102
[13] 韩晓男. 陆空两栖载物平台模式切换与判决研究[D]. 长春: 吉林大学, 2019.
HAN Xiaonan. Research on mode switching and judgment of land and air amphibious load platform[D]. Changchun: Jilin University, 2019.
[14] 宋自立. 四旋翼飞行机器人增稳控制方法研究[D]. 北京: 华北电力大学, 2014.
SONG Zili. Research on stability augmentation control method for quadrotor flying robot[D]. Beijing: North China Electric Power University, 2014.
[15] 赵治国, 何宁, 朱阳, 等. 四轮驱动混合动力轿车驱动模式切换控制[J]. 机械工程学报, 2011, 47(4): 100–109
ZHAO Zhiguo, HE Ning, ZHU Yang, et al. Mode transition control for four wheel drive hybrid electric car[J]. Journal of mechanical engineering, 2011, 47(4): 100–109
[16] 汤新民, 韩云祥, 韩松臣. 面向4D航迹运行的飞行冲突混杂系统理论监控方法[J]. 电子科技大学学报, 2012, 41(5): 717–722
TANG Xinmin, HAN Yunxiang, HAN Songchen. 4D trajectory based operation flight conflict supervisory control based on hybrid system theory[J]. Journal of University of Electronic Science and Technology of China, 2012, 41(5): 717–722
[17] 汪少华. 半主动空气悬架混杂系统的多模式切换控制研究[D]. 镇江: 江苏大学, 2013.
WANG Shaohua. Research on multi-mode switching control of semi-active air suspension hybrid system[D]. Zhenjiang: Jiangsu University, 2013.
[18] LIN Yuandan, SONTAG E D, WANG Yuan. A smooth converse Lyapunov theorem for robust stability[J]. SIAM journal on control and optimization, 1996, 34(1): 124–160.
[19] 何仁, 胡东海. 轿车电磁与摩擦制动集成系统混杂控制方法[J]. 机械工程学报, 2016, 52(12): 118–128
HE Ren, HU Donghai. Hybrid control method of the integrated system of electromagnetic and friction braking of car[J]. Journal of mechanical engineering, 2016, 52(12): 118–128
[20] 张昊昱. 大型高适应性六足机器人结构及稳定性分析[D]. 长春: 吉林大学, 2021.
ZHANG Haoyu. Analysis of the structure and stability of a large and highly adaptable hexapod robot[D]. Changchun: Jilin University, 2021.
[21] ZHANG Jie, LEI Jin, QIN Xinyan, et al. Modeling and analysis of a flying-walking power line inspection robot[C]//Proceedings of the 2021 2nd International Conference on Control, Robotics and Intelligent System. Qingdao: ACM, 2021: 25-30.
[22] 刘豹, 唐万生. 现代控制理论[M]. 3版. 北京: 机械工业出版社, 2006.
[23] PANEQUE J L, DIOS J R M D, OLLERO A, et al. Perception-aware perching on powerlines with multirotors[J]. IEEE robotics and automation letters, 2022, 7(2): 3077–3084.
[24] LI Zhaojun, QIN Xinyan, LEI Jin, et al. Variable universe fuzzy control of walking stability for flying-walking power line inspection robot based on multi-work conditions[J]. IET cyber-systems and robotics, 2022, 4(3): 212–227.
[25] ZHOU Xin, WANG Zhepei, YE Hongkai, et al. EGO-planner: an ESDF-free gradient-based local planner for quadrotors[J]. IEEE robotics and automation letters, 2021, 6(2): 478–485.
[26] RAMON-SORIA P, GOMEZ-TAMM A E, GARCIA-RUBIALES F J, et al. Autonomous landing on pipes using soft gripper for inspection and maintenance in outdoor environments[C]//2019 IEEE/RSJ International Conference on Intelligent Robots and Systems. Macau: IEEE, 2020: 5832-5839.
备注/Memo
收稿日期:2022-11-10。
基金项目:国家自然科学基金项目(62163032,62063030);兵团财政科技计划(2021DB003,2022CB011,2022CB002-07);兵团九师科技专项(2021JS008).
作者简介:秦新燕,副教授,博士,主要研究方向为机器人和复杂机电系统与控制,农业机械装备创新与性能设计。主持国家自然科学基金项目1项、兵团财政科技创新骨干人才计划项目1项,参与国家自然科学基金项目1项、兵团财政科技计划项目1项、兵团九师科技专项1项,授权发明专利3项。发表学术论文10余篇,主编教材1部;李惠东,硕士研究生,主要研究方向为电力线巡检机器人控制系统;雷金,副教授,博士后,主要研究方向为机器人和复杂机电系统与控制。主持国家自然科学基金项目1项、兵团财政科技创新人才计划项目1项、兵团财政科技计划项目1项、兵团九师科技专项1项,授权发明专利4项、实用新型2项、计算机软件著作 权1项。发表期刊论文20余篇
通讯作者:雷金.E-mail:jinlei@shzu.edu.cn
更新日期/Last Update:
1900-01-01