Cooperative Moving-Target Enclosing of Networked Vehicles With Constant Linear Velocities

被引：50

作者：

Yu, Xiao ^{[1
,2
]}

Ding, Ning ^{[3
]}

Zhang, Aidong ^{[3
]}

Qian, Huihuan ^{[4
]}

机构：

[1] Shanghai Jiao Tong Univ, Dept Automat, Shanghai 200240, Peoples R China

[2] Minist Educ China, Key Lab Syst Control & Informat Proc, Shanghai 200240, Peoples R China

[3] Chinese Univ Hong Kong, Inst Robot & Intelligent Mfg, Shenzhen 518172, Peoples R China

[4] Chinese Univ Hong Kong, Sch Sci & Engn, Shenzhen 518172, Peoples R China

来源：

IEEE TRANSACTIONS ON CYBERNETICS | 2020年 / 50卷 / 02期

基金：

中国国家自然科学基金; 国家重点研发计划;

关键词：

Orbits; Angular velocity; Target tracking; Vehicle dynamics; Robot sensing systems; Cooperative control; nonholonomic vehicles; target enclosing; velocity constraint; COLLECTIVE CIRCULAR MOTION; COORDINATED STANDOFF TRACKING; NONHOLONOMIC MOBILE ROBOTS; CYCLIC PURSUIT; TRAJECTORY TRACKING; CIRCUMNAVIGATION; STABILIZATION; CONSENSUS;

D O I：

10.1109/TCYB.2018.2873904

中图分类号：

TP [自动化技术、计算机技术];

学科分类号：

0812 ;

摘要：

This paper investigates the cooperative moving-target enclosing control problem of networked unicycle-type nonholonomic vehicles with constant linear velocities. The information of the target is only known to some of the vehicles, and the topology of the vehicle network is described by a directed graph. A dynamic control law is proposed to steer the vehicles, such that they can get close to orbiting around the target while the target is moving with a time-vary velocity. Besides, the constraint of bounded angular velocity for the vehicles can always be satisfied. The proposed control law is distributed in the sense that each vehicle only uses its own information and the information of its neighbors in the network. Finally, simulation results of an example validate the effectiveness of the proposed control law.

引用

页码：798 / 809

页数：12

共 21 条

[1] Cooperative Moving-Target Enclosing Control for Multiple Nonholonomic Vehicles Using Feedback Linearization Approach
Peng, Xiuhui
Guo, Kexin
Li, Xue
Geng, Zhiyong
[J]. IEEE TRANSACTIONS ON SYSTEMS MAN CYBERNETICS-SYSTEMS, 2021, 51 (08): : 4929 - 4935
[2] Cooperative Control for Moving-Target Circular Formation of Nonholonomic Vehicles
Yu, Xiao
Liu, Lu
[J]. IEEE TRANSACTIONS ON AUTOMATIC CONTROL, 2017, 62 (07) : 3448 - 3454
[3] Cooperative Enclosing Control for Networked Unmanned Aerial Vehicles to Faster Target
Chen, Lin
Duan, Haibin
[J]. JOURNAL OF GUIDANCE CONTROL AND DYNAMICS, 2024, 47 (02) : 366 - 374
[4] Moving-Target Enclosing Control for Mobile Agents With Collision Avoidance
Dou, Liya
Yu, Xiao
Liu, Lu
Wang, Xiaofan
Feng, Gang
[J]. IEEE TRANSACTIONS ON CONTROL OF NETWORK SYSTEMS, 2021, 8 (04): : 1669 - 1679
[5] Cooperative Control Synthesis for Moving-Target-Enclosing with Changing Topologies
Guo, Jing
Yan, Gangfeng
Lin, Zhiyun
[J]. 2010 IEEE INTERNATIONAL CONFERENCE ON ROBOTICS AND AUTOMATION (ICRA), 2010, : 1468 - 1473
[6] Cooperative Circular Formation Control Design for Enclosing a Moving Target With Collision Avoidance
Xiong, Yutao
Lu, Ke
Dai, Shi-Lu
[J]. 2022 41ST CHINESE CONTROL CONFERENCE (CCC), 2022, : 4551 - 4556
[7] Vision-Based Moving-Target Geolocation Using Dual Unmanned Aerial Vehicles
Pan, Tingwei
Deng, Baosong
Dong, Hongbin
Gui, Jianjun
Zhao, Bingxu
[J]. REMOTE SENSING, 2023, 15 (02)
[8] Coordinated Moving-Target Encircling Control for Networked Quadrotors With Event-Triggered Extended State Observers
Shao, Xingling
Yue, Xiaohui
Zhang, Wendong
[J]. IEEE SYSTEMS JOURNAL, 2023, 17 (04): : 6576 - 6587
[9] Reinforcement learning-based moving-target enclosing control for an unmanned surface vehicle in multi-obstacle environments
Wang, Qiang
Liu, Chun
Meng, Yizhen
Ren, Xiaoqiang
Wang, Xiaofan
[J]. OCEAN ENGINEERING, 2024, 304
[10] Cooperative Target Tracking by Altering UAVs' Linear and Angular Velocities
Ma, Lili
[J]. 2019 INTERNATIONAL CONFERENCE ON UNMANNED AIRCRAFT SYSTEMS (ICUAS' 19), 2019, : 69 - 78

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