Lyapunov and Sliding Mode Based Leader-follower Formation Control for Multiple Mobile Robots with an Augmented Distance-angle Strategy

In this paper, a new two-layer control strategy which combines Kinematic Controller based on Lyapunov Theory (KCLT) with Dynamic Controller based on Sliding Mode (DCSM) is proposed to solve the problem of leader-follower formation control for multiple wheeled mobile robots (M-WMR). An augmented dist...

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Bibliographic Details
Published inInternational journal of control, automation, and systems Vol. 17; no. 5; pp. 1314 - 1321
Main Authors Zhao, Yudong, Zhang, Yueyuan, Lee, Jangmyung
Format Journal Article
LanguageEnglish
Published Bucheon / Seoul Institute of Control, Robotics and Systems and The Korean Institute of Electrical Engineers 01.05.2019
Springer Nature B.V
제어·로봇·시스템학회
Subjects
Control
Control algorithms
Engineering
Iterative methods
Kinematics
Machine learning
Mechatronics
Proportional integral derivative
Regular Papers
Robotics
제어계측공학
Lyapunov theory
multiple wheeled mobile robot
sliding mode control
Leader-follower formation control
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Summary:In this paper, a new two-layer control strategy which combines Kinematic Controller based on Lyapunov Theory (KCLT) with Dynamic Controller based on Sliding Mode (DCSM) is proposed to solve the problem of leader-follower formation control for multiple wheeled mobile robots (M-WMR). An augmented distance-angle leader-follower formation kinematic is constructed to describe the formation states, and a 2D LiDAR sensor is utilized to measure the states instead of using camera and image processing on each follower. Instead of transferring the measured formation states into reference position command for each follower, KCLT is designed to generate follower’s velocity command. By taking the velocity command of followers as reference signals, DCSM is implemented to realize formation control. Lyapunov stability theory verifies that with the designed controller all the error signals can converge to 0 theoretically, which implies formation control of M-WMR under the proposed method can be realized. Real experiments with one leader and two followers are carried out to demonstrate the effectiveness of the proposed control schema. In order to verify the robustness of the proposed method, the reference rotational velocity of the leader robot is designed to change between +0:2 rad/s and -0:2 rad/s at some specified position. And the experimental results are compared with that of traditional proportional-integral-derivative (PID) method.
Bibliography:http://link.springer.com/article/10.1007/s12555-018-0194-7
ISSN:1598-6446
2005-4092
DOI:10.1007/s12555-018-0194-7