Formation Control of Nonholonomic Mobile Robots Without Position and Velocity Measurements
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AbstractMost existing formation control approaches are based on the assumption that the global/relative position and/or velocity measurements of mobile robots are directly available. To extend the application domain and to improve the formation control performance, it is extremely necessary to avoid the use of position and velocity measurements in the design of formation controllers. In this paper, we propose new leader-following formation tracking control schemes for nonholonomic mobile robots with onboard perspective cameras, without using both position and velocity measurements. To address the unavailability issue of position measurements, the leader-follower kinematics model in the image space is developed, which can facilitate the complete elimination of measurement/estimation of the position information. Furthermore, feedback information from the perspective camera of the follower robot is used to design adaptive observers to estimate the leader linear velocity for feedforward compensation, which can handle the absence of velocity measurements such that the proposed schemes can be applied to control formations of mobile robots without mutual communication abilities. By using the Lyapunov stability theory, a rigorous stability analysis based on the nonlinear formation dynamics is provided to show that the global stability of the combined observer-controller closed-loop system can he guaranteed. Both simulation and experimental results are also given to demonstrate the performance of the proposed formation tracking control schemes.
All Author(s) ListLiang XW, Wang HS, Liu YH, Chen WD, Liu T
Journal nameIEEE Transactions on Robotics
Year2018
Month4
Volume Number34
Issue Number2
PublisherIEEE
Pages434 - 446
ISSN1552-3098
eISSN1941-0468
LanguagesEnglish-United Kingdom
KeywordsFormation tracking control, mobile robots, observer, perspective camera, stability analysis
Web of Science Subject CategoriesRobotics;Robotics

Last updated on 2020-27-09 at 02:57