Adaptive Robust Constraint Following Control for Omnidirectional Mobile Robot: An Indirect Approach

The tracking performance of mobile robot is often affected by uncertainties from the deviation of initial conditions, external disturbances and varying loads, etc. An Udwadia-Kalaba based adaptive robust control is proposed for the trajectory tracking of an omnidirectional mobile robot in the presen...

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Bibliographic Details
Published inIEEE access Vol. 9; p. 1
Main Authors Dong, Fangfang, Jin, Dong, Zhao, Xiaomin, Han, Jiang
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 01.01.2021
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Adaptive control
Adaptive robust control
Constraint following
Force
Initial conditions
Mathematical analysis
Mobile robots
Proportional integral derivative
Robot control
Robot kinematics
Robots
Robust control
Tracking control
Trajectory
Trajectory control
Udwadia-Kalaba theory
Uncertainty
Uniformly bounded
Wheels
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Summary:The tracking performance of mobile robot is often affected by uncertainties from the deviation of initial conditions, external disturbances and varying loads, etc. An Udwadia-Kalaba based adaptive robust control is proposed for the trajectory tracking of an omnidirectional mobile robot in the presence of uncertainties. The proposed control includes nominal control part based on Udwadia-Kalaba theory and adaptive robust control part. The desired trajectory is considered as a virtual servo constraint applied to the robot system and converted into the second order standard form. So that the analytical form of constraint force could be obtained via Udwadia-Kalaba Fundamental Equation (UKFE). The system will precisely obey the given constraint (i.e., the desired trajectory) under the obtained constraint force in ideal cases. No auxiliary variables are required and it is effective whether the constraints are holonomic or nonholonomic. The designed adaptive law is in leakage type and the adaptive parameters are adjusted according to the performance of the system in order to compensate for the effect caused by uncertainty in the system. No extra information of uncertainty is needed except for the existence of uncertainty bound. Comparing with PID control, it can be found that the proposed control has better performance and can realize higher precision trajectory tracking control.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2021.3049913