Adaptive control of robot manipulators using fuzzy logic systems under actuator constraints

Adaptive control of robot manipulators using fuzzy logic systems under actuator constraints

In this paper, a stable fuzzy adaptive controller for trajectory tracking is developed for robot manipulators without velocity measurements, taking into account the actuator constraints. The controller is based on structural knowledge of the dynamics of the robot and measurements of link positions o...

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Bibliographic Details
Published in:Fuzzy sets and systems Vol. 152; no. 3; pp. 651 - 664
Main Authors: Purwar, S., Kar, I.N., Jha, A.N.
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 16-06-2005
Elsevier
Subjects:
Actuator constraints
Adaptive tracking control
Applied sciences
Computer science; control theory; systems
Control theory. Systems
Exact sciences and technology
Fuzzy logic system
General logic
Logic and foundations
Mathematical logic, foundations, set theory
Mathematics
Position measurements
Robot dynamics
Robotics
Sciences and techniques of general use
System theory
Position measurements
Actuator constraints
Robot dynamics
Adaptive tracking control
Fuzzy logic system
Fuzzy system
Filtering
Manipulator
Fuzzy logic
Fuzzy control
Asymptotic stability
Simulation
Position measurement
Robot
Actuator constraint
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Summary:In this paper, a stable fuzzy adaptive controller for trajectory tracking is developed for robot manipulators without velocity measurements, taking into account the actuator constraints. The controller is based on structural knowledge of the dynamics of the robot and measurements of link positions only. The gravity torque including system uncertainty like payload variation, etc., is estimated by a fuzzy logic system (FLS). The adaptive controller represents an amalgamation of a filtering technique to eliminate velocity measurements and the theory of function approximation using FLS to estimate the gravity torque. The proposed controller ensures the local asymptotic stability and the convergence of the position error to zero. The proposed controller is robust not only to structured uncertainty such as payload parameter variation, but also to unstructured one such as disturbances. The validity of the control scheme is shown by simulations on a two-link robot manipulator.
ISSN:0165-0114
1872-6801
DOI:10.1016/j.fss.2004.11.012