Abstract
This paper is concerned with providing a new quantitative analysis method of computed torque control of robot systems by using three types of induced norm. This paper first considers design of a computed torque controller to achieve a trajectory tracking performance of a robot manipulator. Taking into account of the effects of unknown elements on the tracking performance, this paper next divides the unknown elements into model uncertainty and disturbance, and introduces various closed-loop representations of robot systems consisting of robot manipulators together with computed torque controllers and unknown elements. This paper further derives a readily applicable robust stability condition for the model uncertainty by using two types of induced norm from L 2 to L 2 and from L ∞ to L ∞ . Regarding a performance analysis for the disturbance, this paper also proposes to take the induced norm from L 2 to L ∞ , by which the relation between the maximum tracking errors caused by the disturbance and the corresponding parameters of the computed torque controllers are dealt with. Finally, this paper gives some experiments to validate the effectiveness of the performance analysis methods based on the L ∞ /L 2 -induced norm.
Highlights
The tracking problem for a given trajectory has been regarded as one of the most important issues in robot systems
The 3-degrees of freedom (3-DoF) robot manipulator as shown in Fig. 6 is employed where this manipulator consists of three brush-less direct current (BLDC) motors with three linkages whose lengths are 0.3, 0.3 and 0.1 m, respectively
We first dealt with design of computed torque controllers for trajectory tracking problems of robot manipulators
Summary
The tracking problem for a given trajectory has been regarded as one of the most important issues in robot systems. The associated Lyapunov functions should be defined according to the assumptions of some norm constraints on the unknown elements Even though this approach is quite useful to guarantee the robust stability of the closed-loop systems, it is difficult to construct a quantitative performance measure relevant to the computed torque control for unknown elements by using the arguments in [25]–[27]. With this in mind, this paper introduces another type of robust stability analysis by using the concept of small-gain theorem and proposes a new performance measure with respect to unknown elements in a quantitative fashion.
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