Add to ORKGThe problem of robot manipulator controller design in the presence of joint flexibility is addressed. The specific goal is to design a controller that yields good tracking performance in spite of parametric uncertainty. Feedback linearization, robust observers, singular perturbation technique, and adaptive control are different approaches that are theoretically analyzed. Experimental results on a single-link, flexible joint arm are also presented. Although each controller has its advantages and drawbacks, all of the design methods yield improved performance when compared to controller designs based upon rigid joint models.U of I OnlyETDs are only available to UIUC Users without author permissio
Abstract: In this paper a controller design method for flexible joint robots (FJR), considering actu...
Using some recent nonlinear controller design techniques, we derive, and compare, several globally s...
In this paper the control of flexible joint manipulators is studied in detail. The model of N-axis f...
The problem of robot manipulator controller design in the presence of joint flexibility is addressed...
This paper presents the first input-output robust control design for the trajectory following proble...
This paper presents the first input-output robust control design for the trajectory following proble...
This paper presents the first input-output robust control design for the trajectory following proble...
This paper presents the first input-output robust control design for the trajectory following proble...
grantor: University of TorontoThis thesis focuses on the development of new motion and fo...
grantor: University of TorontoThis thesis focuses on the development of new motion and fo...
In this paper a new approach employing smooth robust compensators is proposed for the control of unc...
Abstract — In this paper a new and completely linear algo-rithm is proposed for composite robust con...
In this paper, we present an approach for designing robust tracking controllers for rigid-link flexi...
In this paper, we present an approach for designing robust tracking controllers for rigid-link flexi...
International audiencePresents an adaptive control scheme for flexible joint robot manipulators. Asy...
Abstract: In this paper a controller design method for flexible joint robots (FJR), considering actu...
Using some recent nonlinear controller design techniques, we derive, and compare, several globally s...
In this paper the control of flexible joint manipulators is studied in detail. The model of N-axis f...
The problem of robot manipulator controller design in the presence of joint flexibility is addressed...
This paper presents the first input-output robust control design for the trajectory following proble...
This paper presents the first input-output robust control design for the trajectory following proble...
This paper presents the first input-output robust control design for the trajectory following proble...
This paper presents the first input-output robust control design for the trajectory following proble...
grantor: University of TorontoThis thesis focuses on the development of new motion and fo...
grantor: University of TorontoThis thesis focuses on the development of new motion and fo...
In this paper a new approach employing smooth robust compensators is proposed for the control of unc...
Abstract — In this paper a new and completely linear algo-rithm is proposed for composite robust con...
In this paper, we present an approach for designing robust tracking controllers for rigid-link flexi...
In this paper, we present an approach for designing robust tracking controllers for rigid-link flexi...
International audiencePresents an adaptive control scheme for flexible joint robot manipulators. Asy...
Abstract: In this paper a controller design method for flexible joint robots (FJR), considering actu...
Using some recent nonlinear controller design techniques, we derive, and compare, several globally s...
In this paper the control of flexible joint manipulators is studied in detail. The model of N-axis f...