In this study, an original strategy to control a mobile robot in a dynamic environment is presented. The strategy consists of two main elements. The first is the method for the online trajectory generation based on harmonic potential fields, capable of generating velocity and orientation references, which extends classical results on harmonic potential fields for the case of static environments to the case when the presence of a moving obstacle with unknown motion is considered. The second is the design of sliding-mode controllers capable of making the controlled variables of the robot track in a finite minimum time both the velocity and the orientation references. \ua9 2011 The Institution of Engineering and Technology
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In this study, an original strategy to control a mobile robot in a dynamic environment is presented....
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Abstract — In this paper, a harmonic potential field method for dynamic environments is proposed to ...
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The paper describes trajectory generation and tracking control algorithms, respectively based on non...
This paper presents a new formulation of the artificial potential approach to the obstacle avoidance...
This paper presents a method for motion planning in dynamic environments, subject to robot dynamics ...
In this study, an original strategy to control a mobile robot in a dynamic environment is presented....
In this paper, a harmonic potential field method for dynamic environments is proposed to generate an...
Abstract — In this paper, a harmonic potential field method for dynamic environments is proposed to ...
In this paper, a dynamic obstacle avoidance strategy for mobile robots is proposed. The strategy con...
This paper aims to develop a control method by using artificial potential field with the addition of...
This paper introduces a sliding mode strategy for controlling the trajectory of a mobile robot. An ...
This paper introduces a new integrated path control strategy (combined path planning and motion cont...
This paper provides a new approach to the dynamic motion planning problems of mobile robots in uncer...
In our recent work [5], by explicitly considering kinematic model of the robot, the family of feasib...
This paper presents an extension of motion planning in consideration of travel time and velocity dur...
The problem of controlling an autonomous wheeled vehicle which must move in its operative space and ...
In this paper, the problem of determining an optimal collision-free path is studied for a mobile rob...
The paper describes trajectory generation and tracking control algorithms, respectively based on non...
This paper presents a new formulation of the artificial potential approach to the obstacle avoidance...
This paper presents a method for motion planning in dynamic environments, subject to robot dynamics ...