Abstract
In this paper, an optimized kinematic modeling method to accurately describe the actual structure of a mobile manipulator robot with a manipulator similar to the universal robot (UR5) is developed, and an improved self-collision detection technology realized for improving the description accuracy of each component and reducing the time required for approximating the whole robot is introduced. As the primary foundation for trajectory tracking and automatic navigation, the kinematic modeling technology of the mobile manipulator has been the subject of much interest and research for many years. However, the kinematic model established by various methods is different from the actual physical model due to the fact that researchers have mainly focused on the relationship between driving joints and the end positions while ignoring the physical structure. To improve the accuracy of the kinematic model, we present a kinematic modeling method with the addition of key points and coordinate systems to some components that failed to model the physical structure based on the classical method. Moreover, self-collision detection is also a primary problem for successfully completing the specified task of the mobile manipulator. In traditional self-collision detection technology, the description of each approximation is determined by the spatial transformation of each corresponding component in the mobile manipulator robot. Unlike the traditional technology, each approximation in the paper is directly established by the physical structure used in the kinematic modeling method, which significantly reduces the complicated analysis and shortens the required time. The numerical simulations prove that the kinematic model with the addition of key point technology is similar to the actual structure of mobile manipulator robots, and the self-collision detection technology proposed in the article effectively improves the performance of self-collision detection. Additionally, the experimental results prove that the kinematic modeling method and self-collision detection technology outlined in this paper can optimize the inverse kinematics solution.
Highlights
We developed a kinematic modeling method to accurately describe the actual structure of the mobile manipulator robot with a UR-like arm
We improved the performance of the self-collision detection process by reasonably approximating the structure of the mobile manipulator robot and reducing the time required for position description
To validate the performance of kinematic modeling and self-collision detection, which was optimized by adding some key points to some components that failed to model the physical structure, we conducted some typical simulations in the mobile manipulator robot with a UR5-like arm, including the kinematic model, approximation results, the time required to approximate the robot, and the effectiveness of self-collision detection
Summary
Due to the combination of the high mobility of the mobile platform and the dexterous maneuverability of the manipulator, it can be widely used in current life and work, such as in planetary exploration, nuclear reactor maintenance, landmine detection, agriculture missions, and fire rescue operations [3,4,5]. Improving the accuracy of the kinematic model and avoiding self-collision remain challenging problems in robot operations [9,10]. The resolution of these challenges is extremely promising for the development of mobile manipulator systems
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