基于三摆行为的自主轮式移动机器人路径规划控制器设计

Q3 Engineering

International Journal of Mechanical Engineering and Robotics Research Pub Date : 2023-01-01 DOI:10.18178/ijmerr.12.1.23-31

Salah M. Swadi, A. Kadhim, Ghusoon M. Ali

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引用次数: 1

摘要

本文研究了自主差动驱动轮式移动机器人的路径规划问题。基于三摆的混沌行为，设计了移动机器人的路径规划控制器。利用Simscape多体仿真软件研究了TP的动态响应。用0-1检验检验了TP的混沌行为。提出的模型用五种不同的情景进行了测试。在每个实验中，机器人被设计为寻找一个可能代表出口点、危险物质或任何特定目标的目标。这个目标被放置在一个2500毫米乘2500毫米的方形竞技场上的任意位置。为了增加机器人任务的复杂性，目标被障碍物(u形)包围，使机器人有一个唯一的入口到达目标。此外，还将所提出的控制器与基于传统混沌系统(洛伦兹系统)的控制器进行了比较。在这项工作中，使用KiKS模拟器进行了仿真结果。结果表明，在场景1、场景2、场景3、场景4和场景5中，控制器分别以13.11秒、17.09秒、36.47秒、12.52秒和12.49秒成功完成了所有任务。第二个控制器分别在25.22秒、32.28秒、46.49秒、49.4秒和33.38秒完成了同样的任务。这些结果证明了该控制器的优势，具有很大的潜力，可以在未来进行进一步的研究。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Design of Path Planning Controller of Autonomous Wheeled Mobile Robot Based on Triple Pendulum Behaviour

—This paper deals with the path planning of autonomous differential driving wheeled mobile robots. The path planning controller of the mobile robot is designed based on the chaotic behaviour of the Triple Pendulum (TP). The dynamic response of the TP is investigated using Simscape Multibody software. The chaotic behaviour of the TP is examined with a 0-1 test. The proposed model was tested with five different scenarios. In each experiment, the robot is designed to search for a target that may represent an exit point, dangerous material, or any specific target. This target is placed in an arbitrary position on a square arena 2500 mm by 2500 mm. In order to increase the complexity of the robot mission, the target is surrounded by an obstacle (u-shape) so that there is a unique entrance for the robot to reach the target. In addition, the proposed controller is compared with the controller based on a traditional chaotic system (Lorenz system), which is designed for this purpose. In this work, simulation results are conducted using the KiKS simulator. The results show the success of the proposed controller in completing all missions with 13.11 sec, 17.09 sec, 36.47 sec, 12.52 sec, and 12.49 sec for scenarios 1, 2, 3, 4, and 5, respectively. The second controller completed the same mission in 25.22 sec, 32.28 sec, 46.49 sec, 49.4 sec, and 33.38 sec. These results proved the proposed controller's advantage, which has great potential and can be investigated in the future.

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来源期刊

International Journal of Mechanical Engineering and Robotics Research Engineering-Mechanical Engineering

CiteScore

2.80

自引率

0.00%

发文量

期刊介绍： International Journal of Mechanical Engineering and Robotics Research. IJMERR is a scholarly peer-reviewed international scientific journal published bimonthly, focusing on theories, systems, methods, algorithms and applications in mechanical engineering and robotics. It provides a high profile, leading edge forum for academic researchers, industrial professionals, engineers, consultants, managers, educators and policy makers working in the field to contribute and disseminate innovative new work on Mechanical Engineering and Robotics Research.