JACIII Vol.25 No.1 pp. 64-72
doi: 10.20965/jaciii.2021.p0064


Path Planning Based on Improved Hybrid A* Algorithm

Bijun Tang, Kaoru Hirota, Xiangdong Wu, Yaping Dai, and Zhiyang Jia

School of Automation, Beijing Institute of Technology
No.5 Zhongguancun South Street, Haidian District, Beijing 100081, China

Corresponding author

October 25, 2020
October 29, 2020
January 20, 2021
path planning, hybrid A* algorithm, artificial potential field, ROS platform

Hybrid A* algorithm has been widely used in mobile robots to obtain paths that are collision-free and drivable. However, the outputs of hybrid A* algorithm always contain unnecessary steering actions and are close to the obstacles. In this paper, the artificial potential field (APF) concept is applied to optimize the paths generated by the hybrid A* algorithm. The generated path not only satisfies the non-holonomic constraints of the vehicle, but also is smooth and keeps a comfortable distance to the obstacle at the same time. Through the robot operating system (ROS) platform, the path planning experiments are carried out based on the hybrid A* algorithm and the improved hybrid A* algorithm, respectively. In the experiments, the results show that the improved hybrid A* algorithm greatly reduces the number of steering actions and the maximum curvature of the paths in many different common scenarios. The paths generated by the improved algorithm nearly do not have unnecessary steering or sharp turning before the obstacles, which are safer and smoother than the paths generated by the hybrid A* algorithm for the autonomous ground vehicle.

Cite this article as:
B. Tang, K. Hirota, X. Wu, Y. Dai, and Z. Jia, “Path Planning Based on Improved Hybrid A* Algorithm,” J. Adv. Comput. Intell. Intell. Inform., Vol.25 No.1, pp. 64-72, 2021.
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