基于偏转角抑制的改进人工势场法路径规划

doi:10.16180/j.cnki.issn1007-7820.2024.10.003

摘要/Abstract

摘要：

针对传统人工势场法在实际应用中存在的局部最极小值、目标不可达以及路径震荡等问题,文种提出了一种基于偏转角抑制的改进人工势场法。该方法以传统人工势场法为基础,采用改进斥力势场函数保证目标点为全局势能最低点。在路径解算中引入偏转角抑制因子来抑制无人车行驶过程中过大的偏转角,在无人车陷入局部极小值点后每一步的路径解算中都添加新的虚拟目标点,直至无人车累积一定的偏转角摆脱障碍物群。仿真实验结果表明,该算法可以在不影响无人车避障的情况下减少规划路径的震荡性,并能够使无人车逃脱复杂障碍物群顺利到达目标点,规划出一条有效、简短以及震荡较少的路径。

关键词: 人工势场法, 路径规划, 无人车, 震荡过滤, 偏转角抑制, 虚拟目标点, 局部极小值, 避障

Abstract:

In view of the local minimum value, unreachable target and path oscillation in the practical application of traditional artificial potential field method, this study proposes an improved artificial potential field method based on deflection angle suppression. Based on the traditional artificial potential field method, this method adopts the improved repulsive potential field function to ensure that the target point is the lowest point of the whole situation. The deflection angle inhibitor is introduced in the path solution to suppress the excessive deflection angle during the driving process of the unmanned vehicle. After the unmanned vehicle falls into the local minimum point, a new virtual target point is added to the path solution at each step until the unmanned vehicle accumulates a certain deflection angle to get rid of the obstacle group. The simulation results show that the algorithm can reduce the volatility of the planning path without affecting the obstacle avoidance of the unmanned vehicle, and enable the unmanned vehicle to smoothly escape the complex obstacle group, smoothly reach the target point, and plan an effective, short and less oscillating path.

Key words: artificial potential field method, path planning, driverless vehicle, oscillation filtering, deflection angle suppression, virtual target point, local minimum, obstacle avoidance

中图分类号:

TP242

金涛, 于莲芝. 基于偏转角抑制的改进人工势场法路径规划[J]. 电子科技, 2024, 37(10): 15-22.

JIN Tao, YU Lianzhi. Path Planning of Improved Artificial Potential Field Method Based on Deflection Angle Suppression[J]. Electronic Science and Technology, 2024, 37(10): 15-22.

图/表 22

图1

图2

图3

图4

图5

图6

图7

图8

图9

图10

表1

图11

图12

表2

图13

图14

图15

图16

图17

图18

图19

表3

参考文献 20

[1]	罗欣, 丁晓军. 地面移动作业机器人运动规划与控制研究综述[J]. 哈尔滨工业大学学报, 2021, 53(1):1-15.
	Luo Xin, Ding Xiaojun. Research and prospective on motion planning and control of ground mobile mainpulators[J]. Journal of Harbin Institute of Technology, 2021, 53(1):1-15.
[2]	卢东祥. 智能交通路径规划算法研究综述[J]. 电子科技, 2022, 35(7):22-27.
	Lu Dongxiang. A survey of intelligent transportation path planning algorithms[J]. Electronic Science and Technology, 2022, 35(7):22-27.
[3]	石志刚, 梅松, 邵毅帆, 等. 基于人工势场法的移动机器人路径规划研究现状与展望[J]. 中国农机化学报, 2021, 42(12):182-188.
	Shi Zhigang, Mei Song, Shao Yifan, et al. Research status and prospect of path planning for mobile robots based on artificial potential field method[J]. Journal of Chinese Agricultural Mechanization, 2021, 42(12):182-188.
[4]	许志远. 基于改进神经网络的船舶航行路径规划[J]. 舰船科学技术, 2022, 44(14):57-60.
	Xu Zhiyuan. Rearch on ship navigation path planning based on improved neural networks[J]. Ship Science and Technology, 2022, 44(14):57-60.
[5]	Xu X, Zhoya M. Path planning in Multi-AGVs using amodified A-star algorithm[J]. International Journal for Innovation Education and Research, 2020, 8(5):273-282.
[6]	徐伟杰, 高海若. 基于改进Dijstra算法的多源点最佳逃逸路线规划[J]. 通讯世界, 2019, 26(5):241-243.
	Xu Weijie, Gao Hairuo. Multisource optimal escape route planning based on improved Dijstra algorithm[J]. Telecom World, 2019, 26(5):241-243.
[7]	万鹏, 时培成, 梁涛年, 等. 基于粒子群算法的车道保持模型预测控制研究[J]. 机械设计与研究, 2022, 38(1):38-42,50.
	Wan Peng, Shi Peicheng, Liang Taonian, et al. Research on model predictive control of lane keeping based on particle swarm optimization[J]. Mechanical Design and Research, 2022, 38(1):38-42,50.
[8]	梁晓辉, 慕永辉, 吴北华, 等. 关于路径规划的相关算法综述[J]. 价值工程, 2020, 39(3):295-299.
	Liang Xiaohui, Mu Yonghui, Wu Beihua, et al. Summaryof path planning algorithms[J]. Value Engineering, 2020, 39(3):295-299.
[9]	豆祥忠. 基于改进人工势场法和栅格法的自主配送车避障研究[D]. 西安: 长安大学,2019:9-11.
	Dou Xiangzhong. Research of obstacle avoidance of autonomous distribution vehicle based on improved artificial potential field algorithm and grid method[D]. Xi'an: Chang'an University,2019:9-11.
[10]	罗强, 王海宝, 崔小劲, 等. 改进人工势场法自主移动机器人路径规划[J]. 控制工程, 2019, 26(6):1091-1098.
	Luo Qiang, Wang Haibao, Cui Xiaojin, et al. Autonomous mobile robot path planning based on improved artificial potential method[J]. Control Engineering of China, 2019, 26(6):1091-1098.
[11]	任工昌, 郭维鹏, 刘朋. 基于改进人工势场法的移动机器人避障研究[J]. 软件导刊, 2021, 20(2):97-101.
	Ren Gongchang, Guo Weipeng, Liu Peng. Research on obstacle avoidance of mobile robot based on improved artificial potential field method[J]. Software Guide, 2021, 20(2):97-101.
[12]	张宇迪, 龚鹏, 胡为. 改进人工势场法的智能车路径规划[J]. 机械科学与技术, 2024, 43(8):1447-1453.
	Zhang Yudi, Gong Peng, Hu Wei. Improved artificial potential field method for smart vehicle path planning[J]. Mechanical Science and Techonolgy for Aerospace Engineering, 2024, 43(8):1447-1453.
[13]	李二超, 王玉华. 改进人工势场法的移动机器人避障轨迹研究[J]. 计算机工程与应用, 2022, 58(6):296-304. doi: 10.3778/j.issn.1002-8331.2108-0122
	Li Erchao, Wang Yuhua. Research on obstacle avoidance trajectory of mobile robot based on improved artificial potential field[J]. Computer Engineering and Applications, 2022, 58(6):296-304. doi: 10.3778/j.issn.1002-8331.2108-0122
[14]	陈冠星, 张志安, 黄学功, 等. 改进人工势场法在未知环境中的路径规划研究[J]. 机械与电子, 2021, 39(5):74-80.
	Chen Guanxing, Zhang Zhian, Huang Xuegong, et al. Research on path planning of improved artificial potential field method in unknown environment[J]. Machinery & Electronics, 2021, 39(5):74-80.
[15]	李庆华, 尤越, 沐雅琪, 等. 一种针对大型凹型障碍物的组合导航算法[J]. 电子与信息学报, 2020, 42(4):917-923.
	Li Qinghua, You Yue, Mu Yaqi, et al. Integrated navigation algorithm for large concave obstacles[J]. Journal of Electronics & Information Technology, 2020, 42(4):917-923.
[16]	魏立新, 吴绍坤, 孙浩, 等. 基于多行为的移动机器人路径规划[J]. 控制与决策, 2019, 34(12):2721-2726.
	Wei Lixin, Wu Shaokun, Sun Hao, et al. Mobile robot path planning based on multi-behaviors[J]. Control and Decision, 2019, 34(12):2721-2726.
[17]	付雷, 秦一杰, 何顶新, 等. 基于改进人工势场法的多机器人编队避障[J]. 控制工程, 2022, 29(3):388-396.
	Fu Lei, Qin Yijie, He Dingxin, et al. Obstacle avoidance in multi-robot formation based on improved artificial potential field[J]. Control Engineering of China, 2022, 29(3):388-396.
[18]	宋建辉, 代涛, 刘砚菊. 基于改进人工势场法的移动机器人路径规划[J]. 计算机工程与科学, 2017, 39(7):1328-1332.
	Song Jianhui, Dai Tao, Liu Yanju. Path planning of mobile robots based on improved artificial potential field method[J]. Computer Engineering & Science, 2017, 39(7):1328-1332.
[19]	Lazarowska A. Discrete artificial potential field approach to mobile robot path planning[J]. IFAC-Papers on Line, 2019, 52(8):277-282.
[20]	郝林佳, 叶灿, 都书鲜, 等. 改进人工势场的手术机器人位姿规划[J]. 控制理论与应用, 2022, 39(6):1121-1129.
	Hao Linjia, Ye Can, Du Shuxian, et al. Pose planning for surgical robot with improved artificial potential field method[J]. Control Theory and Applications, 2022, 39(6):1121-1129.

参数	数值
障碍物半径/m	0.2
障碍物影响半径/m	1.0
斥力增益系数	0.5
目标点模糊距离/m	0.1
引力增益系数	1.0
无人车步长/m	0.2
逃脱判定周期/步	5.0

算法	步数	累积偏转角/(°)
传统势场法	88	4 836.12
引入偏转角抑制因子	69	320.27

算法	是否到达目标点	碰撞次数	步数
A	N	-	-
B	Y	4	101
C	Y	0	94