[1]林子洋,顿向明,韩学行,等.基于有限状态机的AGV轨迹模块化研究[J].机械与电子,2017,(08):62-66,71.[doi:1001-2257(2017)08-0062-05]
 LIN Ziyang,DUN Xiangming,HAN Xuexing,et al.Research on AGV Modular Path Planning Based on Finite-State Machine[J].Machinery & Electronics,2017,(08):62-66,71.[doi:1001-2257(2017)08-0062-05]
点击复制

基于有限状态机的AGV轨迹模块化研究
分享到:

《机械与电子》[ISSN:1001-2257/CN:52-1052/TH]

卷:
期数:
2017年08期
页码:
62-66,71
栏目:
智能工程
出版日期:
2017-08-25

文章信息/Info

Title:
Research on AGV Modular Path Planning Based on Finite-State Machine
作者:
林子洋1顿向明1韩学行1山磊2高爱军2范俊3
(1.上海交通大学机械与动力工程学院,上海 200240; 2 宁波介量机器人技术有限公司,浙江 宁波 315500; 3 江苏泉工机器人科技有限公司,江苏 常州 213164)
Author(s):
LIN Ziyang1 DUN Xiangming1 HAN Xuexing SHAN Lei2 GAO Aijun2 FAN Jun3
(1.School of Mechanical Engineering, Shanghai Jiaotong University, Shanghai 200240,China; 2.Ningbo Vast Robot Technology Co., Ltd., Ningbo 315500,China; 3.Jiangsu Quangong Robot Technology Co., Ltd., Changzhou 213164,China)
关键词:
激光雷达 AGV 轨迹模块化 有限状态机
Keywords:
laser radar AGV modular path planning finite state machine
分类号:
TP24
DOI:
1001-2257(2017)08-0062-05
文献标志码:
A
摘要:
将结构化环境的AGV轨迹模块化与有限状态机的思路对比发现, AGV轨迹模块化可以按照有限状态机的模型、转移规则简化设计,经模块化分析与算法推导,设计实现了基于有限状态机的AGV轨迹模块化。该方法将数据处理模块得到的特征信息与路线编辑模块得到的路线逻辑表对比分析,实现AGV轨迹模块化。最后通过实验详细介绍了轨迹模块化的操作流程和实验结果,验证了轨迹模块化的可行性、先进性。
Abstract:
By comparing the AGV modular path planning in the structured environment with the idea of finite-state machine, it is found that AGV modular path planning can be simplified and designed according to the mode and transition rules of finite-state machine. In this research, the AGV modular path planning based on finite-state machine was realized based on the modular analysis and the algorithm deduction. In addition, the feature information obtained from data processing module was compared with the logical route table obtained from route editing module. Finally, the operation procedure of the modular path planning experiment and the experimental result were introduced, and the feasibility and advancement of modular path planning was validated.

参考文献/References:

[1]MARTINEZ-BARBERA H, HERRERO-PEREZ D. Development of a flexible AGV for flexible manufacturing systems[J]. Industrial Robot, 2010, 37(5):459-468.
[2]RONZONI D, OLMI R, SECCHI C, et al. AGV global localization using indistinguishable artificial landmarks[J]. IEEE International Conference on Robotics & Automation,2011, 124(1):287-292.
[3]林伟民. 基于激光雷达导向的重型自动导引运载车系统设计与研究[D]. 上海交通大学,2017.
[4]PARK HW, RAMEZANI A, GRIZZLE JW. A Finite-State Machine for Accommodating Unexpected Large Ground-Height Variations in Bipedal Robot Walking[J]. IEEE Transactions on Robotics,2013, 29(2):331-345.
[5]BROOKS RA. A Robust Layered Control System for a Mobile Robot[J]. IEEE Journal on Robotics & Automation,1986, 2(1):14-23.
[6]SALES DO, CORREA DO, FERNANDES LC, et al. Adaptive finite state machine based visual autonomous navigation system[J]. Engineering Applications of Artificial Intelligence.2014, 29(3):152–162.
[7]KURT A,(¨overO)ZGüNER ümit. Hierarchical finite state machines for autonomous mobile systems[J]. Control Engineering Practice, 2013, 21(2):184-194.
[8]许虹, 唐任仲, 程耀东. 可重构机床控制的模块化设计方法[J]. 浙 江大学学报(工学版),2004,38(1):5-10.
[9]谭超, 牛可, 仝矿伟. 基于有限状态机的采煤机变频牵引控制系统的研究[J]. 煤矿机械,2009,30(12):224-226.
[10]鲁梦昆. 基于有限状态机的全自动编织袋套袋机控制策略设计[D].武汉:湖北工业大学,2016.
[11]崔家瑞, 李擎. 基于有限状态机的智能抄表集中器设计与实现[J]. 实验室研究与探索,2014,33(8):134-139.
[12]周攀. 基于有限状态机的抽水蓄能机组工况转换控制[J]. 水电自动化与大坝监测, 2015, 1(3):91-96.

相似文献/References:

[1]周仕炜1,姜 勇2,唐煊阳1,等. 变电站带电水冲洗机器人的视觉系统标定方法[J].机械与电子,2019,(09):54.
 ,,et al.Vision System Calibration Method for Substation Charged Water Washing Robot[J].Machinery & Electronics,2019,(08):54.
[2]肖奇军,郑健聪,陈斯鹏,等.一种基于地图构建与角度传感器的扫地机器人自动回充方法[J].机械与电子,2019,(02):78.
 ,,et al.An Automatic Recharge Method of Sweeping Robot Based on Map Construction and Angle Sensor[J].Machinery & Electronics,2019,(08):78.
[3]李新斌,刘继勇,刘 星.基于小波分析的脉冲激光回波抗干扰算法研究[J].机械与电子,2018,(01):31.
 LI Xinbin,LIU Jiyong,LIU Xing.Research on Anti-Interference Algorithm for Pulse Laser Echo Based on Wavelet Analysis[J].Machinery & Electronics,2018,(08):31.
[4]李文.基于自动控制系统的机械手与AGV的设计探讨[J].机械与电子,2017,(10):76.[doi:1001-2257(2017)10-0076-05]
 LI Wen.Discussion on Design of Manipulator and AGV Based on Automatic Control System[J].Machinery & Electronics,2017,(08):76.[doi:1001-2257(2017)10-0076-05]
[5]王梦宇,张延超,李美伦,等.用于激光雷达的高精度脉冲延时及脉宽控制研究[J].机械与电子,2016,(08):3.
 WANG Mengyu,ZHANG Yanchao,LI Meilun,et al.Research on High-Precision Pulsed Delay and Pulse Width Control based on Laser Lidar[J].Machinery & Electronics,2016,(08):3.
[6]卢晓光,李凤格,许明.基于激光测风的阵风控制研究[J].机械与电子,2016,(11):69.
 LU Xiaoguang,LI Fengge,XU Ming.Research on Gust Control System Based on Laser Wind Measurement[J].Machinery & Electronics,2016,(08):69.
[7]韩 光,陈龙庆,许 义,等.基于激光雷达与倾斜摄影融合技术的电力巡检系统设计[J].机械与电子,2020,(10):27.
 HAN Guang,CHEN Longqing,XU Yi,et al.Design of Power Inspection System Based on Lidar and Oblique Photography Fusion Technology[J].Machinery & Electronics,2020,(08):27.
[8]赵 涛,弓建新,樊 荣,等.基于激光雷达的输电线路杆塔基坑监测管控系统[J].机械与电子,2022,(10):41.
 ZHAO Tao,GONG Jianxin,FAN Rong,et al.A Monitoring and Controlling System of Transmission Line Tower Foundation Pit Based on Lidar[J].Machinery & Electronics,2022,(08):41.
[9]王小龙,刘亨洋,张天毅,等.基于激光雷达的无人机路径规划研究[J].机械与电子,2023,41(08):56.
 WANG Xiaolong,LIU Hengyang,ZHANG Tianyi,et al.Research on Path Planning of UAV Based on Lidar[J].Machinery & Electronics,2023,41(08):56.

备注/Memo

备注/Memo:
收稿日期:2017-04-29
基金项目:江苏省科技厅重点研发计划(BE2015057);上海交通大学中央高校基本科研业务费资助(16JCHY03)
作者简介:林子洋(1993-),男,福建龙岩人,硕士研究生,研究方向为特种机器人;顿向明(1972-),男,上海人,副教授,博士,研究方向为特种机器人设计、智能机器人。
更新日期/Last Update: 2017-08-25