Robot Real-time Obstacle Avoidance Algorithm Based on Prediction of Obstacle Reachable Area

doi:10.12068/j.issn.1005-3026.2022.09.002

Abstract

Abstract: For the path planning and autonomous obstacle avoidance problem of robot in complex environment， a real-time obstacle avoidance algorithm is proposed based on the prediction of the reachable area of dynamic obstacles. The static obstacles are described and modelled， and the state update prediction equations of dynamic obstacles are established to realize the prediction of the reachable area of dynamic obstacle mass center. For dynamic and static obstacles， a multi-step elliptic envelope potential field based on reachable area prediction and a potential field based on the novel Sigmoid function are proposed， respectively， to modify the target’s logarithmic Lyapunov gravitational field. A real-time obstacle avoidance algorithm is given for robot in the environment of multi-type obstacles. The numerical simulation and experimental results show that compared with traditional methods， the real-time obstacle avoidance algorithm can realize shorter path length， higher security and smaller driving angle during obstacle avoidance process.

Key words: robot; reachable area prediction; multi-step elliptic enveloping potential field; Sigmoid function potential field; real-time obstacle avoidance

CLC Number:

TP20

PENG Fan， XIE Yong-fang， CHEN Xiao-fang， YIN Ze-yang. Robot Real-time Obstacle Avoidance Algorithm Based on Prediction of Obstacle Reachable Area[J]. Journal of Northeastern University(Natural Science), 2022, 43(9): 1225-1233.

References

[1]Warren C.Fast path planning using modified A* method［C］// IEEE International Conference on Robotics and Automation.New York，1993:662-667.
[2]Beard R W，Mclain W，Goodrich M A，et al.Coordinated target assignment and intercept for unmanned air vehicles［J］.IEEE Transactions on Robotics and Automation，2003，18(6):911-922.
[3]Sanchez G，Latombe J C.On delaying collision checking in PRM planning:application to multi-robot coordination［J］.International Journal of Robotics Research，2002，21(1):5-26.
[4]Mo H，Xu L.Research of biogeography particle swarm optimization for robot path planning［J］.Neurocomputing，2015，148(10):91-99.
[5]Roberge V，Tarbouchi M，Labonte G.Comparison of parallel genetic algorithm and particle swarm optimization for real-time UAV path planning［J］.IEEE Transactions on Industrial Informatics，2013，9(1):132-141.
[6]刘杰，闫清东，马越，等.基于蚁群几何优化算法的全局路径规划［J］.东北大学学报(自然科学版)，2015，36(7)，923-928.(Liu Jie，Yan Qing-dong，Ma Yue，et al.Global path planning based on improved ant colony optimization algorithm for geometry［J］.Journal of Northeastern University(Natural Science)，2015，36(7):923-928.)
[7]宋晓琳，周南，黄正瑜，等.改进RRT在汽车避障局部路径规划中的应用［J］.湖南大学学报(自然科学版)，2017，44(4):30-37.(Song Xiao-lin，Zhou Nan，Huang Zheng-yu，et al.An improved RRT algorithm of local path planning for vehicle collision avoidance［J］.Journal of Hunan University(Natural Sciences)，2017，44(4):30-37.)
[8]Du L，Bo S，Liu Y，et al.Genetic algorithm-based compliant robot path planning:an improved bi-RRT-based initialization method［J］.Assembly Automation，2017，37(3):1-10.
[9]Fulgenzi C，Spalanzani A，Laugier C.Dynamic obstacle avoidance in uncertain environment combining pvos and occupancy grid［C］//IEEE International Conference on Robotics and Automation.Roma，2007:1610-1616.
[10]Saravanakumar S，Asokan T.Multipoint potential field method for path planning of autonomous underwater vehicles in 3D space［J］.Intelligent Service Robotics，2013，6(4):211-224.
[11]Ren J，Mcisaac K A，Patel R V，et al.A potential field model using generalized Sigmoid functions［J］.IEEE Transactions on Systems Man and Cybernetics Part B(Cybernetics)，2007，37(2):77-84.
[12]卞永明，季鹏成，周怡和，等.基于改进型DWA的移动机器人避障路径规划［J］.中国工程机械学报，2021，19(1):44-49.(Bian Yong-ming，Ji Peng-cheng，Zhou Yi-he，et al.Obstacle avoidance path planning of mobile robot based on improved DWA［J］.Chinese Journal of Construction Machinery，2021，19(1):44-49.)

[1]	GENG Rong， WU Ya-qian， XIAO Qian-qian， XU Sai. Research on Resource Prediction of Space-based Information Network Based on Improved GRU Algorithm [J]. Journal of Northeastern University(Natural Science), 2023, 44(3): 305-314.
[2]	LUO Zhong， WU Dong-ze，LI Lei， GE Chang-chuang. Design and Experimental Verification of Rotor System Dynamics Simulation Platform [J]. Journal of Northeastern University(Natural Science), 2023, 44(3): 375-381.
[3]	HOU Zhen-long， ZHENG Yu-jun， GONG En-pu， CHENG Hao. Joint Correlation Imaging Inversion with Gravity Gradiometry Data Based on Depth Weighting [J]. Journal of Northeastern University Natural Science, 2020, 41(11): 1628-1632.
[4]	WU Chao， LI Yuan-hui， XU Shuai， DAI Xing-hang. Method for Determining the Lower Limit of Statistical Joints Trace Length in Underground Engineering Rock Mass [J]. Journal of Northeastern University Natural Science, 2020, 41(8): 1167-1173.
[5]	WEN Shou-qin， TANG Tie-qiao， XIE Wei， FU Jian-fei. Constraints of f_O▲2 and f_S▲2 on the Paragenesis and Separation of Mineral Assemblages in Hongqi Pb-Zn Deposit， Xiuyan [J]. Journal of Northeastern University Natural Science, 2020, 41(7): 999-1007.
[6]	QI Xi-jing， TANG Liang， KANG Wei-xin， QIN Jiao-jiao. Multi-objective Decision-Making Method for Bridge Deck Maintenance Scheme for Highway [J]. Journal of Northeastern University Natural Science, 2020, 41(7): 1033-1040.
[7]	CAI Zhi-hui， ZHANG De-liang， ZHOU Yan-jun， WEN Guang-qi. Effect of Strain Rate on Deformation Behavior of Fe-11Mn-2Al-0.2C Medium-Mn Steel [J]. Journal of Northeastern University Natural Science, 2020, 41(7): 1041-1047.
[8]	MA Shu-jun， WANG Xiao-xiao. Influence of Adsorbed Micro-particles on Micro-suspended Bridge Sensor [J]. Journal of Northeastern University Natural Science, 2020, 41(1): 108-112.
[9]	MA Shu-jun， XUAN Hang， SUN Jia-wei， YANG Lei. Modeling and Simulation of Micro-cantilever Vibrating in Inviscid Fluid Domains [J]. Journal of Northeastern University Natural Science, 2018, 39(9): 1272-1276.
[10]	MA Shu-jun， XIU Qiang. Modelling and Simulation of a Surface Stress-Included Microcantilever-based Mass Sensor [J]. Journal of Northeastern University Natural Science, 2018, 39(2): 237-241.
[11]	CHEN Da-li， SHEN Yan-tao， XIE Bing-zhu， MA Ying-yi. A Measure Model of Similarity for Finding the Best Coach [J]. Journal of Northeastern University Natural Science, 2014, 35(12): 1697-1700.
[12]	PAN Feng， LIU Lu， XUE Dingyu. Optimal FractionalOrder PIλDμ Network Delay Controller [J]. Journal of Northeastern University Natural Science, 2014, 35(10): 1382-1385.
[13]	LIU Lu， PAN Feng， XUE Dingyu. A FractionalOrder Kalman Filter〓 [J]. Journal of Northeastern University Natural Science, 2014, 35(8): 1069-1072.
[14]	LIU Jin-hai， FENG Jian， MA Da-zhong. A High Accurate and Real Time Filter Method for Pressure Signal of Fluid Pipeline [J]. Journal of Northeastern University:Natural Science, 2013, 34(1): 9-12.
[15]	SUN Yanrui. Reliability Evaluation of StochasticFlow Network Under both Time and Cost Constraints [J]. Journal of Northeastern University(Natural Science), 2013, 34(11): 1537-1541.