Game Theory Based Multi-UAV Cooperative Searching Model and Fast Solution Approach

Abstract

Abstract: This paper proposed a local Nash optimal based distributed search decision method in the frame of distributed model predictive control (DMPC). To consider the interaction between the UAVs, a graph theory based multi-UAVs cooperative model was constructed, which was based on artificial potential field (AFP) cooperative mechanism. It proposed a connected component based hierarchical structure that decomposes the complex optimization problem into smaller, more manageable sub-problems, to reduce the computational complex and communication burden. In this approach, a decision priority sequence is determined by node output degree. According to the decision priority, the paper proposed three decision forms: symmetry, leader-follower(LF) and symmetry-LF form. The corresponding game models were generated. The MPC and particle swarm optimization (PSO) based method was implemented to solve the individual UAV decision making. The simulations show that this is potentially a good method for solving cooperative search problem involving a large number of vehicles with robust performance.

Key words: unmanned aerial vehicle (UAV), cooperative search, artificial potential field, graph theory, game theory, local Nash optimal, decision priority order

CLC Number:

V 249.122

DU Ji-Yong-a, ZHANG Feng-Ming-b, MAO Hong-Bao-c, LIU Hua-Wei-c, YANG Ji-a. Game Theory Based Multi-UAV Cooperative Searching Model and Fast Solution Approach[J]. Journal of Shanghai Jiaotong University, 2013, 47(04): 667-673.

References

［1］Joel G, Sujit P B, Sousa J B. Search strategies for multiple UAV search and destroy missions ［J］. Intell Robot Syst, 2011，61:355367.
［2］Yang Yanli. Cooperative search by uninhabited air vehicles in dynamic environment［D］. Cincinnati: Department of Electrical and Computer Engineering & Computer Science of the College of Engineering, University of Cincinnati, 2005.
［3］白杰，杨根科，潘常春，等. 基于改进分散搜索算法的无人机路径规划［J］. 上海交通大学学报,2011,45(2):173178.
BAI Jie, YANG Genke, PAN Changchun, et al. A revised scatter search algorithm for path planning of multiple UAVs［J］. Journal of Shanghai Jiaotong University, 2011, 45(2):173178.
［4］Sujit P B, Ghose D. Twoagent cooperative search using game models with endurance time constraints［J］. Engineering Optimization, 2010, 42(7): 617–639.
［5］杨少环，高晓光，符小卫. 基于博弈论的无人机搜索路径规划［J］.系统工程与电子技术,2011,33(10): 22542257.
YANG Shaohuan, GAO Xiaoguang, FU Xiaowei. Search path planning of unmanned aerial vehicles based on game theory［J］. Systems Engineering and Electronics, 2011, 33(10):22542257.
［6］Yan Meng. Multirobot searching using gametheory based approach［J］. International Journal of Advanced Robotic Systems, 2008, 5(4): 341350.
［7］Giovanini L, Balderud J, Katebi R. Autonomous and decentralized mission planning for clusters of UAVs ［J］. International Journal of Control, 2007, 80(7): 11691179.
［8］彭辉,沈林成,朱华勇. 基于分布式模型预测控制的多UAV协同区域搜索［J］.航空学报, 2010,31(3):593601.
PENG Hui, SHEN Lincheng, ZHU Huayong. Multiple UAV cooperative area search based on distributed model predictive control ［J］. Acta Aeronautica Et Astronautica Sinica, 2010, 31(3):593601.
［9］Itay Sisso, Tal Shima, Yakov BenHaim. Infogap approach to mutiagent search under severe uncertainty［C］∥AIAA Guidance, Navigation, and Control Conference. Chicago： AIAA, 2009:121.
［10］David Galati, Yong Liu, Simaan M. A fast algorithm for unit level team resource allocation in a game environment［C］∥Proceedings of the 42nd IEEE Conference on Decision and Control. Hawaii：IEEE, 2003: 28722877.
［11］Douglas B West.图论导引［M］. 2版. 李建中，骆吉洲, 译. 北京: 机械工业出版社，2005.
［12］严平.无人飞行器航迹规划与任务分配方法研究［D］.武汉：华中科技大学图像识别与人工智能研究所，2006.

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