无人机集群任务分配的多目标算法研究

doi:10.19665/j.issn1001-2400.20230413

Abstract

Abstract:

Aiming at the cooperative task allocation problem of UAV swarm in target recognition scenario,an optimization model with recognition cost and recognition benefit as the goal is established,and a multi-objective differential evolution algorithm based on decomposition is designed to solve the model.First,an elite initialization method is proposed,and the initial solution is screened to improve the quality of the solution set on the basis of ensuring the uniform distribution of the obtained nondominated solution.Second,the multi-objective differential evolution operator under integer encoding is constructed based on the model characteristics to improve the convergence speed of the algorithm.Finally,a tabul search strategy with restrictions is designed,so that the algorithm has the ability to jump out of the local optimal.The algorithm provides a set of nondominated solution sets for the solution of the problem,so that a more reasonable optimal solution can be selected according to actual needs.After obtaining the allocation scheme by the above method,the task reallocation strategy is designed based on the auction algorithm,and the allocation scheme is further adjusted to cope with the unexpected situation of UAV damage.On the one hand,simulation experiments verify the effectiveness of the proposed algorithm in solving small,medium and large-scale task allocation problems,and on the other hand,compared with other algorithms,the nondominated set obtained by the proposed algorithm has a higher quality,which can consume less recognition cost and obtain higher recognition revenue,indicating that the proposed algorithm has certain advantages.

Key words: task allocation, unmanned aerial vehicles, multi-objective optimization, evolutionary algorithms, tabu search

CLC Number:

TP301.6

GAO Weifeng, WANG Qiong, LI Hong, XIE Jin, GONG Maoguo. Research on the multi-objective algorithm of UAV cluster task allocation[J].Journal of Xidian University, 2024, 51(2): 1-12.

Figures/Tables 13

References 17

[1]	LIN W C, LIAO D Y, LIU C Y, et al. Daily Imaging Scheduling of an Earth Observation Satellite[J]. IEEE Transactions on Systems,Man,and Cybernetics-Part A:Systems and Humans, 2005, 35(2):213-223.
[2]	GUO W Z, LI J, CHEN G L, et al. A PSO-Optimized Real-Time Fault-Tolerant Task Allocation Algorithm in Wireless Sensor Networks[J]. IEEE Transactions on Parallel and Distributed Systems, 2015, 26(12):3236-3249.
[3]	TAL S, STEVEN J R, ANDREW G S, et al. Multiple Task Assignments for Cooperating Uninhabited Aerial Vehicles Using Genetic Algorithms[J]. Computer and Operations Research, 2006, 33(11):3252-3269.
[4]	黄刚, 李军华. 基于AC-DSDE进化算法多UAVs协同目标分配[J]. 自动化学报, 2021, 47(1):173-184.
	HUANG Gang, LI Junhua. Multi-UAV Cooperative Target Allocation Based on AC-DSDE Evolutionary Algorithm[J]. Acta Automatica Sinica, 2021, 47(1):173-184.
[5]	JANA B, CHAKRABORTY M, MANDAL T. A Task Scheduling Technique Based on Particle Swarm Optimization Algorithm in Cloud Environment[J]. Advances in Intelligent Systems and Computing, 2019,742:525-536.
[6]	ALENCAR R C, SANTANA C J, BASTOS-FILHO C J A. Optimizing Routes for Medicine Distribution Using Team Ant Colony System[J]. Advances in Intelligent Systems and Computing, 2020,923:40-49.
[7]	LUO J P, LIU Q Q, YANG Y, et al. An Artificial Bee Colony Algorithm for Multi-Objective Optimization[J]. Applied Soft Computing, 2017,50:235-251.
[8]	DEB K, PRATAP A, AGARWAL S, et al. A Fast and ElitistMultiobjective Genetic Algorithm:NSGA-Ⅱ[J]. IEEE Transactions on Evolutionary Computation, 2002, 6(2):182-197.
[9]	ZHANG Q F, LI H. MOEA/D:A Multi-Objective Evolutionary Algorithm Based on Decomposition[J]. IEEE Transactions on Evolutionary Computation, 2007, 11(6):712-731.
[10]	刘天宇, 曹磊. 多任务机制驱动的高维多目标进化算法[J]. 西安电子科技大学学报, 2022, 49(4):134-143.
	LIU Tianyu, CAO Lei. Many-Objective Evolutionary Algorithm Based on the Multitasking Mechanism[J]. Journal of Xidian University, 2022, 49(4):134-143.
[11]	ZHANG C J, TAN K C, LEE L H, et al. Adjust Weight Vectors in MOEA/D for Bi-Objective Optimization Problems with Discontinuous Pareto Fronts[J]. Soft Computing:A Fusion of Foundations, Methodologies and Application, 2018, 22(12):3997-4012.
[12]	HUA Y, JIN Y, HAO K. A Clustering-Based Adaptive Evolutionary Algorithm for Multiobjective Optimization with Irregular Pareto Fronts[J]. IEEE Transactions on Cybernetics, 2019, 49(7):2758-2770. doi: 10.1109/TCYB.2018.2834466 pmid: 29994342
[13]	STORN R, PRICE K. Differential Evolution-A Simple and Efficient Heuristic for Global Optimization over Continuous Spaces[J]. Journal of Global Optimization, 1997,11:341-359.
[14]	LARA A, SANCHEZ G, COELLO C A C, et al. HCS:A New Local Search Strategy for Memetic Multiobjective Evolutionary Algorithms[J]. IEEE Transactions on Evolutionary Computation, 2010, 14(1):112-132.
[15]	CHENG R, JIN Y C, OLHOFER M, et al. A Reference Vector Guided Evolutionary Algorithm for Many-Objective Optimization[J]. IEEE Transaction on Evolutionary Computation, 2016, 20(5):773-791.
[16]	LIANG Z P, LUO T T, HU K F, et al. An Indicator-Based Many-Objective Evolutionary Algorithm with Boundary Protection[J]. IEEE Transactions on Cybernetics, 2021, 51(9):4553-4566.
[17]	封文清, 巩敦文. 基于在线感知Pareto前沿划分目标空间的多目标进化优化[J]. 自动化学报, 2020, 46(8):1628-1643.
	FENG Wenqing, GONG Dunwen. Multi-Objective Evolutionary Optimization with Objective Space Partition Based on Online Perception of Pareto Front[J]. Acta Automatica Sinica, 2020, 46(8):1628-1643.

目标点编号	目标点所在范围中心/(km,km)
T₁	(10,15)
T₂	(10,35)
T₃	(25,10)
T₄	(25,26)
T₅	(25,40)
T₆	(40,15)
T₇	(40,35)

编号	威胁区中心位置/(km,km)	威胁半径/km
威胁区1	(10,15)	3
威胁区2	(10,35)	3
威胁区3	(25,10)	3

无人机编号	位置坐标/(km,km)	传感器配置	无人机编号	位置坐标/(km,km)	传感器配置
U₁	(29,37)	雷达	U₁₅	(20,39)	红外
U₂	(43,34)	雷达	U₁₆	(22,47)	红外
U₃	(13,35)	雷达	U₁₇	(18,17)	红外
U₄	(47,17)	雷达	U₁₈	(38,33)	红外
U₅	(6,37)	ESM	U₁₉	(31,22)	红外
U₆	(27,44)	ESM	U₂₀	(38,41)	红外
U₇	(36,20)	ESM	U₂₁	(48,9)	红外
U₈	(18,27)	IFF	U₂₂	(35,26)	可见光
U₉	(8,5)	IFF	U₂₃	(5,44)	可见光
U₁₀	(29,6)	IFF	U₂₄	(26,29)	可见光
U₁₁	(37,25)	IFF	U₂₅	(43,10)	可见光
U₁₂	(12,10)	IFF	U₂₅	(24,20)	可见光
U₁₃	(22,25)	IFF	U₂₇	(20,37)	可见光
U₁₄	(18,3)	IFF	U₂₈	(37,19)	可见光

参数	数值
种群个体数目	50
最大迭代次数	200
理想参考点z^*	(0,0)
变异概率ε	0.1
交叉概率	0.6
无人机最大航程L_max/km	40

无人机编号	传感器配置	无人机编号	传感器配置
U₁	可见光+雷达	U₈	红外+IFF
U₂	红外+雷达	U₉	可见光+IFF
U₃	可见光+雷达	U₁₀	红外+IFF
U₄	红外+雷达	U₁₁	可见光+IFF
U₅	可见光+ESM	U₁₂	红外+IFF
U₆	红外+ESM	U₁₃	可见光+IFF
U₇	可见光+ESM	U₁₄	红外+IFF

Research on the multi-objective algorithm of UAV cluster task allocation

RichHTML

PDF (PC)

Like

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 13

References 17

Related Articles 15

Metrics

Comments

Recommended 0

小规模		中规模		大规模
N<4M	N=4M	N<4M	N=4M	N<4M	N=4M
15U-5T	20U-5T	35U-10T	40U-10T	90U-25T	100U-25T

[1]	HU Jialin, REN Zhiyuan, LIU Anni, CHENG Wenchi, LIANG Xiaodong, LI Shaobo. UAV swarm power allocation strategy for resilient topology construction [J]. Journal of Xidian University, 2024, 51(2): 28-45.
[2]	SUN Yanjing, LI Lin, WANG Bowen, LI Song. Highly dynamic multi-channel TDMA scheduling algorithm for the UAV ad hoc network in post-disaster [J]. Journal of Xidian University, 2024, 51(2): 56-67.
[3]	ZHANG Boyang, CHU Yi, YANG Zhongping, ZHOU Qingsong. Efficient manifold algorithm for the waveform design for precision jamming [J]. Journal of Xidian University, 2023, 50(6): 84-92.
[4]	LIU Jingmei,YAN Yibo. Artificial fish feature selection network intrusion detection system [J]. Journal of Xidian University, 2023, 50(4): 132-138.
[5]	WU Yihao,QI Yanli,ZHOU Yiqing,CAI Qing,LIU Ling,SHI Jinglin. UAVs trajectory planning and power allocation based on the convergence of communication,sensing and computing [J]. Journal of Xidian University, 2023, 50(3): 61-74.
[6]	XU Zimeng,WANG Bowen,YUN Xiao,WANG Xiaolin. Stable relay selection method under an uncertain preference ordinal for UAV in post-disaster [J]. Journal of Xidian University, 2022, 49(6): 32-41.
[7]	ZHANG Hao, QIN Tao, XU Linghua, WANG Xiao, YANG Jing. WSNs node deployment strategy based on the improved multi-objective ant-lion algorithm [J]. Journal of Xidian University, 2022, 49(5): 47-59.
[8]	LIU Tianyu,CAO Lei. Many-objective evolutionary algorithm based on the multitasking mechanism [J]. Journal of Xidian University, 2022, 49(4): 134-143.
[9]	DU Wenzhan,YU Zhiyong,YANG Jian,JIANG Haibin. Improved NSGA-II algorithm and research on monitoring antenna optimization deployment [J]. Journal of Xidian University, 2021, 48(5): 239-248.
[10]	WANG Yan. Enhanced multi-objective evolutionary algorithm for workflow scheduling on the cloud platform [J]. Journal of Xidian University, 2019, 46(1): 130-136.
[11]	WANG Danqing;LI Ping. Expedited antenna multi-objective optimization method based on gradient-enhanced kriging surrogate model [J]. Journal of Xidian University, 2018, 45(2): 129-134+165.
[12]	WANG Mingzhao;WANG Yuping;WANG Xiaoli;WEI Zhen. Improved NSGA-Ⅱ algorithm based on the uniformly crowding distance [J]. Journal of Xidian University, 2016, 43(3): 49-54+130.
[13]	LEI Yu;JIAO Licheng;GONG Maoguo;LI Lingling. Enhanced NNIA for multi-objective examination timetabling problems [J]. Journal of Xidian University, 2016, 43(2): 157-161+192.
[14]	WEN Honghang;GE Jianhua;XU Tangwen. Low complexity method for PAPR reduction of OFDM signals [J]. J4, 2015, 42(5): 188-193.
[15]	DAI Cai;WANG Yuping;HE Xiaoguang. New ranking method for many-objective problems [J]. J4, 2014, 41(6): 89-94.