Systems Engineering and Electronics ›› 2020, Vol. 42 ›› Issue (7): 1510-1518.doi: 10.3969/j.issn.1001-506X.2020.07.12
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Yang ZHANG1,2,3,*(), Guangya SI2(), Yanzheng WANG2()
Received:
2019-09-19
Online:
2020-06-30
Published:
2020-06-30
Contact:
Yang ZHANG
E-mail:361477421@qq.com;Sgy863@163.com;wyzcyber@263.com
Supported by:
CLC Number:
Yang ZHANG, Guangya SI, Yanzheng WANG. Simulation of unmanned aerial vehicle swarm electromagnetic operation concept[J]. Systems Engineering and Electronics, 2020, 42(7): 1510-1518.
Table 1
Simulation scenario design table"
想定名称 | 想定概要设计 | 评估指标 |
基本想定 | W军导弹作战力量根据目标列表,向Q地区预定目标实施火力打击作战行动,未实施任何电磁作战 支援行动 | 1. W军摧毁目标数量 2. L军拦截数量 3.作战成本 4.作战收益 5.作战效费比 |
对比想定1 | W军导弹作战力量根据目标列表,向Q地区目标实施火力打击行动; W军指挥员向预定作战区域派 出3架电子战飞机,进行远距离支援干扰行动 | |
对比想定2 | W军导弹作战力量根据目标列表,向Q地区目标实施火力打击作战行动,齐射规模为24枚;同时, 指挥员向预定作战区域派出由1架有人机负责指挥控制, 10架认知通信 对抗UAV(编组为认知通信对抗UAV分群),以及若干架认知雷达对抗UAV(编组为认知雷达对抗UAV分群)负责具体行动 的抗UAV蜂群,实施“雷电蜂”作战行动,近距离干扰支援;各UAV不具备反辐射攻击功能 | |
对比想定3 | W军指挥员根据目标列表,向预定作战区域派出由1架有人机负责指挥控制, 10架认知通信对抗 UAV(编组为认知通信对抗UAV分群),以及若干架认知雷达对抗 UAV(编组为认知雷达对抗UAV分群)负责具体行动的电磁对抗UAV蜂群,实施“雷电蜂”作战行动,近距离干扰与反辐射攻 击目标;导弹作战力量不实施火力打击行动 |
1 | 胡晓峰. 战争工程论——走向信息时代的战争方法学[M]. 北京: 科学出版社, 2018. |
HU X F . On war engineering-war methodology towards the information age[M]. Beijing: Science Press, 2018. | |
2 | PHAM L . UAV swarm attack:protection system alternatives for destroyers[J]. Monterey, California, USA: Navy Postgraduate School, 2012, 12, 120- 130. |
3 | CHUNG T H, JONES K D, DAY M A. 50 vs. 50 by 2015: swarm vs. swarm UAV live-fly competition at the naval postgraduate school[R]. Monterey, California, USA: Navy Postgraduate School, 2015, 3: 1-10. |
4 | 张敏. 智能战争时代,谁来开火?[J]. 军事文摘, 2017, 21, 23- 26. |
ZHANG M . Who is going to fire in the era of intelligent warfare?[J]. Military Digest, 2017, 21, 23- 26. | |
5 |
杨镜宇, 胡晓峰. 基于体系仿真试验床的新质作战能力评估[J]. 军事运筹与系统工程, 2016, 30 (3): 5- 9.
doi: 10.3969/j.issn.1672-8211.2016.03.001 |
YANG J Y , HU X F . New type operation evaluation based on SoS simulation test bed[J]. Military Operations Research and Systems Engineering, 2016, 30 (3): 5- 9.
doi: 10.3969/j.issn.1672-8211.2016.03.001 |
|
6 |
RABAH M , ROHAN A , TALHA M , et al. Autonomous vision-based target detection and safe landing for UAV[J]. International Journal of Control Automation and Systems, 2018, 16 (6): 3013- 3025.
doi: 10.1007/s12555-018-0017-x |
7 | BRYAN C , MARK G . Winning in the gray zone-using electromagnetic warfare to regain escalation dominance[J]. Washington, DC, USA: Center for Strategic and Budgetary Assessments (CSBA), 2017, 10, 30- 32. |
8 | HUANG S , TEO R S H . Distributed UAV loss detection and auto-replacement protocol with guaranteed properties[J]. Journal of Intelligent & Robotic Systems Theory & Applications, 2019, 93 (1/2): 303- 316. |
9 | JOHN K . Regaining the advantage cognitive electronic warfare[J]. The Journal of Electronic Defense, 2016, 12, 56- 63. |
10 | OSNER N R , DU P W P . Threat evaluation and jamming allocation[J]. IET Radar, Sonar & Navigation, 2017, 11 (3): 459- 465. |
11 | OSNER N, PLESSIS W. Electronic warfare training applications of decision-support systems[C]//Proc.of the Defense Operation Application, 2017: 130-135. |
12 | ROSALIE M, DANOY G. UAV multilevel swarms for situation management[C]//Proc.of the 16th DroNet, 2016: 49-52. |
13 | ZHANG S Z . Swarm intelligence applied in green logistics: a literature review[J]. Engineering Application of Artificial Intelligence, 2015, 37 (7): 16- 17. |
14 | DABKOWSKI M , COOK J , KEWLEY R . Swarming UAS II[J]. West Point, New York, USA: United States Military Academy, Department of Systems Engineering, 2010, 2- 6. |
15 | LI N , HUAI W Q , WANG S D . The solution of target assignment problem in command and control decision-making behaviour simulation[J]. Enterprise Information Systems, 2016, 11 (7): 1059- 1077. |
16 | LIU W , GU W , SHENG W X , et al. Decentralized multi-agent system-based cooperative frequency control for autonomous microgrids with communication constraints[J]. IEEE Trans.on Sustainable Energy, 2017, 5 (2): 446- 456. |
17 | ZBYNEK O. Software environment for simulation of UAV multi-agent system[C]//Proc.of the 21st International Conference on Methods and Models in Automation and Robotics, 2016: 134-139. |
18 | ZHU X P , LIU Z C , YANG J . Model of collaborative UAV swarm toward coordination and control mechanisms study[J]. Procedia Computer Science, 2015, 51 (5): 493- 502. |
19 | TIWARI R, JAIN P, BUTAIL S. Effect of leader placement on robotic swarm control[C]//Proc.of the 16th International Conference on Autonomous Agents and Multiagent Systems, 2017: 1387-1392. |
20 | GILES C K . A framework for integrating the development of swarm unmanned aerial system doctrine and design[J]. Monterey, California, USA: Department of Systems Engineering Naval Postgraduate School, 2017, 9- 10. |
21 | DOMENICO P, SALVTORE V, ROCCO A. Agent-based design for UAV mission planning[C]//Proc.of the 8th International Conference on P2P, Parallel, Grid, Cloud and Internet Computing, 2013: 76-83. |
22 | JENSEN J S, BUCHANAN K, HUFF G H. A computer vision-based framework for the synthesis and analysis of beamforming behavior in swarming intelligent systems[C]//Proc.of the IEEE Radar Conference, 2017: 118-122. |
23 | WILSON O Q, RODRIGUEZ I J. Leader-follower formation for UAV robot swarm based on fuzzy logic theory[C]//Proc.of the Artificial Intelligence and Soft Computing, 2018: 740-751. |
24 | 司光亚, 王艳正. 网络空间作战建模仿真[M]. 北京: 科学出版社, 2018. |
SI G Y , WANG Y Z . Modeling and simulation of cyberspace operation[M]. Beijing: Science Press, 2018. | |
25 | PENG G, FANG Y W, CHEN S H. A hybrid multi-objective discrete particle swarm optimization algorithm for cooperative air combat DWTA[C]//Proc.of the 11st Bio-Inspired Computing-Theories and Applications, 2016: 114-119. |
26 | YANG J , LIU J . Influence maximization-cost minimization in social networks based on a multiobjective discrete particle swarm optimization algorithm[J]. IEEE Access, 2018, 99 (6): 2320- 2329. |
27 | ALYSSA P, DANIELA R. Distributed target tracking in cluttered environments with guaranteed collision avoidance[C]//Proc.of the International Symposium on Multi-robot & Multi-agent Systems, 2017: 83-89. |
28 | FANG Q , XU Q . 3D route planning for UAV based on improved PSO algorithm[J]. Journal of Northwestern Polytechnical University, 2017, 35 (1): 66- 73. |
29 | SARA P, JULIAN B, EVA B. A multi-UAV minimum time search planner based on ACOR[C]//Proc.of the Genetic and Evolutionary Computation Conference, 2017: 35-42. |
30 | 戴浩. 无人机系统的指挥控制[J]. 指挥与控制学报, 2016, 2 (1): 5- 8. |
DAI H . Command and control for unmanned aerial vehicles[J]. Journal of Command and Control, 2016, 2 (1): 5- 8. |
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