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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Simulation of unmanned aerial vehicle swarm electromagnetic operation concept
Yang ZHANG1,2,3,*(
), Guangya SI2(), Yanzheng WANG2()
- 1. Graduate School, National Defence University, Beijing 100091, China
2. Joint Operations College, National Defence University, Beijing 100091, China
3. Luoyang Electronic Equipment Test Center, Luoyang 471003, China
-
Received:2019-09-19Online:2020-06-30Published:2020-06-30 -
Contact:Yang ZHANG E-mail:361477421@qq.com;Sgy863@163.com;wyzcyber@263.com -
Supported by:国家自然科学基金(U1435218);装备预研共用技术课题(41401050103)
CLC Number:
Cite this article
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.
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Fig.1
Conceptual design framework of the UAV swarm electromagnetic warfare based on four-ring focus"
Fig.1
Fig.2
Operational process concept view"
Fig.2
Fig.3
Diagram of ESBNI modeling framework for UAV swarm electromagnetic operations"
Fig.3
Fig.4
Diagram of UAV swarm combat force entity modeling method based on the three-tier description"
Fig.4
Fig.5
Diagram of electromagnetic behavior modeling of UAV swarm based on behavior rules"
Fig.5
Fig.6
Diagram of the ESS system modules"
Fig.6
Fig.7
Diagram of UAV swarm maneuver at T+303 s"
Fig.7
Fig.8
Diagram of UAV swarm expansion at T+440 s"
Fig.8
Fig.9
Early warning detection range of the Q area at T+350 s"
Fig.9
Fig.10
Early warning detection range of the Q area at T+417 s"
Fig.10
Fig.11
Diagram of anti-radiation attack at T+546 s"
Fig.11
Fig.12
Early warning detection range of the Q area at T+600 s"
Fig.12
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 |
Table 1
Fig.13
Scale comparison of multi-case shooting"
Fig.13
Fig.14
Comparison of efficiency cost ratios of multi-case operations"
Fig.14
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