Dynamic Supernetwork Modeling of Command Information System Based on Task Timing

doi:10.16182/j.issn1004731x.joss.24-0699

Abstract

Abstract:

Due to the difficulty in reflecting the various information activities and interactions within the command information system using general modeling methods for complex system structure, the advantages of supernetwork in characterizing node heterogeneity and link multiplicity of the system were utilized. Based on the research on the mapping mechanism of the command information system across three domains, the dynamic and multifunctional properties of the functional network structure were analyzed. A dynamic supernetwork model based on task timing was constructed considering task requirements, providing model support for further research on complex interaction relationships in the command information system. The dynamic evolution process of the system structure under the driving force of combat tasks was described through a practical case, and the dynamic characteristics of the network structure were analyzed based on the feature parameters of the supernetwork model, verifying the effectiveness of the model.

Key words: command information system, supernetwork, task timing, mapping analysis, structure modeling

CLC Number:

E919

Qiu Xuehuan, Dong Zhiming, Li Liang, Liu Zhuoli. Dynamic Supernetwork Modeling of Command Information System Based on Task Timing[J]. Journal of System Simulation, 2025, 37(11): 2927-2945.

Figures/Tables 17

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Table 1

Fig. 9

Table 2

Abstraction of nodes

功能类型	节点序列	节点属性			输入信息	输出信息	对应系统单元	参与作战任务
功能类型	节点序列	高度/km	作战半径/km	机动速度/(km/s)	输入信息	输出信息	对应系统单元	参与作战任务
O	$V O 13$	21	2×10³	0.18	$e C$	$e I$	侦察机1	T₁~T₇
O	$V O 15$	28	1×10³	0.20	$e C$	$e I$	预警机-O	T₁~T₇
P	$V P 1$	0	1×10³	0	$e C / e I$	$e I$	雷达情报处理单元1	T₁~T₇
D	$V D 1$	0	2.5×10³	0	$e I$	$e C / e S$	区域联合指挥中心	T₁~T₇
D	$V D 10$	0	1.2×10³	0	$e C / e I$	$e C / e S$	空中作战指挥中心	T₁~T₇
A	$V A 10$	15	1.5×10³	0.17	$e C / e S$	$e S$	电子干扰机2-A	T₂
A	$V A 13$	20	1.5×10³	0.32	$e C / e S$	$e S$	歼击机3	T₃

Table 2

Table 3

Abstraction of edges

信息类型	连接关系	连边属性			源节点	目标节点	参与作战任务
信息类型	连接关系	依赖关系	时延/ms	保密性(0/1)	源节点	目标节点	参与作战任务
$e I$	$(V O 13, V P 4)$	$V O 13 → V P 4$	40	0	侦察机	预警信息处理单元	T₁~T₇
	$(V P 3, V D 5)$	$V P 3 → V D 5$	40	1	雷达情报处理单元3	雷达指挥中心3	T₅~T₇
	$(V P 1, V P 2)$	$V P 1 → V P 2$	40	0	雷达情报处理单元1	雷达情报处理单元2	T₁~T₇
$e C$	$(V D 1, V D 10)$	$V D 1 → V D 10$	20	1	区域联合指挥中心	空中作战指挥中心	T₁~T₇
	$(V D 10, V P 5)$	$V D 10 → V P 5$	20	1	空中作战指挥中心	电抗信息处理单元	T₂~T₇
	$(V D 6, V A 2)$	$V D 6 → V A 2$	40	1	导弹指挥车1	导弹发射单元2	T₄
$e S$	$(V A 9, V A 10)$	$V A 9 → V A 10$	40	0	电子干扰机1-A	电子干扰机2-A	T₂
$e S$	$(V D 6, V D 7)$	$V D 6 → V D 7$	20	1	导弹指挥车1	导弹指挥车2	T₄

Table 3

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Table 4

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Table 5

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作战任务	内容
情报侦察探测T₁	分配情报侦察任务，实时获取的目标情报信息经汇总处理后上报。
电子干扰攻击T₂	基于情报下达电子干扰攻击指令，对目标实施电子干扰。
空中火力突击T₃	依据反馈的战场情报分配作战任务，对目标进行火力打击。
对空远程拦截T₄	根据回传情报发送指挥信息，组织远程导弹拦截。
光电雷达干扰T₅	结合态势信息下达指令，对目标实施光电雷达干扰。
要地防空作战T₆	在情报信息保障前提下组织要地导弹拦截。
末端防御抗击T₇	综合空地态势信息下达任务，实施高炮拦截和摧毁。

作战任务	T₁	T₂	T₃	T₄	T₅	T₆	T₇
节点数	19	25	29	29	35	36	35
连边数	38	35	55	46	49	53	50
网络直径	6	8	6	8	10	10	11
平均路径长度	3.076	4.093	3.599	3.818	4.983	4.944	5.133
网络结构密度	0.222	0.117	0.135	0.113	0.082	0.084	0.084
平均聚类系数	0.808	0.411	0.701	0.401	0.385	0.306	0.364

作战任务	T₁	T₂	T₃	T₄	T₅	T₆	T₇
G_D-G_OP互联度	0.071	0.039	0.034	0.029	0.025	0.023	0.025
G_D-G_A互联度	0.000	0.167	0.143	0.125	0.111	0.100	0.111