基于协同和网络效应的作战体系效能评估方法

doi:10.12305/j.issn.1001-506X.2025.11.23

摘要/Abstract

摘要：

针对作战体系效能评估中协同效应难融合、网络特性难体现的问题，提出融合协同效应模型（coordination effect model，CEM）和三维权重耦合（three-dimensional weight coupling，TDWC）的作战体系效能评估方法。构建加权有向作战体系网络模型，结合层次化模糊赋值方法量化节点与连边能力。依据作战要素交互机理，建立6类协同效应模型，提出基于CEM作战链效能评估方法。在此基础上，构建融合时效性、综合中心性和抗毁性的TDWC模型，形成基于CEM-TDWC的作战体系效能评估模型。4种作战场景仿真验证所提方法能更精准反映节点能力、协同效应与网络拓扑的耦合作用，更科学地反映体系作战能力，为作战体系效能评估理论创新提供一种新的研究思路。

关键词: 作战体系效能, 协同建模, 作战链, 层次化模糊赋值, 三角模糊数聚合, 三维权重

Abstract:

To address the problem of difficult integration of coordination effects and reflection of network characteristics in the evaluation of combat system effectiveness, a combat system effectiveness evaluation method combining coordinated effect model （CEM） and three-dimensional weight coupling （TDWC） is proposed. A weighted directed combat system network model is constructed, combined with a hierarchical fuzzy assignment method to quantify node and edge capabilities. Based on the interaction mechanism of combat elements, six types of collaborative effect models are established, and a CEM based combat chain effectiveness evaluation method is proposed. On this basis, an TDWC model that integrates timeliness, integrated centrality, and resilience is constructed, forming a combat system effectiveness evaluation model based on CEM-TDWC. Through simulation verification in four combat scenarios, the proposed method can more accurately reflect the coupling effect of node capabilities, collaborative effects, and network topology, and more scientifically reflect the system’s combat capabilities. This research provides a new research approach for the theoretical innovation of combat system effectiveness evaluation.

Key words: combat system effectiveness, coordination modeling, combat chain, hierarchical fuzzy assignment, triangular fuzzy number aggregation, three-dimensional weight

中图分类号:

E 917

汪江鹏, 杨萍, 汪民乐, 闫少强. 基于协同和网络效应的作战体系效能评估方法[J]. 系统工程与电子技术, 2025, 47(11): 3754-3764.

Jiangpeng WANG, Ping YANG, Minle WANG, Shaoqiang YAN. Combat system effectiveness evaluation method based on coordination and network effects[J]. Systems Engineering and Electronics, 2025, 47(11): 3754-3764.

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语义项	三角模糊数（a, b, c）	说明
VL （极低）	（0.0, 0.1, 0.3）	几乎无法满足作战需求
L （低）	（0.2, 0.3, 0.5）	需大幅改进才能达标
M （中等）	（0.4, 0.5, 0.6）	基本满足需求，无显著优势
H （高）	（0.6, 0.7, 0.8）	显著优于基准水平
VH （极高）	（0.7, 0.9, 1.0）	接近理论最优值

语义项	三角模糊数
H	（a₁, b₁, c₁）
VH	（a₂, b₂, c₂）
H	（a₃, b₃, c₃）

节点能力	评价1	评价2	评价3	评价4	评价5
情报获取能力	H	VH	VH	H	VH
实时性	M	H	M	H	H
抗干扰能力	L	M	L	M	M
隐蔽生存能力	VH	H	VH	H	VH

维度	聚合模糊数	去模糊值
情报获取能力	（0.66, 0.82, 0.92）	0.805
实时性	（0.52, 0.62, 0.72）	0.620
抗干扰能力	（0.32, 0.42, 0.56）	0.430
隐蔽生存能力	（0.66, 0.82, 0.92）	0.805

类型	综合能力值	类型	综合能力值	类型	综合能力值
A₁	0.85	EG₁	0.927	P₅, A₅	0.88
A₂	0.8	EG₂	0.915	P₆, A₇	0.8
A₃	0.85	EG₃	0.62	P₇, A₈	0.8
A₄	0.8	EG₄	0.879	P₈, A₉	0.78
A₅	0.9	EG₅	0.661	A₁, A₄	0.9
A₆	0.8	EG₆	0.832	A₁, A₅	0.9
A₇	0.75	NG₁	0.912	A₁, A₉	0.9
A₈	0.82	NG₂	0.92	A₂, A₁	0.95
A₉	0.75	NG₃	0.75	A₁, A₂	0.95
S₁	0.8	NG₄	0.667	A₃, A₁	0.95
S₂	0.7	NG₅	0.62	A₁, A₃	0.95
S₃	0.7	EG₁, A₁	0.927	A₄, S₁	0.85
S₄	0.8	EG₂, S₁	0.93	A₄, S₂	0.85
S₅	0.86	EG₂, S₂	0.932	A₄, S₃	0.95
S₆	0.82	EG₃, S₃	0.93	A₅, A₇	0.95
S₇	0.842	EG₄, A₇	0.842	A₅, A₈	0.92
S₈	0.9	EG₅, S₁₀	0.811	A₆, A₅	0.92
S₉	0.8	EG₆, S₁₁	0.813	A₅, A₆	0.92
S₁₀	0.75	NG₁, P₂	0.894	A₇, S₄	0.9
S₁₁	0.7	NG₂, S₁	0.957	A₇, S₅	0.9
P₁	0.75	NG₃, S₂	0.718	A₇, S₆	0.9
P₂	0.863	NG₄, S₃	0.886	A₈, S₇	0.9
P₃	0.849	NG₅, S₄	0.866	A₈, S₈	0.9
P₄	0.832	NG₅, S₅	0.866	A₈, S₉	0.9
P₅	0.817	P₁, A₁	0.872	A₉, S₁₀	0.9
P₆	0.798	P₂, A₁	0.868	A₉, S₁₁	0.9
P₇	0.881	P₃, A₄	0.955
P₈	0.963	P₄, A₅	0.832