Design and Verification of Manned-unmanned Collaborative Combat Capability System Based on MBSE

doi:10.16182/j.issn1004731x.joss.25-0007

Abstract

Abstract:

The traditional model-based systems engineering (MBSE) method has problems of failing to fully exhibit complex combat logics in manned-unmanned collaborative combat system modeling, neglecting the scenario constraints in interface modeling, and requiring long-term and costly algorithm verification. In order to solve the problems, a methodology and design tool based on MBSE was proposed. An integrated verification method of a system's operational logic, interface design, and algorithmic design was constructed, thus providing a digital and rapidly iterative verification approach for system simulation. A verification environment for multiple key algorithm simulations was established, effectively reducing the economic cost of building verification environments. The design and verification practices were completed in a typical manned-unmanned collaborative combat system. By integrating the MBSE design tool Modelook and the battlefield simulation design tool, the method enabled the integrated verification of the system's operational logic, data interaction models, and key algorithm models described by SysML. Experimental results demonstrate that this method can provide the system with a digital, low-cost, and agile iterative model simulation verification early in the design phase, enhancing comprehensive capabilities of digital prototype from a functional logic level to a level integrating functional logic and key algorithms.

Key words: model-based systems engineering(MBSE), featuring manned-unmanned collaborative combat, design and verification of a typical system, SysML, combat simulation modeling

CLC Number:

TP391.9

Wang Fangbo, Guo Jian, Du Chenglie, Liu Yifan, Zhang Pengpeng. Design and Verification of Manned-unmanned Collaborative Combat Capability System Based on MBSE[J]. Journal of System Simulation, 2026, 38(3): 800-807.

Figures/Tables 10

Fig. 1

Fig. 2

Fig. 3

Fig. 4

Fig. 5

Fig. 6

Fig. 7

Fig. 8

Fig. 9

Fig. 10

References 14

[1]	樊洁茹, 李东光. 有人机/无人机协同作战研究现状及关键技术浅析[J]. 无人系统技术, 2019, 2(1): 39-47.
	Fan Jieru, Li Dongguang. Overview of MAV/UAV Collaborative Combat and Its Key Technologies[J]. Unmanned Systems Technology, 2019, 2(1): 39-47.
[2]	王灿, 郭齐胜, 穆歌, 等. 军事领域体系结构研究综述[J]. 火力与指挥控制, 2023, 48(2): 1-11, 18.
	Wang Can, Guo Qisheng, Mu Ge, et al. Review of System of Systems Architecture Research in Military Domain[J]. Fire Control & Command Control, 2023, 48(2): 1-11, 18.
[3]	吕昭, 邓锦洲, 梁东晨. 作战体系的结构建模与应用研究[J]. 战术导弹技术, 2021(3): 109-118.
	Zhao Lü, Deng Jinzhou, Liang Dongchen. Study of Operation SoS Architecture Modeling and Application[J]. Tactical Missile Technology, 2021(3): 109-118.
[4]	Pandey Mohinder. A Generic Hierarchical System of Systems Engineering Approach for Model Based System Engineering Projects[J]. Incose International Symposium, 2022, 32(1): 737-766.
[5]	杨亚杰, 张绍杰, 刘鑫海, 等. 基于MBSE的民机综合监视系统设计[J]. 飞机设计, 2024, 44(6): 66-73.
	Yang Yajie, Zhang Shaojie, Liu Xinhai, et al. Design of Civil Aircraft Integrated Surveillance System Using Model-based System Engineering[J]. Aircraft Design, 2024, 44(6): 66-73.
[6]	姬晓慧, 陈国定. MBSE方法论实施方法研究[J]. 中国新技术新产品, 2022(4): 33-38.
[7]	杨静, 梁彦刚, 黎克波, 等. 基于SysML的无人机集群协同作战体系结构设计[C]∥第五届体系工程学术会议论文集——数智时代的体系工程. 长沙: 国防科技大学系统工程学院, 2023: 49-55.
	Yang Jing, Liang Yangang, Li Kebo, et al. Architecture Design of UAV Cluster Cooperative Operations Based on SysML[C]∥Proceedings of the 5th Academic Conference on Systems Engineering-Systems Engineering in the Digital Age. Changsha: School of Systems Engineering, National University of Defense Technology, 2023: 49-55.
[8]	张天目, 安晓强, 孙志彬, 等. 基于SysML的系统架构设计与建模方法[J]. 飞机设计, 2023, 43(4): 46-51.
	Zhang Tianmu, An Xiaoqiang, Sun Zhibin, et al. The System Architecture Design and Modeling Method Based on SysML[J]. Aircraft Design, 2023, 43(4): 46-51.
[9]	陆志沣, 洪泽华, 张励, 等. 武器装备体系对抗仿真技术研究[J]. 上海航天, 2019, 36(4): 42-50.
	Lu Zhifeng, Hong Zehua, Zhang Li, et al. Review on the Simulation Technology of Weapon System-of-Systems Encounter[J]. Aerospace Shanghai, 2019, 36(4): 42-50.
[10]	黄晨, 于倩, 左万娟, 等. 基于SysML模型的需求建模及测试方法[J]. 测试技术学报, 2021, 35(2): 93-99.
	Huang Chen, Yu Qian, Zuo Wanjuan, et al. Requirement Modeling and Testing Method Based on SysML Model[J]. Journal of Test and Measurement Technology, 2021, 35(2): 93-99.
[11]	Mhenni Faïda, Choley Jean-Yves, Penas Olivia, et al. A SysML-based Methodology for Mechatronic Systems Architectural Design[J]. Advanced Engineering Informatics, 2014, 28(3): 218-231.
[12]	张同, 陈聪, 惠慧. 基于DDS的分布式仿真平台接口设计[J]. 机电工程技术, 2024, 53(6): 156-161.
	Zhang Tong, Chen Cong, Hui Hui. Interface Design of Distributed Simulation Platform Based on DDS[J]. Mechanical & Electrical Engineering Technology, 2024, 53(6): 156-161.
[13]	李大超, 孙帷胜, 张志涛. DDS发布订阅通信节点自动发现机制与改进[J]. 航空电子技术, 2023, 54(1): 20-28.
	Li Dachao, Sun Weisheng, Zhang Zhitao. Research on DDS Publish-subscribe Communication Behavior and Improvement[J]. Avionics Technology, 2023, 54(1): 20-28.
[14]	黄乃娇. 基于DDS的无人系统空地协同的通信及服务质量研究[D]. 南京: 南京邮电大学, 2022.
	Huang Naijiao. Research on Communication and Service Quality of Unmanned System Air-ground Cooperation Based on DDS[D]. Nanjing: Nanjing University of Posts and Telecommunications, 2022.