基于DoDAF的航空装备智能保障系统体系结构建模

doi:10.12305/j.issn.1001-506X.2024.02.27

Abstract

Abstract:

The architecture modeling of support system is an important foundation for the development and construction of a new generation of aviation equipment intelligent support system. The aviation equipment support system involves many support elements and complex cross-linking relationships, it is necessary to carry out top-level design from the perspective of system engineering, and use a unified structural framework to model and characterize its architecture. The Departmeant of Defense Architecture Framework (DoDAF) architecture framework is introduced, and the architecture development sequence based on "concept-task-capability" is proposed. The view models of capabilities, support activities, information interaction and organization relationship of each support element of the aviation equipment intelligent support system are constructed, and the corresponding relationship between "capability layer-demand layer-technology layer" is obtained. This method can comprehensively describe the architecture of aviation equipment intelligent support system, improve the interoperability among different support elements, and translate it into specific design requirements, which can provide support for the development of aviation equipment intelligent support system.

Key words: aviation equipment, intelligent support system, Department of Defense Architecture Framework (DoDAF), model-based systems engineering (MBSE)

CLC Number:

E926

Xuewen MIAO, Xiaoxiong DONG, Zhengwen QIAN, Yang HU, Mudong LI. Architecture modeling of aviation equipment intelligent support system based on DoDAF[J]. Systems Engineering and Electronics, 2024, 46(2): 640-648.

Figures/Tables 9

Table 1

Fig.1

Fig.2

Fig.3

Fig.4

Fig.5

Fig.6

Fig.7

Fig.8

References 30

1	GJB451A-2005. 可靠性维修性保障性术语[S]. 北京: 中国人民解放军总装备部.
	GJB451A-2005. Reliability maintainability and supportability terms[S]. Beijing: General Armament Department of the Chinese People's Liberation Army.
2	DURMAZ M . Defense technology development: does every country need an organization like DARPA?[J]. Innovation, 2016, 18 (1): 2- 12. doi: 10.1080/14479338.2016.1163235
3	ZHOU J , LI P G , ZHOU Y H . Toward new-generation intelligent manufacturing[J]. Engineering, 2018, 4 (1): 11- 20. doi: 10.1016/j.eng.2018.01.002
4	WOLFE F . F-35 ALIS to ODIN transition contract expected early next year[J]. Defense Daily, 2021, 10 (7): 1- 2.
5	宁莹, 季自力. 人工智能应用对装备保障的影响及对策[J]. 科技资讯, 2022, 20 (17): 33- 35.
	NING Y , JI Z L . Influence of AI application on equipment support and countermeasures[J]. Science & Technology Information, 2022, 20 (17): 33- 35.
6	苗学问, 胡杨, 钱征文, 等. 航空装备智能保障系统论证研究[J]. 测控技术, 2020, 39 (12): 22- 25.
	MIAO X W , HU Y , QIAN Z W , et al. Argumentation research of aviation equipment intelligent support system[J]. Observation and Control Technology, 2020, 39 (12): 22- 25.
7	方伟光, 聂兆伟, 刘宸宁, 等. 数字孪生驱动的武器装备智能保障技术研究[J]. 系统工程与电子技术, 2023, 45 (4): 1247- 1260.
	FANG W G , NIE Z W , LIU C N , et al. Research on digital twin driven intelligent weaponry support technology[J]. Systems Engineering and Electronics, 2023, 45 (4): 1247- 1260.
8	周扬, 曾照洋, 周岩, 等. 航空装备智能保障系统研究[J]. 航空科学技术, 2020, 31 (12): 68- 72.
	ZHOU Y , ZENG Z Y , ZHOU Y , et al. Research on intelligent support system of aviation equipment[J]. Aeronautical Science & Technology, 2020, 31 (12): 68- 72.
9	崔广宇, 谢娜. 航空装备智能保障思考[J]. 测控技术, 2020, 39 (12): 28- 33.
	CUI G Y , XIE N . Consideration of intelligent support for aviation equipment[J]. Measurement & Control Technology, 2020, 39 (12): 28- 33.
10	USA Department of Defense. Quadrennial defense review report[R]. Washington DC: Department of Defense, 2001.
11	GE B , HIPEL K W , FANG L , et al. An interactive portfolio decision analysis approach for system-of-systems architecting using the graph model for conflict resolution[J]. IEEE Trans.on Systems, Man, and Cybernetics: Systems, 2014, 44 (10): 1328- 1346. doi: 10.1109/TSMC.2014.2309321
12	KAUL A , WU B . A capabilities-based perspective on target selection in acquisitions[J]. Strategic Management Journal, 2016, 37 (7): 1220- 1239. doi: 10.1002/smj.2389
13	DEKKER A H . Applying social network analysis concepts to military C⁴ISR architecture[J]. Connections, 2002, 24 (3): 93- 103.
14	LI J F , SUN B C , DAI Z . Research on C⁴ISR requirement demonstrating method based on system configuration[J]. Journal of Physics: Conference Series, 2021, 1802 (4): 042084. doi: 10.1088/1742-6596/1802/4/042084
15	Department of Defense Architecture Framework Working Group. DoD architecture framework version 1.0[R]. Washington DC: Department of Defense, 2003.
16	Department of Defense Architecture Framework Working Group. Department of defence architecture framework version 2.0[R]. Washington DC: Department of Defense, 2009.
17	Department of Defense Architecture Framework Working Group. DoD architecture framework version 2.02. Changel volume: overview and concepts[R]. Washington DC: Department of Defense, 2015: 20-26.
18	Department of Defense Architecture Framework Working Group. Department of defense architecture framework vertion 2.02. Changel volume 2: arhitecture data and models[R]. Washington DC: Department of Defense, 2015.
19	Department of Defense Architecture Framework Working Group. Department of defense architecture framework vertion 2.02. Changel volume 3: DoDAF meta-model ontology foundation and physical exchange specification[R]. Washington DC: Department of Defense, 2015.
20	Department of Defense Architecture Framework Working Group. Department of defense architecture framework vertion 2.02. Changel volume 4: DoDAF journal[R]. Washington DC: Department o1 Defense, 2015.
21	HAO I J . Study on the DoDAF-based UUV formation system collaborative anti-submarine architecture modeling[J]. Journal of Engineering School, 2017, 32 (16): 947- 951.
22	STOEWER H , LIN C . Results from the panel on "MBSE transition towards the digital enterprise-where do go from here?"[J]. Insight, 2019, 22 (1): 51- 53. doi: 10.1002/inst.12239
23	HULDT T , STENIU I . State-of-practice survey of model-based systems engineering[J]. Systems Engineering, 2019, 22 (2): 134- 145. doi: 10.1002/sys.21466
24	KHARRAT M , PENAS O , PLATEAUX R , et al. Integration of electromagnetic constraint as of the conceptual design through an MBSE approach[J]. IEEE Systems Journal, 2020, 15 (1): 7- 44.
25	LIU W W, LIU F S, XU D, et al. Analysis of joint capabilities integration and development system of U.S. Army[C]//Proc. of the International Conference on Quality, 2012: 1355-1359.
26	SCHLOMER D E , CAMPBELL D G . Strategies to streamline the U.S. Army's acquisition approval process[J]. International Journal of Applied Management & Technology, 2018, 17 (1): 59- 67.
27	ZHANG Y W, CUI W X, LUO Y F. Military task completion evaluation method based on DoDAF model and improved FDNA[C]//Proc. of the 34th China Control and Decision Conference, 2022: 6.
28	YANG W J , HOU J F , LIU M F . Research on demand analysis method of military civilian integration medical equipment based on DoDAF[J]. Basic & Clinical Pharmacology & Toxicology, 2021, 12 (8): 17- 18.
29	AGHAMOHAMMADPOUR A , MAHDIPOUR E , ATTARZADEH I . Architecting threat hunting system based on the DoDAF framework[J]. The Journal of Supercomputing, 2022, 79 (4): 4215- 4242.
30	WANG C W . Study on vessel maintenance support system modelling based on DoDAF[J]. IOP Conference Series: Materials Science and Engineering, 2019, 692, 012051.

模型	名称	模型含义	描述角度	形式
AV-1	总体概要模型	智能保障系统总体描述	总体架构	文字型
AV-2	集成字典	智能保障系统名词解释和缩略语	总体架构	文字型
OV-1	顶层概念图	直观展现智能保障业务的顶层目标和基本运用方式	业务功能	图片型
OV-2	资源流描述	描述智能保障系统内部的信息交联关系, 重点表达保障节点间的互连关系, 即需求线	业务信息	图片型
OV-4	组织关系模型	描述各保障要素的组织指挥关系	组织结构	结构型
OV-5b	保障活动模型	描述静态的智能保障活动和信息流逻辑流程	业务功能	行为型
OV-6c	事件跟踪描述	描述动态的智能保障活动和信息逻辑流程, 并能推动相关模型/仿真模块的分项演算	业务过程	行为型
CV-1	能力愿景	智能保障能力的整体构想	总体能力	图片型
CV-2	能力分类模型	智能保障能力指标框架	指标框架	图片型

[1]	Mengru DONG, Guoxin WANG, Jinzhi LU, Junda MA, Yan YAN. Research on the development trend of MBSE based on WordCloud technology [J]. Systems Engineering and Electronics, 2024, 46(2): 534-548.
[2]	Jicheng WEI, Juan ZHANG, Wenya YANG, Lanling MA, Hang ZHANG. Design for integrated disposal system architecture of low-slow-small aerocraft based on DoDAF [J]. Systems Engineering and Electronics, 2024, 46(1): 162-172.
[3]	Ran HUANG, Qibo PENG, Xinfeng WU, Qing NI. Architecture modeling for manned lunar landing based on DoDAF [J]. Systems Engineering and Electronics, 2023, 45(7): 2131-2137.
[4]	Qibo PENG, Hailian ZHANG. Model-based requirements analysis method for manned space engineering [J]. Systems Engineering and Electronics, 2023, 45(11): 3532-3543.
[5]	Wenqing SHI, Haifeng WANG, Haixin CHEN. Fighter-drone teaming system requirements elicitation and verification [J]. Systems Engineering and Electronics, 2023, 45(1): 108-118.
[6]	Gang DING, Lin ZHANG, Lijie CUI, Liang ZHANG, Xinchun LI. Research on simulation evaluation method of aviation equipment unit maintenance and support [J]. Systems Engineering and Electronics, 2022, 44(4): 1246-1255.
[7]	Qiucen FAN, Wenhao BI, An ZHANG, Wenhao WANG. MBSE modeling method of civil aircraft altitude control system [J]. Systems Engineering and Electronics, 2022, 44(1): 164-171.
[8]	Hongchen JIAO, Yong LEI, Hongyu ZHANG, Guobin ZHANG, Yaodong WANG. Research on modeling and design method of spacecraft system based on MBSE [J]. Systems Engineering and Electronics, 2021, 43(9): 2516-2525.
[9]	Yunong WANG, Wenhao BI, An ZHANG, Chao ZHAN. DoDAF-based civil aircraft MBSE development method [J]. Systems Engineering and Electronics, 2021, 43(12): 3579-3585.
[10]	Wenhao WANG, Wenhao BI, An ZHANG, Qiucen FAN. Function modeling method of civil aircraft system based on MBSE [J]. Systems Engineering and Electronics, 2021, 43(10): 2884-2892.
[11]	Zhiwei MAO, Zhanwen QU, Tong ZHANG, Yi LU, Shan FU, Dan HUANG. Design of civil aircraft certification test flight scenario based on MBSE [J]. Systems Engineering and Electronics, 2020, 42(8): 1768-1775.
[12]	Xinyao WANG, Yunfeng CAO, Houjun SUN, Caise WEI, Jiang TAO. Modeling for cooperative combat system architecture of manned/unmanned aerial vehicle based on DoDAF [J]. Systems Engineering and Electronics, 2020, 42(10): 2265-2274.
[13]	REN Bingxuan, LU Yi, FU Shan, HUANG Dan. Identification and verification of civil aircraft functional requirements through MBSE [J]. Systems Engineering and Electronics, 2019, 41(9): 2016-2024.
[14]	LI Daxi, ZHANG Qiang, LI Xiaoxi, XU Yong, YANG Jianjun. Architecture modeling for equipment of airborne anti-missile based on DoDAF [J]. Systems Engineering and Electronics, 2017, 39(5): 1036-1041.
[15]	LI Zhi-huai, TAN Xian-si, WANG Hong, LI Gui-xiang. Data consistency verification of architecture based on DM2 [J]. Journal of Systems Engineering and Electronics, 2013, 35(2): 357-361.

Architecture modeling of aviation equipment intelligent support system based on DoDAF

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 9

References 30

Related Articles 15

Recommended Articles

Metrics

Comments