Systems Engineering and Electronics ›› 2021, Vol. 43 ›› Issue (9): 2516-2525.doi: 10.12305/j.issn.1001-506X.2021.09.19
• Systems Engineering • Previous Articles Next Articles
Hongchen JIAO*, Yong LEI, Hongyu ZHANG, Guobin ZHANG, Yaodong WANG
Received:
2020-12-19
Online:
2021-08-20
Published:
2021-08-26
Contact:
Hongchen JIAO
CLC Number:
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.
Table 1
Functions of spacecraft MBSE models"
模型名称 | 实现功能 |
需求模型 | (1) 梳理利益相关者, 完成顶层任务需求捕获, 建立设计约束; (2) 配合模型精化, 形成顶层需求至系统需求、系统需求至分系统需求、分系统需求至组件需求的分解; (3) 实现需求追溯分析与满足度分析。 |
功能模型 | (1) 描述航天器任务功能性目标, 基于用例展开功能黑盒分析; (2) 描述航天器与大系统的接口关系, 建立需求与功能的可追溯关系; (3) 对关键功能进一步展开, 明确各分系统组成及功能活动。 |
架构模型 | (1) 描述系统内各分系统间的接口关系, 建立系统上下文联系; (2) 描述分系统动态行为、各工作模式间的切换关系、时序关系等; (3) 明确航天器系统的逻辑组成, 以及各分系统之间的信息交换关系。 |
产品模型 | (1) 描述分系统各组件的配套信息; (2) 建立产品性能指标参数与分系统设计约束的可追溯关系; (3) 建立各组件在分系统中的逻辑组成关系。 |
工艺模型 | (1) 定义产品在软件、电气、机械等层面的实施方式; (2) 明确产品制造工艺以及性能指标参数。 |
验证模型 | (1) 利用上述模型已建立的参数可追溯关系, 分析验证航天器系统、分系统设计对功能需求、性能参数、设计约束等的满足度; (2) 辅助地面测试验证或虚拟/数字化测试验证; (3) 航天器在轨运行任务模式仿真和使用培训。 |
1 | 王建军, 向永清, 何正文. 基于数字孪生的航天器系统工程模型与实现[J]. 计算机集成制造系统, 2019, 25 (6): 1348- 1360. |
WANG J J , XIANG Y Q , HE Z W . Models and implementation of digital twin based spacecraft system engineering[J]. Computer Integrated Manufacturing Systems, 2019, 25 (6): 1348- 1360. | |
2 | 杨磊. 基于系统工程的多式联运绩效评价指标体系构建研究[J]. 铁道运输与经济, 2019, 41 (8): 64- 76. |
YANG L . A study on the construction of performance evaluation index system for multi-modal transportation based on system engineering[J]. Railway Transport and Economy, 2019, 41 (8): 64- 76. | |
3 | 马小俊, 彭焕春. 系统工程在大型客机运行支持系统研制中的应用综述[J]. 航空学报, 2019, 40 (1): 522376. |
MA X J , PENG H C . Review on development of commercial aircraft operation support system based on system engineering approach[J]. Acta Aeronautica et Astronautica Sinica, 2019, 40 (1): 522376. | |
4 | 王建军, 向永清, 赵宁. 基于精益协同思想的航天器系统工程研制管理平台[J]. 系统工程与电子技术, 2018, 40 (6): 1310- 1317. |
WANG J J , XIANG Y Q , ZHAO N . Spacecraft system engineering development management platform based on lean and collaborative concept[J]. Systems Engineering and Electronics, 2018, 40 (6): 1310- 1317. | |
5 | 张庆君, 刘杰. 航天器系统设计[M]. 北京: 北京理工大学出版社, 2018: 515- 523. |
ZHANG Q J , LIU J . Spacecraft system design[M]. Beijing: Beijing Institute of Technology Press, 2018: 515- 523. | |
6 | MICHAEL R, STEPHEN K. NASA systems engineering challenges[R]. Washington D. C. : NASA PM Challenge, 2011: 1-11. |
7 | CHARLES E D , DIMITRI M . A brief history of models and model based systems engineering and the case for relational orientation[J]. IEEE Systems Journal, 2009, 11, 6- 11. |
8 | NCOSE A . A word in motion: systems engineering vision 2025[M]. San Diego: International Council on Systems Engineering, 2014: 1- 30. |
9 | FISHER J . Model-based systems engineering: a new paradigm[J]. INCOSE Insight, 1998, 1 (3): 3- 4. |
10 |
THRAMBOULIDIS K . Model-integrated mechatronics-toward a new paradigm in the development of manufacturing systems[J]. IEEE Trans.on Industrial Informatics, 2005, 1 (1): 54- 61.
doi: 10.1109/TII.2005.844427 |
11 |
KERNSCHMIDT K , FELDMANN S , VOGELHEUSER B . A model-based framework for increasing the interdisciplinary design of mechatronic production systems[J]. Journal of Engineering Design, 2018, 29 (11): 617- 643.
doi: 10.1080/09544828.2018.1520205 |
12 |
CHEN B . Conceptual design synthesis based on series-parallel functional unit structure[J]. Journal of Engineering Design, 2018, 29 (3): 87- 130.
doi: 10.1080/09544828.2018.1448057 |
13 |
KURTOGLU T , SWANTNER A , CAMPBELL M I . Automating the conceptual design process: from black box to component selection[J]. Artificial Intelligence for Engineering Design, Analysis and Manufacturing, 2010, 24 (1): 49- 62.
doi: 10.1017/S0890060409990163 |
14 |
KOMOTO H , TOMIYAMA T . A framework for computer-aided conceptual design and its application to system architecting of mechatronics products[J]. Computer-Aided Design, 2012, 44 (10): 931- 946.
doi: 10.1016/j.cad.2012.02.004 |
15 |
WYATT D F , WYNN D C , JARRETT J P . Supporting product architecture design using computational design synthesis with network structure constraints[J]. Research in Engineering Design, 2012, 23 (1): 17- 52.
doi: 10.1007/s00163-011-0112-y |
16 | YUAN L , LIU Y , SUN Z , et al. A hybrid approach for the automation of functional decomposition in conceptual design[J]. Journal of Engineering Design, 2016, 27 (4): 333- 360. |
17 | NASA. Expanded guidance for NASA systems engineering: crosscutting topics, special topics, and appendices[M]. Washington D. C., NASA Headquarters, 2016: 94-110. |
18 | STEVEN W M. The challenge of managing enterprise-scale models in MBSE[R]. Bethesda: Lockheed Martin Corporation, 2015: 1-21. |
19 | HOFFMANN H P . MBSE with rational rhapsody and rational harmony for systems engineering[M]. New York: IBM Software Group, 2011: 19- 31. |
20 |
GRIEVES M , VICKERS J . Digital twin: mitigating unpredictable, undesirable emergent behavior in complex systems[J]. Transdisciplinary Perspectives on Complex Systems, 2017,
doi: 10.1007/978-3-319-38756-7-4 |
21 |
MILLER A M , ALVAREZ R , HARTMAN N . Towards an extended model-based definition for the digital twin[J]. Computer-Aided Design and Applications, 2018, 15 (6): 880- 891.
doi: 10.1080/16864360.2018.1462569 |
22 | SHAFTO M, CONROY M, DOYLE R, et al. Modeling, simulation, information technology & processing roadmap[R]. Washington D. C., USA: NASA Headquarters, 2010: 17-18. |
23 |
ZHENG C , HEHENBERGER P , LE D G J , et al. Multidisciplinary design methodology for mechatronic systems based on interface model[J]. Research in Engineering Design, 2017, 28, 333- 56.
doi: 10.1007/s00163-016-0243-2 |
24 |
CHEN R , LIU Y , FAN H , et al. An integrated approach for automated physical architecture generation and multi-criteria evaluation for complex product design[J]. Journal of Engineering Design, 2019, 30 (2-3): 63- 101.
doi: 10.1080/09544828.2018.1563287 |
25 |
YILDIRIM U , CAMPEAN F , WILLIAMS H . Function modeling using the system state flow diagram[J]. Artificial Intelligence for Engineering Design Analysis and Manufacturing, 2017, 31 (4): 413- 435.
doi: 10.1017/S0890060417000294 |
26 | KASLOW D, SOREMEKUN G, KIM H, et al. Integrated model-based systems engineering (MBSE) applied to the simulation of a cube sat mission[C]//Proc. of the IEEE Aerospace Conference, 2014. |
27 |
EDWARDS S , CILLI M , PETERSON T , et al. Whole systems trade analysis[J]. Incose International Symposium, 2015, 25 (1): 1133- 1146.
doi: 10.1002/j.2334-5837.2015.00120.x |
28 |
韩凤宇, 罗强, 张利强, 等. 基于协同设计中心的航天器系统工程实践[J]. 航天器工程, 2014, 23 (4): 105- 120.
doi: 10.3969/j.issn.1673-8748.2014.04.018 |
HAN F Y , LUO Q , ZHANG L Q , et al. Practice of spacecraft system engineering based on collaborative design center[J]. Spacecraft Engineering, 2014, 23 (4): 105- 120.
doi: 10.3969/j.issn.1673-8748.2014.04.018 |
|
29 |
韩凤宇, 林益明, 范海涛. 基于模型的系统工程在航天器研制中的研究与实践[J]. 航天器工程, 2014, 23 (3): 119- 125.
doi: 10.3969/j.issn.1673-8748.2014.03.021 |
HAN F Y , LIN Y M , FAN H T . Research and practice of model-based systems engineering in spacecraft development[J]. Spacecraft Engineering, 2014, 23 (3): 119- 125.
doi: 10.3969/j.issn.1673-8748.2014.03.021 |
|
30 | 王建军, 李延, 文明. 航天器系统设计的质量管理[J]. 质量与可靠性, 2020, (1): 10- 15. |
WANG J J , LI Y , WEN M . Quality management for spacecraft system design[J]. Quality and Reliability, 2020, (1): 10- 15. |
[1] | Jiang JIANG, Qiancheng JIN, Xueming XU, Shuai HOU, Jichao LI. Preliminary study on national defense science and technology system engineering in the era of intelligence [J]. Systems Engineering and Electronics, 2022, 44(6): 1880-1888. |
[2] | Wanbin LIAO, Yunfeng CAO, Xinyao WANG. DSL building for requirement analysis of complex system [J]. Systems Engineering and Electronics, 2022, 44(11): 3443-3454. |
[3] | 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. |
[4] | Delin LI, Wenhao BI, An ZHANG, Qiucen FAN. MBSE-based process management in the development of civil aircraft [J]. Systems Engineering and Electronics, 2021, 43(8): 2209-2220. |
[5] | Bing HUA, Yingying LIANG, Rui NI. Spacecraft integrated attitude determination method based on improved factor graph model [J]. Systems Engineering and Electronics, 2021, 43(8): 2273-2281. |
[6] | 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. |
[7] | Wenwen KANG, Haomin LI. Multi-view representation method of aircraft system architecture based on model [J]. Systems Engineering and Electronics, 2021, 43(11): 3266-3277. |
[8] | 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. |
[9] | 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. |
[10] | 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. |
[11] | FU Jiangliang, GAN Qingbo, ZHANG Yang, ZHAO Kexin, YUAN Hong. NTSM based kinematically coupled motion control for spacecraft’s feature points staring and tracking [J]. Systems Engineering and Electronics, 2019, 41(7): 1623-1632. |
[12] | DONG Chaoyang, MA Mingyu, WANG Qing, ZHOU Min. Attitude cooperative control of multiple spacecraft on SO(3) with communication time-delay [J]. Systems Engineering and Electronics, 2018, 40(9): 2032-2039. |
[13] | WANG Jianjun, XIANG Yongqing, ZHAO Ning. Spacecraft system engineering development management platform based on lean and collaborative concept [J]. Systems Engineering and Electronics, 2018, 40(6): 1310-1317. |
[14] | JIN Jian, CHEN Bohan. Analysis on control strategies of CO2 partial pressure of manned spacecraft assemble with multi-cabins [J]. Systems Engineering and Electronics, 2018, 40(6): 1351-1357. |
[15] | LI Xing-qian, WEI Chuan-feng, ZHANG Wei, XIA Qiao-li, LI Tao. On-orbit maintainability design system for manned spacecraft [J]. Systems Engineering and Electronics, 2016, 38(1): 84-89. |
Viewed | ||||||
Full text |
|
|||||
Abstract |
|
|||||