Journal of Systems Engineering and Electronics ›› 2020, Vol. 31 ›› Issue (6): 1216-1229.doi: 10.23919/JSEE.2020.000094
• SYSTEMS ENGINEERING • Previous Articles Next Articles
Jiuyao JIANG(), Jichao LI*(), Kewei YANG()
|1||YANG J J, LONG G Z, ZHAO B J. Demonstration of weaponry development, Beijing: National Defense Industry Press. 2009.|
|2||CHEN W Y, ZHANG Z B, YANG K W Contribution rate evaluation for requirement demonstration of a new weapon equipment system. Systems Engineering and Electronics, 2019, 41 (8): 1795- 1801.|
KERR C, JARADAT R, HOSSAIN N U I Battlefield mapping by an unmanned aerial vehicle swarm: applied systems engineering processes and architectural considerations from system of systems. IEEE Access, 2020, 8, 20892- 20903.
CLINIC S, LEE M A study on the military organization task analysis method. Journal of the Korea Data and Information Science Society, 2019, 30 (1): 139- 157.
ZACHMAN J A A framework for information systems architecture. IBM Systems Journal, 1987, 26 (3): 276- 292.
MO H, DENG Y Identifying node importance based on evidence theory in complex networks. Physica A: Statistical Mechanics and its Applications, 2019, 529, 121538.
|7||DENG Q, XUE Q, CHEN L, et al Research of anti-destroy optimizing based on operation system complex network. Computer Simulation, 2019, 36 (6): 1- 4.|
|8||CHEN H, HUANG J, GONG J, et al Operational capability evaluation based on improved generalized grey incidence analysis model. Journal of Physics: Conference Series, 2019, 1168 (3): 032048.|
|9||WANG Z, LIU S, FANG Z Research on SoS-GERT network model for equipment system of systems contribution evaluation based on joint operation. IEEE Systems Journal, 2019, 1- 9.|
|10||YOU Y Q, SUN J B, JIANG J, et al Belief-rule-base model with attribute reliability for multiple attribute decision making. Proc. of the IEEE Chinese Control and Decision Conference, 2019, 4770- 4775.|
MARIANI M S, REN Z M, BASCOMPTE J, et al Nestedness in complex networks: observation, emergence, and implications. Physics Reports, 2019, 813, 1- 90.
ALETA A, MORENO Y Multilayer networks in a nutshell. Annual Review of Condensed Matter Physics, 2019, 10, 45- 62.
|13||YANG K W, YANG Z W, TAN Y J, et al Review of the evaluation methods of equipment system of systems facing the contribution rate. Systems Engineering and Electronics, 2019, 41 (2): 311- 321.|
|14||TAN Y J, ZHANG X K, YANG K W Networking description and modeling method of weapon equipment system. Journal of Systems Management, 2012, 21 (6): 781- 786.|
|15||ZHANG Y, ZHANG M Z, YANG J Y, et al Modeling method for weapon equipment system of systems based on OODA loop. Journal of System Simulation, 2013, 25 (S1): 6- 11.|
|16||TAN S Y, DENG Y, WU J Cost-effectiveness analysis of structural robustness in complex networks. Proc. of the IEEE International Symposium on Circuits and Systems, 2019, 1- 5.|
|17||WANG Y M, CHEN S, CHEN B, et al Measure of invulnerability for command and control network based on combat link efficiency. Journal of Command and Control, 2017, 39 (8): 1782- 1787.|
|18||LI J C, WU J, TAN Y J, et al Robustness of combat networks based on directed natural connectivity. Complex System and Complexity Science, 2015, 12 (4): 25- 31.|
CIMINI G, SQUARTINI T, SARACCO F, et al The statistical physics of real-world networks. Nature Reviews Physics, 2019, 1 (1): 58- 71.
|20||ZHANG W Z, JIA J Analysis of network's invulnerability based on community connectivity. Military Operations Research and Systems Engineering, 2019, 33 (4): 75- 80.|
DONG G G, FAN J, SHEKHTMAN L M, et al Resilience of networks with community structure behaves as if under an external field. Proceedings of the National Academy of Sciences, 2018, 115 (27): 6911- 6915.
ZHANG L M, ZENG G W, LI D Q, et al Scale-free resilience of real traffic jams. Proceedings of the National Academy of Sciences, 2019, 116 (18): 8673- 8678.
WU J, TAN S Y, LIU Z, et al Enhancing structural robustness of scale-free networks by information disturbance. Scientific Reports, 2017, 7 (1): 7559.
|24||TAN G X. Research on topology layer survivability measurement of complex networks. Nanjing, China: Nanjing University of Science and Technology, 2011.|
|25||ZHAO D L, TAN Y J, LI J C, et al Research on structural robustness of weapon system-of-systems based on heterogeneous network. Systems Engineering—Theory & Practice, 2019, 39 (12): 3197- 3207.|
|26||TAN Y J, LV X, WU J, et al Thoughts on several problems in the study of complex network invulnerability. Systems Engineering — Theory & Practice, 2008, 28 (S1): 116- 120.|
|27||HE S, YANG K W, LIANG J Research on contribution of single equipment to weapon system-of-systems based on network invulnerability. Fire Control & Command Control, 2017, 42 (8): 87- 96.|
|28||WANG H Y, WU W, WEI Y Y Weapon system-of-systems invulnerability analysis based on super network model. Systems Engineering and Electronics, 2017, 39 (8): 87- 96.|
BUEDE D M, BRESNICK T A Applications of decision analysis to the military systems acquisition process. Interfaces, 1992, 22 (6): 110- 125.
DOU Y J, ZHAO D L, XIA B Y, et al System portfolio selection for large-scale complex systems construction. IEEE Systems Journal, 2019, 13 (4): 3627- 3638.
LI J C, GE B F, ZHAO D L, et al Meta-path-based weapon-target recommendation in heterogeneous combat network. IEEE Systems Journal, 2019, 13 (4): 4433- 4441.
|32||DOU Y J, XV X Q, ZHOU Z X, et al Analysis of system portfolio selection problem and typical military application. Systems Engineering and Electronics, 2019, 41 (12): 2754- 2762.|
DOU Y J, ZHOU Z X, ZHAO D L, et al Weapons system portfolio selection based on the contribution rate evaluation of system of systems. Journal of Systems Engineering and Electronics, 2019, 30 (5): 905- 919.
DOU Y J, ZHOU Z X, XU X Q, et al System portfolio selection with decision-making preference baseline value for system of systems construction. Expert Systems with Applications, 2019, 123, 345- 356.
|35||ZHANG X, JIANG J, GE B, et al Group decision making for weapon systems selection with VIKOR based on consistency analysis. Proc. of the IEEE Annual Systems Conference, 2016, 1- 6.|
LI J C, GE B F, JIANG J, et al High-end weapon equipment portfolio selection based on a heterogeneous network model. Journal of Global Optimization, 2020, 78, 743- 761.
|37||ZHOU Z, DOU Y J, XIA B Y, et al Weapon systems portfolio selection based on fuzzy clustering analysis. Proc. of the 3rd IEEE International Conference on Control Science and Systems Engineering, 2017, 702- 705.|
|38||LIU L, WANG T, CUI J A glimpse into the development of U.S. army’s concept of multi-domain operations in recent years. Aerospace Electronic Warfare, 2019, 35 (6): 42- 46.|
|39||LIU S Y, LI B An analysis of the concept of “multi-domain battle” of the US army. National Defense Technology, 2018, 39 (6): 108- 112.|
|40||BOYD J R The essence of winning and losing. Unpublished Lecture Notes, 1996, 12 (23): 123- 125.|
|41||CARES J. Distributed networked operations: the foundations of network centric warfare. New York: IUniverse, 2006.|
|42||ZHANG X K. Modeling and optimization of armament system of systems development based on operation loop. Changsha, China: National University of Defense Technology, 2016. (in Chinese)|
|43||LI J C. Research on equipment contribution of weapon system-of-systems based on combat network model. Changsha, China: National University of Defense Technology, 2015. (in Chinese)|
|44||LI J C, JIANG J, YANG K W, et al Research on functional robustness of heterogeneous combat networks. IEEE Systems Journal, 2018, 13 (2): 1487- 1495.|
|||Ziyi CHEN, Yajie DOU, Xiangqian XU, Yuejin TAN. Service-oriented weapon systems of system portfolio selection method [J]. Journal of Systems Engineering and Electronics, 2020, 31(3): 551-566.|