logo

SCIENTIA SINICA Informationis, Volume 50 , Issue 11 : 1665(2020) https://doi.org/10.1360/SSI-2020-0119

Solution study for building autonomous adaptive command and control systems

More info
  • ReceivedMay 5, 2020
  • AcceptedOct 17, 2020
  • PublishedNov 9, 2020

Abstract


Funded by

国家重点研发计划(2017YFB1001800)


References

[1] Zhang W M, Huang S P, Huang J C, et al. Analysis on multi-domain operation and its command and control problems. Command Inform Syst Technol, 2020, 11: 1--6. Google Scholar

[2] Jiang X Y, Deng K B. Command information system requirements for future informatization operation. Command Inform Syst Technol, 2016, 7: 1--5. Google Scholar

[3] Fan J X, Chen J H. New concepts of future air warfare and the challenges for its realization. Aero Weaponry, 2020, 27: 15--24. Google Scholar

[4] Li L, Jiang Q, Wang T. Analysis of mosaic warfare in the United States. Tactical Missile Technol, 2019, 6: 108--114. Google Scholar

[5] Shi D F, Cai J, Huang S H, et al. Operational concept and enlightenment of United States Air Force “Combat Cloud". Command Inform Syst Technol, 2017, 8: 27--32. Google Scholar

[6] Clark B, Patt D, Schramm H. Mosaic Warfare: Exploiting Artificial Intelligence and Autonomous Systems to Implement Decision-Centric Operations. Washington: CSBA, 2020. Google Scholar

[7] Alberts D S, Garstka J J, Hayes R E, et al. Understanding Information Age Warfare. Washington: CCRP, 2001. Google Scholar

[8] Lan Y S. Understanding the network-centered command information system. Command Inform Syst Technol, 2010, 1: 1--4. Google Scholar

[9] Neema S, Parikh R, Jagannathan S. Building Resource Adaptive Software Systems. IEEE Softw, 2019, 36: 103-109 CrossRef Google Scholar

[10] Matthews G, Reinerman-Jones L E, Barber D J, et al. Resilient autonomous systems: challenges and solutions. In: Proceedings of Resilience Week (RWS), Chicago, 2016. 208--213. Google Scholar

[11] DARPA. Intent-defined adaptive software (IDAS). https://www.darpa.mil/program/intent-defined-adaptive-software. Google Scholar

[12] Yang F Q, Lv J, Mei H. An architecture centric approach to internetware. Sci China Ser F-Inf Sci, 2008, 38: 818-828. Google Scholar

[13] Lv J, Ma X X, Tao X P, et al. A survey of internetware: research and progress. Sci China Ser F-Inf Sci, 2006, 36: 1037--1080. Google Scholar

[14] Mei H, Lv J. Internetware: A New Software Paradigm for Internet Computing. Berlin: Springer, 2016. Google Scholar

[15] Wu G Q. A Dynamic QoS Assessment Approach for Internetware with Uncertainty Reasoning. J Software, 2008, 19: 1173-1185 CrossRef Google Scholar

[16] Ma X X, Liu X Z, Xie B, et al. Software development methods: review and outlook. J Softw, 2019, 30: 3--21. Google Scholar

[17] Li W, Wang H M, Wu W J. 复杂软件系统的成长性构造与适应性演化. Sci Sin-Inf, 2014, 44: 743-761 CrossRef Google Scholar

[18] Wang H M, Yin G, Xie B, et al. Research on network-based large-scale collaborative development and evolution of trustworthy software. Sci Sin Inform, 2014, 44: 1--19. Google Scholar

[19] Wang H M, Shi P C, Ding B. Chin J Comput, 2011, 34: 318-328 CrossRef Google Scholar

[20] Lan Y S, Zhou G X, W H, et al. Construction mechanism and implementation of resilient command information systems. J Command Control, 2015, 1: 284--286. Google Scholar

[21] Fei A G. Analysis on related issues about resilient command and control system design. Command Inform Syst Technol, 2017, 8: 1--4. Google Scholar

[22] Zhao X, Yu J, Liu X, et al. Core-mission supported architecture for resilient information service cloud environment. Command Inform Syst Technol, 2018, 9: 19--24. Google Scholar

[23] Ding F, Zhou F, Zhao X, et al. Evaluating the capability for resilient information service cloud environment under cyber attack condition. Syst Eng Electron, 2018, 40: 2722--2728. Google Scholar