通过分析自然界有机体系的有机特性集,将有机特性统一到体系生命力概念之下,提出了体系生命力理论,并结合人工智能及其相关的信息技术,提出了在工程技术体系中导向涌现出有机特性集的技术框架。体系生命力理论框架为提高体系的稳定性和可用性,提高体系的优化和选择进化能力提供了理论指导。
In this Paper, after systematic analysis on set of organic characteristics of organic system in nature, organic characteristics are integrated into the concept of systems of system vitality, and after combining artificial intelligence and its relevant information technology, a technical framework which makes the set of organic characteristics directed emergency in engineering technology SoS is proposed. The theoretical framework of SoS vitality provides theoretical guidance in improving system stability and availability, and promoting system ability on optimization and selective evolvability.
[1] Maier M W. Architecting principles for systems-of-systems[J]. Systems Engineering:The Journal of the International Council on Systems Engineering, 1998, 1(4):267-284.
[2] Maier M W. Research challenges for systems-of-systems[C]//2005 IEEE International Conference on Systems, Man and Cybernetics. Piscataway, NJ:IEEE, 2005, 4:3149-3154.
[3] DoD. Systems engineering guide for systems of systems[M]. Washington DC:Department of Defense Office of the Deputy Under Secretary of Defense, 2008.
[4] Haskins C, Forsberg K, Krueger M, et al. Systems engineering handbook[M]. San Diego, CA:INCOSE, 2006.
[5] Beer S. The viable system model:Its provenance, development, methodology and pathology[J]. Journal of the Operational Research Society, 1984, 35(1):7-25.
[6] Beer S. The heart of enterprise[M]. London:English Universities Press, 1959.
[7] Holling C S. Resilience and stability of ecological systems[J]. Annual Review of Ecology and Systematics, 1973, 4(1):1-23.
[8] Haimes Y Y. On the definition of resilience in systems[J]. Risk Analysis:An Official Publication of the Society for Risk Analysis, 2009, 29(4):498-501.
[9] Kahan J H, Allen A C, George J K. An operational framework for resilience[J]. Journal of Homeland Security & Emergency Management, 2009, 6(1):83, Doi:https://doi.org/10.2202/1547-7355.1675.
[10] Pecht M. Prognostics and health management of electronics[M]. New York:John Wiley & Sons Inc, 2008.
[11] Hess A, Fila L. The Joint strike fighter (JSF) PHM concept:Potential impact on aging aircraft problems[J]. IEEE Aerospace Conference Proceedings, 2002(6):3021-3026.
[12] Baheti R, Gill H. Cyber-physical systems[J]. The Impact of Control Technology, 2011, 12(1):161-166.
[13] Lee J, Qiu B, Wei M H. The New Generation Of Industrial Intelligence[M]. ShangHai:ShangHai Jiao Tong University Press, 2017.
[14] Lee J, Bagheri B, Kao H A. Recent advances and trends of cyber-physical systems and big data analytics in industrial informatics[C]. Proceeding of Int Conference on Industrial Informatics, 2014:1-6.
[15] Lee J, Bagheri B, Kao H A. A Cyber-Physical Systems architecture for Industry 4.0-manufacturing systems[J]. Manufacturing Letters, 2015, 3:18-23.
[16] Gill H. From vision to reality:Cyber-physical systems[Z]. HCSS National Workshop on New Research Directions for High Confidence Transportation CPS:Automotive, Aviation, and Rail, 2008.
[17] 中国信息物理系统发展论坛. 信息物理系统白皮书(2017)[M]. 北京:中国电子技术标准化研究院, 2017.
