Abstract
The Internet of Things (IoT) as an emerging network paradigm is bringing the next scientific and technological revolution for ubiquitous things’ interactions in cyber-physical-social spaces. The IoT influences the current science and technology system by enabling its relatively stable interrelations for an inevitable architecture reconfiguration. In this paper, we aim to explore an updated science and technology framework for the IoT. Particularly, a novel cyber-physical-social-thinking (CPST) space is established by involving an attractive concept of the Internet of Thinking (IoTk), and a science and technology framework is accordingly proposed referring to both scientific aspect (i.e., cyber-physical, social, and noetic sciences) and technological aspect (i.e., fundamental, physical, cyber, and social technologies). According to the perspective of the traditional Chinese culture, we explain the established science and technology framework, in which the “Five Elements” (i.e., wood, fire, earth, metal, and water) have common properties with the restructured cyber-physical science in the IoT. Moreover, we introduce a scenario of smart city to identify the technological aspect in the IoT, and discuss the key enabling technologies, including resource management, energy management, data management, session management, security and privacy, loop control, space-time consistency, nanotechnology, and quantum technology. It turns out that the established science and technology framework will launch an innovation for academia and industry communities.
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References
Atzori L, Iera A, Morabito G. The Internet of Things: a survey. Comput Netw, 2010, 54: 2787–2805
Liu Y, Wu J, Zhang Z, et al. Research achievements on the new generation internet architecture and protocols. Sci China Inf Sci, 2013, 56: 111101
Qian X. The behavior science system (in Chinese). Phil Res, 1985, 8: 11–15
Ning H, Wang Z. Future Internet of Things architecture: like mankind neural system or social organization framework? IEEE Commun Lett, 2011, 15: 461–463
Kortuem G, Bandara A K, Smith N, et al. Educating the Internet-of-Things generation. Computer, 2013, 46: 53–61
Gluhak A, Krco S, Nati M, et al. A survey on facilities for experimental Internet of Things research. IEEE Commun Mag, 2011, 49: 58–67
Hamblen J O, van Bekkum G M E. An embedded systems laboratory to support rapid prototy** of robotics and the Internet of Things. IEEE Trans Edu, 2013, 56: 121–128
Ning H, Hu S. Technology classification, industry, and education for future Internet of Things. Int J Commun Syst, 2012, 25: 1230–1241
He M. The evolution and future trends of technology and information sciences. In: Proceedings of WASE International Conference on Information Engineering (ICIE 2009), Taiyuan, 2009. 11–15
Chen C Y. Early Chinese Work in Natural Science: A Re-Examination of the Physics of Motion, Acoustics Astronomy and Scientific Thoughts. Hong Kong University Press, 1996
Ng S K, Wong L. Accomplishments and challenges in bioinformatics. IT Prof, 2004, 6: 44–50
Chamberlain T E. Behavioral science: a progress report. IEEE Aerosp Elect Syst Mag, 2000, 15: 3–6
Ning H. Unit and Ubiquitous Internet of Things. CRC Press, Taylor & France Group, 2013
Zhang Y, Qian Z, Zheng W. Employing intelligence in object-based storage devices to provide attribute-based file access. Sci China Inf Sci, 2013, 56: 032115
Melo G, Weikum G. Taxonomic data integration from multilingual wikipedia editions. Knowl Inf Syst, 2014, 39: 1–39
Evrim V, McLeod D. Context-based information analysis for the web environment. Knowl Inf Syst, 2014, 38: 109–140
Munasinghe K S, Kibria M R, Jamalipour A. Designing VoIP session management over interworked WLAN-3G networks. IEEE Wirel Commun, 2008, 15: 86–94
Chen L, Wu J, Zheng Z, et al. Modeling and exploiting tag relevance for web service mining. Knowl Inf Syst, 2014, 39: 153–173
Ning H, Liu H, Yang L T. Cyberentity security in the Internet of Things. Computer, 2013, 46: 46–53
Roman R, Najera P, Lopez J. Securing the Internet of Things. Computer, 2011, 44: 51–58
Basher A R M A, Fung B C M. Analyzing topics and authors in chat logs for crime investigation. Knowl Inf Syst, 2014, 39: 351–1381
Zhou T C, Lyu M R T, King I, et al. Learning to suggest questions in social media. Knowl Inf Syst, 2014: 1–28
Ning H, He W, Hu S, et al. Space-time registration for physical-cyber world map** in Internet of Things. In: Proceedings of IEEE 12th International Conference on Computer and Information Technology (CIT2012), Chengdu, 2012. 307–310
Balasubramaniam S, Kangasharju J. Realizing the Internet of Nano Things: challenges, solutions, and applications. Computer, 2013, 46: 62–68
Akyildiz I F, Jornet J M. The Internet of Nano-Things. IEEE Wirel Commun, 2010, 17: 58–63
Dowling P J, Miburn G J. Quantum technology: the second quantum revolution. Phil Trans Roy Soc A-Math Phy, 2003, 361: 1655–1674
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Ning, H., Liu, H. Cyber-physical-social-thinking space based science and technology framework for the Internet of Things. Sci. China Inf. Sci. 58, 1–19 (2015). https://doi.org/10.1007/s11432-014-5209-2
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DOI: https://doi.org/10.1007/s11432-014-5209-2