Enabling Technologies for Effective Deployment of Internet of Things (IoT) Systems A Communication Networking Perspective

Main Article Content

Jamil Y. Khan
Dong Chen
Oliver Hulin

Keywords

IoT

Abstract

The demand for IoT (Internet of Things) systems that encompass cloud computing, the multitude of low power sensing and data collection electronic devices and distributed communications architecture is increasing at an exponential pace. With increasing interests from different industrial, business and social groups, in the near future it will be necessary to support massive deployment of diverse IoT systems in different geographical areas. Large scale deployment of IoT systems will introduce challenging problems for the communication designers, as the networking is one of the key enabling technologies for the IoT systems. Major challenges include cost effective network architecture, support of large area of coverage and diverse QoS (Quality of Service) requirements, reliability, spectrum requirements, energy requirements, and many other related issues. The paper initially reviews different classes of IoT applications and their communication requirements. Following the review, different communications and networking technologies that can potentially support large scale deployment of IoT systems for different industrial, business and social applications are discussed. The paper then concentrates on wireless networking technologies for IoT systems with specific focus on deployment issues. The deployment discussion concentrates on different IoT systems QoS and networking requirements, cost, coverage area and energy supply requirements. We introduce a sustainable low cost heterogeneous network design using short range radio standards such as IEEE 802.15.4/Zigbee, IEEE 802.11/WLAN that can be used to develop a wide area networks to support large number of IoT devices for various applications. Finally the paper makes some general recommendations towards sustainable network design techniques for future IoT systems that can reduce the OPEX and CAPEX requirements.

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References

Akyildiz, I. F; Jornet, J. M. 2010. “The Internet of Nano-Things”, IEEE Wireless Communications, December 2010, pp. 58-63.
Atzori, L; Iera, A; Morabito, G. 2010. “The Internet of Things: A Survey”, Computer Networks, 54(2010), pp2787-2805.
Balasubramaniam, S; Kangasharju, J. 2013. “Realizing Internet of Nano Things: Challenges, Solutions and Applications”, IEEE Computer, February 2013, pp. 62-68.
Chen, D; Khan, J.Y; Brown, J. 2014. ‘An Area Packet Scheduler to Mitigate the Coexistence Issue in a WPAN/WLAN Based Heterogeneous Network’ submitted for review IEEE WCNC 2014, New Orleans, USA, 9-12 March, 2014.
Edson, A; Marques, L; dos Passos, D; Macedo, R; Dias, K; Nogueira, M. 2014. ‘Interoperability issues on heterogeneous wireless communication for smart cities’, Computer Communications, early access article, http://dx.doi.org/10.1016/j.comcom.2014.07.005
Euisin, L; Eun-Kyu, L; Gerala, M; Oh, S. Y. 2014, ‘Vehicular Cloud Networking: Architecture & Design Principles’, IEEE Communication Magazine, February 2014, 148-155.
Forbes. 2013. Forbes Magazine 1 July 2013. "How many things are currently connected to the internet of Things (IoT)?" Available at: http://www.forbes.com/sites/quora/2013/01/07/how-many-things-are-currently-connected-to-the-internet-of-things-iot/
Gartner. 2014. Media release. "Gartner says a Thirty-Fold increase in internet-connected physical devices by 2020 will significantly alter how the Supply Chain operates", March 24, 2014. Available at: http://www.gartner.com/newsroom/id/2688717
Iniewski, K. 2010. Convergence of Mobile & Stationary Next-Generation Networks, John Wiley & Sons.
Jin, J; Gubbi, J; Marusic, S; Palaniswami, M. 2014. “An information framework of creating Smart City through Internet of Things”, IEEE Journal of Internet of Things, DOI: 1109/JIOT.2013.2296516.
Kim, J; Lee, J; Kim, J; Yun, J. 2014. “M2M Service Platforms: Survey, Issues and Enabling Technologies”, IEEE Communications Surveys & Tutorials, vol: 16, no:1, First quarter, 2014, pp. 61-76.
M2M Satellite. 2013. "M2M Connectivity". Available at: http://www.m2mconnectivity.com.au/technologies/satellite
Miorandi, D; Sicari, S; De Pellegrini, F; Chlamtac, I. 2012. “Internet of things: Vision, applications and research challenges”, Ad hoc Networks, 10 (2012), pp. 1497-1516.
Mobile World. 2014. Mobile World Live 23 April 2014. "Huawei predicts 100B connected terminals by 2025". Available at: http://www.mobileworldlive.com/evolving-ict-market-create-infinite-opportunities-huawei
Ardis, Kristopher. 2013. "What’s to come: the IoT’s role in smart grid evolution". Smart Grid News. Dec 3, 2013. Available at: http://www.smartgridnews.com/artman/publish/End_Use_Smart_Homes/What-s-to-come-the-IoT-s-role-in-smart-grid-evolution-6200.html#.VDb_6_mSzh4
Sterling, L; Tareter, K. 2009. Intelligent Lifestyle Applications, MIT Press, 1st edition, 2009, 281-326.
Wu, X; Mincic, R; Al-Stouhi; Misener, J; Bai, S; Chan, W-H. 2014. ‘Car Talks to Phones: A DSRC Based Vehicle – Pedestrian Safety System’, Proc. Of the IEEE VTC Fall, 14-17 September, Vancouver, 2014.
Xu, L. D; He, W; Li, S. 2014. “Internet of Things in Industries: A Survey”, IEEE Trans. On Industrial Informatics, DOI:10.1109/TII.2014.2300753, early access article available from IEEE Explore, 2014.
Yuce M; Khan, J. Y. (editors). 2011. Wireless Body Area Networks: Technology, Implementation, and Applications, Pan Stanford Publishing, 2011.
Zaslavsky; A. 2013. “Internet of Things and Ubiquitous Sensing” Computing Now, September 2013,