Abstract
When the Future Internet is defined as a dynamic global network infrastructure, the Internet of Things (IoT), an integrated part of it, is viewed as one of the most important technologies. Distinct from former definition and applications of IoT and the IoT based on Radio Frequency IDentification (RFID), the current IoT means the interconnection of devices and appliances via the Internet. However, because the development of the IoT technologies varies, there is neither an unified standard nor a standardized interoperability to provide an unified network software architecture for the IoT. In this paper, we propose a method for integrating the data detected by sensors in the IoT-IMS communication platform with specifications, including Zigbee, Wireless Sensor Network (WSN), RFID and IEEE 1451, and converting the data to Sensor Be One Code (SBO Code), a coding format that supports all kinds of sensors. Through this system, the data gathered by different sensors can be unified to meet the IoT requirement.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Hwang J, Kim N, Kang S, Koh J (2008) A framework for IMS interworking networks with quality of service guarantee. In: The 7th international conference on networking 2008, ICN 2008, pp 454–459, 13–18 Apr 2008
Epcglogal Tag Data Standard v. 1.5 http://www.epcglobalinc.org/standards/tds/tds_1_5-standard-20100818.pdf
Zhang DY, Zhu YL, Chen HN (2008) An algorithm for deployment of RFID readers in EPC network. In: The 4th international conference on wireless communications, networking and mobile computing 2008, WiCOM ’08, pp 1–4, 12–14 Oct 2008
Lee SD, Shin MK, Kim HJ (2007) EPC vs. IPv6 mapping mechanism. In: The 9th international conference on advanced communication technology, pp 1243–1245, 12–14 Feb 2007
Gao J, Liu F, Ning H, Wang B (2007) RFID coding, name and information service for internet of things. In: IET conference on wireless mobile and sensor networks 2007, (CCWMSN07), pp 36–39, 12–14 Dec 2007
Chang YC, Chen JL, Lin YS, Wang SM (2008) RFIPv6: a novel IPv6-EPC bridge mechanism. In: international conference on consumer electronics 2008, ICCE 2008. Digest of technical papers, pp 1–2, 9–13 Jan 2008
Thiesse F, Floerkemeier C, Harrison M, Michahelles F, Roduner C (2009) Technology, standards, and real-world deployments of the EPC Network. Internet computing, IEEE, pp 36–43, Mar–Apr 2009
Sanchez Lopez T, Kim D (2007) A context middleware based on sensor and RFID information. In: The 5th annual IEEE international conference on pervasive computing and communications workshops 2007, PerCom Workshops ‘07, pp 331–336, 19–23 Mar 2007
Huifang Deng, Haiyan Kang (2010) Research on high performance RFID code resolving technology. In: The 3rd international symposium on intelligent information technology and security informatics (IITSI) 2010, pp 677–681, 2–4 Apr 2010
Chalasani S, Boppana R (2007) Data architectures for RFID transactions. Industrial informatics, IEEE transactions, pp 246–257, Aug 2007
Pathak R, Joshi S (2009) Recent trends in RFID and a java based software framework for its integration in mobile phones. In: The first Asian himalayas international conference internet 2009, AH-ICI 2009, pp 1–5, 3–5 Nov 2009
Choi YS, Jeon YJ, Park SH (2010) A study on sensor nodes attestation protocol in a Wireless Sensor Network. In: The 12th international conference on advanced communication technology (ICACT) 2010, vol 1, pp 574–579
Yueqing R, Lixin X (2010) A study on topological characteristics of wireless sensor network based on complex network. In: The international conference on computer application and system modeling (ICCASM) 2010, vol 15, pp 486–489
Ilyas MU, Radha H (2006) End-to-end channel capacity of a wireless sensor network under reachback. In: The 40th annual conference on information sciences and systems 2006, pp 1713–1718
Choi SH, Kim BK, Park J, Kang CH, Eom DS (2004) An implementation of wireless sensor network. IEEE Trans Consum Electron 50(1):236–244
Acknowledgments
This study was supported by the National Science Council, Taiwan, under grant No. NSC 101-2219-E-197-003.
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2014 Springer Science+Business Media Dordrecht
About this paper
Cite this paper
Wu, TY., Liou, WK. (2014). Data Sensing and Communication Technology for the IoT-IMS Platform. In: Huang, YM., Chao, HC., Deng, DJ., Park, J. (eds) Advanced Technologies, Embedded and Multimedia for Human-centric Computing. Lecture Notes in Electrical Engineering, vol 260. Springer, Dordrecht. https://doi.org/10.1007/978-94-007-7262-5_133
Download citation
DOI: https://doi.org/10.1007/978-94-007-7262-5_133
Published:
Publisher Name: Springer, Dordrecht
Print ISBN: 978-94-007-7261-8
Online ISBN: 978-94-007-7262-5
eBook Packages: EngineeringEngineering (R0)