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Seamless Interworking Architecture for WBAN in Heterogeneous Wireless Networks with QoS Guarantees

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Abstract

The IEEE 802.15.6 standard is a communication standard optimized for low-power and short-range in-body/on-body nodes to serve a variety of medical, consumer electronics and entertainment applications. Providing high mobility with guaranteed Quality of Service (QoS) to a WBAN user in heterogeneous wireless networks is a challenging task. A WBAN uses a Personal Digital Assistant (PDA) to gather data from body sensors and forwards it to a remote server through wide range wireless networks. In this paper, we present a coexistence study of WBAN with Wireless Local Area Networks (WLAN) and Wireless Wide Area Networks (WWANs). The main issue is interworking of WBAN in heterogenous wireless networks including seamless handover, QoS, emergency services, cooperation and security. We propose a Seamless Interworking Architecture (SIA) for WBAN in heterogenous wireless networks based on a cost function. The cost function is based on power consumption and data throughput costs. Our simulation results show that the proposed scheme outperforms typical approaches in terms of throughput, delay and packet loss rate.

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References

  1. Khan, P., Hussain, A., and Kwak, K. S., Medical application of wireless sensor networks. International Journal of Digital Content Technology and its Applications. 3(3):2009. doi:10.4156/jdcta.vol3.issue3.23.

  2. Varshney, U., Pervasive healthcare and wireless health monitoring. Mobile Network Appl 12:113–127, 2007.

    Article  Google Scholar 

  3. Hongliang, R., Meng, M. Q.-H., and Chen, X., Physiological information acquisition through wireless biomedical sensor networks. In IEEE international Conference on information Acquisition, 2005, pp. 483–488.

  4. Ullah, S., Higgins, H., Braem, B., Latre, B., Blondia, C., Moerman, I.-G., Saleem, S., Rahman, Z., and Kwak, K. S., A comprehensive survey of wireless body area networks: On PHY, MAC, and network layers solutions. J Med Syst. In Press, doi:10.1007/s10916-010-9571-3.

  5. http://www.ieee802.org/15/pub/TG6.html, May 14, 2009.

  6. Zahran, A. H., and Liang, B., Performance evaluation framework for vertical handoff algorithms in heterogeneous networks, communications. In: IEEE International Conference. 1:173–178, 2005.

  7. Chen, H. P., and Hsu, W. P., Adapted queuing priority algorithm for soft handoff in mobile communication networks. In: International Symposium on Communications and Information Technologies, 2006, pp. 667–673.

  8. Fotouhi, H., Alves, M., Koubaa, A., and Baccour, N., On a reliable handoff procedure for supporting mobility in wireless sensor networks. The 9th RTN’2010 in conjunction with the 22nd ECRTS 2010, Brussels, Belgium, July 6–9, 2010, HURRAY-TR-100802.

  9. Bellavista, P., Corradi, A., and Giannelli, C., Adaptive buffering based on handoff prediction for wireless internet continuous services, Int. Conf. High Performance Computing and Communications (HPCC), LNCS 3726, pp. 1021–1032, 2005.

  10. Venkatachalaiah, S., Harris, R. J., and Murphy, J., Improving handoff in wireless networks using Grey and particle swarm optimisation. in CCCT. 5:368–373, 2004.

  11. Zhang, W., Handover decision using fuzzy MADM in heterogeneous networks. in Proc. of IEEE WCNC’04, Atlanta, GA, March 2004.

  12. Park, J.-T., Nah, J.-W., Kim, S. W., Chun, S. M., Wang, S., and Seo, S. H., Context-aware handover with power efficiency for u-healthcare service in WLAN. 2009 International Conference on New Trends in Information and Service Science. doi:10.1109/NISS.2009.256.

  13. Eshanta, O. M., Ismail, M., Jumari, K., and Yahaya, P., VHO strategy for QoS-provisioning in the WiMAX/WLAN interworking system. J Appl Sci. 2009 Malaysia, ISSN 1996–3343.

  14. Nie, J., He, X., Zhou, Z., and Zhao, C., Communication with bandwidth optimization in IEEE 802.16 and IEEE 802.11 hybrid networks. IEEE International Symposium on Communications and Information Technology, 2005. ISCIT 2005. Volume 1, 12–14 Oct. 2005, pp. 27–30.

  15. Dai, Z., et al., Vertical handover criteria and algorithm in IEEE802.11 and 802.16 hybrid networks. Proc. IEEE ICC, Beijing, China, May 19–23, 2008, pp. 2480–84.

  16. Zhang, Y., and Zhuang, W., Vertical handoff between 802.11 and 802.16 wireless access networks. GLOBECOM08, 2008.

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Acknowledgment

This research was supported by MKE (Ministry of Knowledge and Economy), Korea, Under the ITRC (Information Technology Research Center) support program supervised by the NIPA (National IT Industry Promotion Agency) (NIPA-2010-C1090-1011-0007) and by the National Research Foundation of Korea (NRF) grant funded by the Korea government (MEST)(No.2010-0018116).

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Correspondence to Pervez Khan.

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Khan, P., Ullah, N., Ullah, S. et al. Seamless Interworking Architecture for WBAN in Heterogeneous Wireless Networks with QoS Guarantees. J Med Syst 35, 1313–1321 (2011). https://doi.org/10.1007/s10916-011-9756-4

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  • DOI: https://doi.org/10.1007/s10916-011-9756-4

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