A Three-tiered Architecture for Large-scale Wireless Hospital Sensor Networks
Jamila Ben Slimane, Ye-Qiong Song, Anis Koubâa, Mounir Frikha
2009
Abstract
The Utra Wide Band physical layer specified by the IEEE 802.15.4a standard [1] presents numerous advantages comparing with its original IEEE 802.15.4 standard, namely high accuracy positioning ability, high data rate up to 27 mbps, extended communication range, low power consumption and low complexity. Actually, many research and development activities focus on the design of UWB sensor nodes entities. However nodes interactions or network configuration are neglected. For that, we propose in this paper to investigate the use of UWB for large scale Wireless Hospital Sensor Networks (WHSNs) to benefit from the advantages offered by the UWB technology. This evolving networking paradigm promises to revolutionize healthcare by allowing inexpensive, non-invasive, pervasive and ubiquitous, ambulatory health monitoring. We present the design of new system architecture, based on IEEE 802.15.4a compliant sensors, suitable for health monitoring application in high dense hospital environment. The proposed system architecture is intended to support large-scale deployment and to improve the network performance in terms of energy efficiency, real-time guarantees and Quality-of-Service (QoS).
References
- IEEE 802.15.4a Standard (2007) Part 15.4: IEEE Standard for Information Technology, Amendment to IEEE Std 802.15.4™-2006, (2007)
- Tan, A.E.C., Chia, M.Y.W,: Measuring human body impulse response using UWB radar, Electronics Letters, Vol. 41, Iss. 21, (2005) 1193 - 1194
- Ryckaert, J., Desset, C., Fort, A., Badaroglu, M., De Heyn, V., Wambacq, P., Van der Plas, G., Donnay, S., Van Poucke, B., Gyselinckx, B., : Ultra-Wide Band Transmitter for Wireless Body Area Networks. IEEE Transactions on Circuits and Systems I, Vol.52, No.12, (2005) 2515- 2525
- Domenicali, D., Di Benedetto, M.-G.,:Performance Analysis for a Body Area Network composed of IEEE 802.15.4a devices. The 4th Workshop on Positioning, Navigation and Communication Hannover, Germany. (2007) 273-276
- Yang-Sun, L., Jae-Min, K., Sung-Eon, C., Ji-Woong, K., Heau-Jo, K.,:A Study on the Medical Image Transmission Service Based on IEEE 802.15.4a. Springer Berlin / Heidelberg, (2007) 159-167
- Kottapalli, V-A., Kiremidjian, A-S., Lynch, J-P., Carryer, E., Kenny, T-W., Law, K-H., Lei,Y., :Two-tiered wireless sensor network architecture for structural health monitoring. 10th Annual International Symposium on Smart Structures and Materials, USA (2003)
- Bin, Z., Chao, H., HaiBin, W., Ruiwen G., Meng, M.Q-H., : A wireless Sensor Network for Pervasive Medical Supervision. IEEE International Conference on Integration Technology, Shenzhen, China (2007) 740-744
- OTTO, C., Milenkovic, A., Sanders, C., Jovanov, E.,: System Architecture of A Wireless Body Area Sensor Network For Ubiquitous Health Monitoring. Journal of Mobile Multimedia, Vol. 1. No.4 (2006) 307-326
- Milenkovic, A., OTTO, C., Jovanov, E.,: Wireless Sensor Network for Personal Health Monitoring Issues and an Implementation. Computer Communications. Elsevier (2006)
- She, H., Lu, Z., Jantsch, A., Zheng, L-R., Zhou, D., : A Network-based System Architecture for Remote Medical Applications. Network Research Workshop (2007)
- Hongliang, R., Meng, M-Q-H., Xijun, C.,: Physiological Information Acquisition through Wireless Biomedical Sensor Networks. Hong Kong and Macau, China (2005) 483-488
- Hongliang, R., Meng, M- Q-H., Xijun, C., Haibin, S., Bin, F.,Yawen, C., : System Architecture of Body Area Network and Its Web Services Based Data Publishing. Springer Berlin / Heidelberg. 947-954
- Espina, J., Falck, T., Mülhens, O.,: Network Topologies, Communication Protocols, and Standards. Spriger book. Body Sensor Networks 145-182
- http://www.imec.be/wwwinter/mediacenter/en/SR2006/681579.htm
- Bin, Z., Huan-Bang, L., Ryuji, K., : IEEE Body Area Networks for Medical Applications. IEEE International Symposium on Wireless Communications Systems (2007) 327-331
- IEEE 802.15.4 Standard Part 15.4: Wireless medium access control (MAC) and physical layer (PHY) specifications for Low-Rate Wireless Personal Area Networks (LR-WPANs), IEEE Standard for Information Technology, Revision of IEEE Std 802.15.4-2003, 2006.
- Koubâa, A., Alves. M., Tovar. E., : i-GAME: An Implicit GTS Allocation Mechanism in IEEE 802.15.4, In Euromicro Conference on Real-Time Systems (2006)
- Ben Slimane, J., Song, Y-Q., Frikha, M., Koubâa, A.,:A multi-channel mac protocol for wireless hospital sensor networks, Technical report, 2008, http://hal.inria.fr/inria00322584/fr/.
- http://www.opnet.com/
Paper Citation
in Harvard Style
Ben Slimane J., Song Y., Koubâa A. and Frikha M. (2009). A Three-tiered Architecture for Large-scale Wireless Hospital Sensor Networks . In Proceedings of the 1st International Workshop on Mobilizing Health Information to Support Healthcare-related Knowledge Work - Volume 1: Workshop MobiHealthInf, (BIOSTEC 2009) ISBN 978-989-8111-78-4, pages 20-31. DOI: 10.5220/0001813500200031
in Bibtex Style
@conference{workshop mobihealthinf09,
author={Jamila Ben Slimane and Ye-Qiong Song and Anis Koubâa and Mounir Frikha},
title={A Three-tiered Architecture for Large-scale Wireless Hospital Sensor Networks },
booktitle={Proceedings of the 1st International Workshop on Mobilizing Health Information to Support Healthcare-related Knowledge Work - Volume 1: Workshop MobiHealthInf, (BIOSTEC 2009)},
year={2009},
pages={20-31},
publisher={SciTePress},
organization={INSTICC},
doi={10.5220/0001813500200031},
isbn={978-989-8111-78-4},
}
in EndNote Style
TY - CONF
JO - Proceedings of the 1st International Workshop on Mobilizing Health Information to Support Healthcare-related Knowledge Work - Volume 1: Workshop MobiHealthInf, (BIOSTEC 2009)
TI - A Three-tiered Architecture for Large-scale Wireless Hospital Sensor Networks
SN - 978-989-8111-78-4
AU - Ben Slimane J.
AU - Song Y.
AU - Koubâa A.
AU - Frikha M.
PY - 2009
SP - 20
EP - 31
DO - 10.5220/0001813500200031