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Wireless Networks
Erschienen in: Wireless Networks 8/2014

01.11.2014

Sensor and gateway location optimization in body sensor networks

verfasst von: Mari Carmen Domingo

Erschienen in: Wireless Networks | Ausgabe 8/2014

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Abstract

In body sensor networks (BSNs), energy-constrained sensors monitor the vital signs of human beings in healthcare applications. Energy consumption is a fundamental issue, since BSNs must operate properly and autonomously for long period of time without battery recharge or replacement. In addition, the human exposure to electromagnetic radiation must be limited. For all these reasons, the energy consumption in BSNs should be minimized. In this paper, sensor and gateway location optimization for BSNs has been analyzed. A mathematical model has been proposed to minimize the energy consumption of the BSN and the heating effects on human tissues. We distinguish between ‘in-body’ and ‘on-body’ sensors depending on their location inside or outside the human body, respectively. The theoretical analysis and the numerical results reveal that in in-BSNs the energy consumption can be significantly reduced when the optimal positions of the gateway or the sensors are computed. However, in on-BSNs the energy consumption is not affected by the devices’ location. With power control the interferences are minimized and the human exposure to electromagnetic radiation is reduced.
Vorheriger Artikel Rendezvous-based data dissemination for supporting mobile sinks in multi-hop clustered wireless sensor networks
Nächster Artikel Comprehensive event based estimation of sensor node distribution strategies using classical flooding routing protocol in wireless sensor networks

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Literatur
1.
Crosby, G. V., Ghosh, T., Murimi, R., & Chin, C. A. (2012). Wireless body area networks for healthcare: a survey. International Journal of Ad hoc, Sensor and Ubiquitous Computing (IJASUC), 3(3), 1–26.CrossRef
2.
Chen, Y., Teo, J., Lai, J. C. Y., Gunawan, E., Low, K. S., Soh, Ch B, et al. (2009). Cooperative communications in ultra-wideband wireless body area networks: channel modeling and system diversity analysis. IEEE Journal on Selected Areas in Communications, 27(1), 5–16.CrossRef
3.
Natarajan, A., Motani, M., De Silva, B., Yap, K.-K., & Chua, K. C. (2007). Investigating network architectures for body sensor networks. New York, USA: In Proc. of Health Net.
4.
Latré, B., Braem, B., Blondia, C., Moerman, I., & Demeester, P. (2011). A survey on wireless body area networks. Wireless Networks, 17(1), 1–18.CrossRef
5.
Zhen, B., Patel, M., Lee, S., Won, E., and Astrin, A. (2008). TG6 Technical requirements document (TRD) ID: 802.15-08-0644. IEEE Submission.
6.
Melodia, T., Pompili, D., and Akyildiz, I.F. A Communication Architecture for Mobile Wireless Sensor and Actor Networks. In Proc. of the 3rd Annual IEEE Communications Society on Sensor and Ad Hoc Communications and Networks (SECON ‘06), Sept. 2006.
7.
Xu, W., Zhang, M., Sawchuk, A. A., & Sarrafzadeh, M. (2012). Robust human activity and sensor location corecognition via sparse signal representation. IEEE Transactions on Biomedical Engineering, 59(11), 3169–3176.CrossRef
8.
Shah R.C., and Yarvis M. Characteristics of on-body 802.15.4 Networks. In Proc. of WiMesh, Sept. 2006.
9.
Oliveira C., Pedrosa L., and Rocha R.M. Characterizing On-body wireless sensor networks. In Proc. of NTMS, Nov. 2008.
10.
Yang W.-B., Sayrafian-Pour K., Hagedorn J., Terrill J., and Yazdandoost K.Y. Simulation study of body surface RF propagation for UWB wearable medical sensors. In Proc. of ISABEL, Nov. 2009.
11.
Amini, N., Sarrafzadeh, M., Vahdatpour, A., & Xu, W. (2011). Accelerometer-based on-body sensor localization for health and medical monitoring applications. Pervasive and Mobile Computing, 7, 746–760.CrossRef
12.
Atallah, L., Lo, B., King, R., & Yang, G.-Z. (2011). Sensor positioning for activity recognition using wearable accelerometers. IEEE Transactions on Biomedical Circuits and Systems, 5(4), 320–329.CrossRef
13.
Min, Ch-H, Tewfik, A. H., Kim, Y., & Menard, R. (2009). Optimal sensor location for body sensor network to detect self-stimulatory behaviors of children with autism spectrum disorder. Sept: In Proc. of EMBC.
14.
Patterson, J.A.C., McIlwraith, D.G., and Yang, G.-Z. A Flexible, Low Noise Reflective PPG Sensor Platform for Ear-Worn Heart Rate Monitoring. In Proc. of BSN, June 2009.
15.
Zhao, G., Mei, Z., Liang, D., Ivanov, K., Guo, Y., Wang, Y., et al. (2012). Exploration and implementation of a pre-impact fall recognition method based on an inertial body sensor network. Sensors (Basel), 12(11), 15338–15355.CrossRef
16.
Atallah, L., Aziz, O., Lo, B., and Yang, G.-Z., Detecting Walking Gait Impairment with an Ear-worn Sensor, in Proc. of BSN, June 2009.
17.
Jovanov, E., Milenkovic, A., Otto, C., & de Groen, P. C. (2005). A wireless body area network of intelligent motion sensors for computer assisted physical rehabilitation. Journal of NeuroEngineering and Rehabilitation, 2(1), 16–23.CrossRef
18.
19.
Reusens, E., Joseph, W., Latré, B., Braem, B., Vermeeren, G., Tanghe, E., et al. (2009). Characterization of on-body communication channel and energy efficient topology design for wireless body area networks. IEEE Transactions of Information Technology in Biomedicine, 13(6), 933–945.CrossRef
20.
Takizawa, K., Aoyagi, T., and Kohno, R. Channel Modeling and Performance Evaluation of UWB-based Wireless Body Area Networks. In Proc. of ICC 2009, June 2009.
21.
Yazdandoost, K.Y., and Sayrafian-Pour, K. Channel Model for Body Area Network (BAN). Report to the IEEE P802.15, ID: IEEE P802.15-08-0780-12-0006, November 2010.
22.
Byrd, R. H., Hribar, M. E., & Nocedal, J. (1999). An interior point algorithm for large scale nonlinear programming. SIAM Journal of Optimization, 9, 877–900.MathSciNetCrossRefMATH
23.
Gill, P. E., Murray, W., & Saunders, M. A. (2005). SNOPT: An SQP algorithm for large-scale constrained optimization. SIAM Review, 47(1), 99–131.MathSciNetCrossRefMATH
24.
25.
26.
Sasamori, T., Satoh, Y., Tobana, T., Isota, Y., Takahashi, M., and Uno T. Bit Error rate performance of wireless body area network system. In Proc. of IEEE Antennas and Propagation Society International Symposium (APSURSI), July 2010.
27.
Seunghyun, Oh, and Wentzloff, D.D. Portable hardware for real-time channel estimation on wireless body Area networks. In Proc. of Biomedical Circuits and Systems Conference (BioCAS), Nov. 2011.
28.
Hsieh, C.-H., Su M.Y., Kung, J.-Y., Lee S.-Y., and Fang, Q. Low-power 13.56 MHz RF Front-end Circuit for Body Sensor Network, In Proc. of International Symposium on Bioelectronics and Bioinformatics (ISBB), Nov. 2011.
29.
Chen, X., Lu, X., Jin, D., Su, Li, and Zeng, L. Channel modeling of UWB-based wireless body area networks, In Proc. of IEEE International Conference on Communications (ICC), June 2011.
Metadaten
Titel
Sensor and gateway location optimization in body sensor networks
verfasst von
Mari Carmen Domingo
Publikationsdatum
01.11.2014
Verlag
Springer US
Erschienen in
Wireless Networks / Ausgabe 8/2014
Print ISSN: 1022-0038
Elektronische ISSN: 1572-8196
DOI
https://doi.org/10.1007/s11276-014-0745-7

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