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Wireless Personal Communications

Erschienen in:

09.08.2020

RK-Energy Efficient Routing Protocol for Wireless Body Area Sensor Networks

verfasst von: Rahat Ali Khan, Qin Xin, Nabiha Roshan

Erschienen in: Wireless Personal Communications | Ausgabe 1/2021

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Abstract

Wireless Body Area Sensor Networks are related to the monitoring of human physiological parameters. In these small sized machines called sensors are used to observe the physiological parameters. They are small in size which makes them easy to carry around but on the same time they have a serious problem that they can carry with them a very small sized battery. The sensors deplete their energy while sensing the parameter, communication of the sensed data to the base station and also in processing of the observed data. The sensors cannot be charged on regular intervals because they are attached to human body and charging them may not be an easy option. In this paper an energy efficient routing protocol is presented which uses sensors in WBASN to observe parameter in much efficient way. The concept of multi hopping has been utilized with forwarder node. Forwarder node accepts data from sensor nodes which are far from the sink. After accepting data the forwarder node forwards this data to the sink node. This scheme is compared with an existing scheme with which it has been compared in terms of four parameters which are residual energy, network stability and life time, throughput and path loss.

Vorheriger Artikel A Reward Based Formal Model for Distributed Software Defined Networks

Nächster Artikel Energy Efficient Location Error Resilient Connectivity in Wireless Sensor Networks

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Khan, R. A., & Pathan, A. S. K. (2018). The state-of-the-art wireless body area sensor networks: A survey. IJDSN, 14, 1550147718768994.

Khan, R. A., Soomro, A. M., & Zafar, H. (2017). Minimizing path loss in medical wireless sensors in wireless body area sensor networks. IJST. https://doi.org/10.17485/ijst/2017/v10i32/11700.CrossRef

Khan, R. A., Memon, S., Zardari, S., Dhomeja, L. D., & Usman, M. (2016). Transposition technique for minimization of path loss in wireless on-body medical sensors. SURJ (Science Series), 48, 747–754.

Hasan, K., Biswas, K., Ahmed, K., Nafi, N. S., & Islam, M. S. (2019). A comprehensive review of wireless body area network. JNCA, 143, 178–198.

Ling, Z., Hu, F., & Shao, M. (2019). The optimal control policy for point-to-point wireless body area network based on simultaneous time-ratio and transmission power allocation. IEEE Access, 7, 46454–46460.CrossRef

Durai Rajan, D., Arya, S., & Chung, Y. H. (2019). Patient mobility support for indoor non-directed optical body area networks. Sensors, 19, 2297.CrossRef

Peng, H., Han, X., & Liu, H. (2019). Chain modeling of molecular communications for body area network. Sensors, 19, 395.CrossRef

Daniel, V., Costa, N., Roda-Sanchez, L., Olivares, T., Fernández-Caballero, A., & Pereira, A. (2019). Body area networks in healthcare: A brief state of the art. Applied Sciences, 9, 3248.CrossRef

Khalid, H., Biswas, K., Ahmed, K., Nafi, N. S., & Islam, Md. (2019). A comprehensive review of wireless body area network. JNCA, 143, 178–198.

10.

Sen, Y., Soh, P. J., & Vandenbosch, G. A. (2018). Wearable ultrawideband technology—A review of ultrawideband antennas, propagation channels, and applications in wireless body area networks. IEEE Access, 6, 42177–42185.CrossRef

11.

Ullah, Z., Ahmed, I., Khan, F. A., Asif, M., Nawaz, M., Ali, T., et al. (2019). Energy-efficient harvested-aware clustering and cooperative routing protocol for WBAN (E-HARP). IEEE Access, 7, 100036–100050.CrossRef

12.

Smail, O., Kerrar, A., Zetili, Y., & Cousin, B. (2016). ESR: Energy aware and stable routing protocol for WBAN networks. In Proceedings of the 2016 international wireless communications and mobile computing conference (IWCMC), Paphos, Cyprus, 5–9 Sept. 2016.

13.

Yousaf, S., Ahmed, S., Akbar, M., Javaid, N., Khan, Z. A., & Qasim, U. (2014). Co-CEStat: Cooperative critical data transmission in emergency in static wireless body area network. In Proceedings of 2014 ninth international conference on broadband and wireless computing, communication and applications (BWCCA), Guangdong, China, 8–10 Nov. 2014.

14.

Maskooki, A., Soh, C. B., Gunawan, E., & Low, K. S. (2011). Opportunistic routing for body area network. In Proceedings of 2011 IEEE consumer communications and networking conference (CCNC), Las Vegas, NV, USA, 9–12 Jan. 2011.

15.

Anwar, M., Abdullah, A. H., Altameem, A., Queshi, K. N., Masud, F., Faheem, M., et al. (2018). Green communication for wireless body area networks: Energy aware link efficient routing approach. Sensors, 18, 3237.CrossRef

16.

Jamil, F., Iqbal, M. A., Amin, R., & Kim, D. (2019). Adaptive thermal-aware routing protocol for wireless body area network. Electronics, 8, 47.CrossRef

17.

Liu, Y., Liu, D., & Yue, G. (2018). BGMM: a body Gauss-Markov based mobility model for body area networks. TST, 23, 277–287.

18.

Majumder, A. B., & Gupta, S. (2018). An energy-efficient congestion avoidance priority-based routing algorithm for body area network. In S. Bhattacharyya, S. Sen, M. Dutta, et al. (Eds.), Industry interactive innovations in science, engineering and technology: Lecture notes in networks and systems (Vol. 11). Singapore: Springer.

19.

Yang, X., Wang, L., & Zhang, Z. (2018). Wireless body area networks MAC protocol for energy efficiency and extending lifetime. IEEE Sensors Letters, 2, 1–4.

20.

Sandhu, M. M., Javaid, N., & Akbar, M., et al. (2014). FEEL: Forwarding data energy efficiently with load balancing in wireless body area networks. In Proceedings of the 2014 IEEE 28th international conference on advanced information networking and applications, Victoria, BC, Canada, 13–16 May 2014.

21.

Javaid, N., Abbas, Z., Fareed, M. S., Khan, Z. A., & Alrajeh, N. (2013). M-ATTEMPT: A new energy efficient routing protocol for wireless body area sensor networks. Procedia Computer Science, 19, 224–231.CrossRef

Titel: RK-Energy Efficient Routing Protocol for Wireless Body Area Sensor Networks
verfasst von: Rahat Ali Khan
Qin Xin
Nabiha Roshan
Publikationsdatum: 09.08.2020
Verlag: Springer US
Erschienen in: Wireless Personal Communications / Ausgabe 1/2021
Print ISSN: 0929-6212
Elektronische ISSN: 1572-834X
DOI: https://doi.org/10.1007/s11277-020-07734-z

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