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Wireless Networks
Published in: Wireless Networks 7/2018

15-03-2017

A local synchronization-based wireless system for power efficient ad-hoc networks

Authors: Kyung-Tae Chung, Jihoon Lee, Yongseok Park, Hichan Moon

Published in: Wireless Networks | Issue 7/2018

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Abstract

In a scalable ad-hoc network, which is deployed in a large area with many nodes, it is difficult to maintain global time synchronization among all nodes in a whole network. Considering this problem, a local synchronization-based system is presented to discover neighboring nodes in a scalable wireless network. With the proposed system, a whole ad-hoc network is composed of several subgroups and local time synchronization is maintained within each subgroup. For the proposed system, the transmitter and receiver operations of a node are presented to discover neighboring nodes. The most important parameter for power consumption is the duty cycle of a node, defined as the ratio between the receiver turn-on time and total considered time. The duty cycles of the proposed system and cyclic quorum-based power management (CQPM) are compared by analysis. In addition, the power consumptions of the proposed system and CQPM are compared by simulation. The results show that the proposed system can reduce the power consumption of a node significantly in a scalable ad-hoc network.
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Literature
1.
Basagni, S., Giordano, M. C. S., & Stojmenovic, I. (2004). Mobile ad hoc networking. New York: IEEE Press.CrossRef
2.
IEEE Standard 802.11. (2012). IEEE standard for information technology, telecommunications and information exchange between systems, local and metropolitan area networks, specific requirement part 11: Wireless LAN MAC and PHY specifications.
3.
Nosovic, W., & Todd, T. D. (2002). Scheduled rendezvous and RFID wakeup in embedded wireless networks. In Proceedings of IEEE international conference on communications, New York, USA, 2002, pp. 3325–3329.
4.
Wu, S. L., Tseng, P. C., & Chou, Z. T. (2005). Distributed power management protocols for multi-hop mobile ad hoc networks. Computer Networks, 47(1), 63–85.CrossRefMATH
5.
Zheng, R., & Kravets, R. (2003). On-demand power management for ad hoc networks. In Proceedings of IEEE INFOCOM, San Francisco, USA, pp. 481–491.
6.
Romer, K. (2001). Time synchronization in ad hoc networks. In Proceedings of International Symposium on Mobile Ad Hoc Networking & Computing, New York, USA, pp. 173–182.
7.
Blum, J., Eskandarian, A., & Hoffman, L. (2004). Challenges of intervehicle ad hoc networks. IEEE Transactions on Intelligent Transportation Systems, 5(4), 347–351.CrossRef
8.
Indira, S. (2014). A survey on energy efficient protocols in mobile ad hoc networks. International Journal of Advances in Computer Science & Technology, 3(6), 390–394.
9.
Bekmezci, I., Sahingoz, O. K., & Temel, S. (2013). Flying ad-hoc networks (FANETs): A survey. Ad Hoc Networks, 11(3), 1254–1270.CrossRef
10.
Orlinski, M., & Filer, N. (2012). Movement speed based inter-probe times for neighbour discovery in mobile ad-hoc networks. In Proceedings of international conference on ad hoc networks, Paris, France, pp. 316–331.
11.
Tseng, Y. C., Hsu, C. S., & Hsieh, T. Y. (2003). Power saving protocols for IEEE 802.11 based multihop ad hoc networks. In Proceedings of IEEE INFOCOM, New York, USA, pp. 200–209.
12.
Choi, B., & Shen, X. (2011). Adaptive asynchronous sleep scheduling protocols for delay tolerant networks. IEEE Transactions on Mobile Computing, 10(9), 1283–1296.CrossRef
13.
Zheng, R., Hou, J. C., & Sha, L. (2003). Asynchronous wakeup for ad hoc networks. In Proceedings of International Symposium on Mobile Ad Hoc Networking & Computing, Annapolis, USA, pp. 35–45.
14.
Jiang, Z. R., Tseng, Y. C., Hsu, C. S., & Lai, T. H. (2005). Quorum-based asynchronous power saving protocols for IEEE 802.11 ad hoc networks. Mobile Networks and Applications, 10(1–2), 169–181.CrossRef
15.
Chou, Z. T. (2007). Optimal adaptive power management protocols for asynchronous wireless ad hoc networks. In Proceedings of wireless communications & networking conference, Hong Kong, pp. 61–65.
16.
Chao, C., Sheu, J., & Chou, I. (2006). An adaptive quorum-based energy conserving protocol for IEEE 802.11 ad hoc networks. IEEE Transactions on Mobile Computing, 5(5), 560–570.CrossRef
17.
Wu, S., Chen, M., & Chen, C. (2014). Optimally adaptive power-saving protocols for ad doc networks using the hyper quorum system. IEEE/ACM Transactions on Networking, 22(1), 1–15.CrossRef
18.
Wu, S., Chen, M., & Chen, C. (2008). Fully adaptive power saving protocols for ad hoc networks using the hyper quorum system. In Proceedings of international conference on distributed computing systems, Beijing, China.
19.
Wu, S., Sheu, J., & King, C. (2013). Unilateral wakeup for mobile ad hoc networks with group mobility. IEEE Transactions on Mobile Computing, 12(12), 2507–2517.CrossRef
20.
Wu, S., Sheu, J., & King, C. (2011). Unilateral wakeup for mobile ad hoc networks. In Proceedings of international conference on parallel processing.
21.
Younis, O., & Fahmy, S. (2004). HEED: A hybrid, energy-efficient, distributed clustering approach for ad hoc sensor networks. IEEE Transactions on mobile computing, 3(4), 366–379.CrossRef
22.
Bukhari, S. H. R., Rehmani, M. H., & Siraj, S. (2015). A survey of channel bonding for wireless networks and guidelines of channel bonding for futuristic cognitive radio sensor networks. IEEE Communications Survey & Tutorials, 18(2), 924–948.CrossRef
23.
Akyildiz, I., Lo, B., & Balakrishnan, R. (2011). Cooperative spectrum sensing in cognitive radio networks: A survey. Journal of Physical Communication, 4(1), 40–62.CrossRef
24.
Akhtar, F., Rehmani, M. H., & Reisslein, M. (2016). White space: Definitional perspectives and their role in exploiting spectrum opportunities. Telecommunications Policy, 40(4), 319–331.CrossRef
25.
Rehmani, M. H., Viana, A. C., Khalife, H., & Fdida, S. (2011). Improving data dissemination in multi-hop cognitive radio ad-hoc networks. In Proceedings of international conference on ad hoc networks, Paris, France, pp. 117–130.
26.
Bukhari, S. H. R., Siraj, S., & Rehmani, M. H. (2016). PRACB: A novel channel bonding algorithm for cognitive radio sensor networks. IEEE Access, 4, 6950–6963.CrossRef
27.
Singer, J. (1938). A theorem in finite projective geometry and some applications to number theory. Transactions of the American Mathematical Society, 43(3), 377–385.MathSciNetCrossRefMATH
28.
Goldsmith, A. (2004). Wireless communications. Cambridge: Cambridge Univ Press.
29.
Bluegiga. (2013). WF111-802.11 B/G/N Module, datasheet.
Metadata
Title
A local synchronization-based wireless system for power efficient ad-hoc networks
Authors
Kyung-Tae Chung
Jihoon Lee
Yongseok Park
Hichan Moon
Publication date
15-03-2017
Publisher
Springer US
Published in
Wireless Networks / Issue 7/2018
Print ISSN: 1022-0038
Electronic ISSN: 1572-8196
DOI
https://doi.org/10.1007/s11276-017-1488-z

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