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A Novel Topology for the Zonal Network with Wireless Coverage

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DOI: 10.4236/cn.2009.12009    4,129 Downloads   7,602 Views   Citations

ABSTRACT

In this paper, we propose a banyan-tree topology for the wireless coverage along the road or railway, which is characterized as a zonal network. Theoretical analysis and numerical studies show that the proposed ban-yan-tree topology is appropriate for the zonal network with the Wireless Mesh Network (WMN) technology, which is feasible to deploy and has the enhanced robust, improved bandwidth with this topology.

Conflicts of Interest

The authors declare no conflicts of interest.

Cite this paper

F. ZOU, X. JIANG, Z. LIN and T. WANG, "A Novel Topology for the Zonal Network with Wireless Coverage," Communications and Network, Vol. 1 No. 2, 2009, pp. 57-62. doi: 10.4236/cn.2009.12009.

References

[1] China Internet Network Information Center, the 24th Statistical Report on Internet Development [R], Beijing, China, July 2009.
[2] Ministry of Tranport of the People’s Republic of China, Statistical Communique on the 2008 Road and Waterway Development [R], Beijing, China, April 2009.
[3] Ministry of Railways of the People’s Republic of China, Statistical Communique on the 2008 Railway Develop- ment [R], Beijing, China, June 2009.
[4] X. H. Jiang, F. M. Zou, Z. X. Lin, and T. S. Wang, “A Survey on the Internet Application on Passenger Train [J],” Journal of the China Railway Society, Vol. 29, No. 5, pp. 103–110, 2007.
[5] Roamad, “Highway Wi-Fi networks: A RoamAD white- paper with a case study on the Arizona I-19 highway Wi- Fi corridor [R],” February 2006, http://www.kordiasolutions.com/files/RoamAD_Case_Study_Arizona_Highway_Wi-Fi_Corridor.pdf.
[6] Y. F. Ko, M. L. Sim, and M. Nekovee, “Wi-Fi based broadband wireless access for users on the road [J],” BT Technology Journal, July 2006.
[7] U. S. Department of Transportation, Federal Railroad Administration, Study of High-Speed Wireless Data Transmissions for Railroad Operation [R], RR07-10, U.S.A, April 2007, http://www.fra.dot.gov/downloads/Research/rr0710.pdf.
[8] S. Savary and A. De Cort, “WiFi services in fast speed trains: The thalys user experience [C],” Train Communi- cations 2008, London, England, June 2008.
[9] G. I. Ohta, F. Kamada, N. Teramura, et al., “5 GHz W- LAN verification for public mobile applications—Internet newspaper on train and advanced ambulance car [C],” In proceedings of the 1st IEEE Consumer Commu- nications and Networking Conference, pp. 569–574, 2004.
[10] M. Hempel, H. Sharif, Z. Ting, et al., “A wireless test bed for mobile 802.11 and beyond [C],” International Wireless Communications and Mobile Computing Con- ference, Vancouver, Canada, pp. 1003–1008, 2006.
[11] A. Stefan and S. Wolfgang, “Performance measurements in wireless 802.11g Multi-Hop Networks [D],” the Uni- versity of H¨ogskolani Halmstad, Sweden, May 2006.
[12] R. D. Chen, H. W. Li, F. H. Li, et al., “Performance optimization in wireless Mesh networks based on Mesh point priority mechanism [C],” In Proceedings of Asia-Pacific Advanced Network, Singapore, 2006.
[13] Knuth and E. Donald, “The art Of computer programming: Fundamental algorithms, 3rd Edtion [M],” Addison-Wesley, Boston, Vol. 1, 1997.
[14] F. M. Zou and X. H. Jiang, “Improve the capacity of wireless backbone in multi-hop mesh network [J],” Science Technology and Engineering, Vol. 8, No. 13, pp. 3678–3681, 2008,

  
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