Enabling location-based services in wireless LAN hotspots

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Enabling location-based services in wireless LAN hotspots

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International Journal of Network Management archive
Volume 15 , Issue 3 (May 2005) table of contents

Pages: 163 - 175

Year of Publication: 2005

ISSN:1099-1190

Authors

Yen-Cheng Chen	Department of Information Management, National Chi Nan University, Puli, Nantou 545, Taiwan
Yao-Jung Chan	Teacher of Tungshih Industrial Vocational Senior High School, Taiwan
Cheung-Wo She	Graduate Institute of Information Management, Chang Gung University, Taiwan

Publisher

John Wiley & Sons, Inc. New York, NY, USA

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DOI Bookmark:	10.1002/nem.558

ABSTRACT

The wide deployment of IEEE 802.11 Wireless LAN (WLAN) makes possible application services developed in WLAN hotspots. Owing to the small cell size in WLAN hotspots, it is practical to develop location-based services with the awareness of the WLAN access points (APs) that mobile devices currently access. In this paper, we propose an effective location determination technique using the inherent SNMP support in WLAN APs. It is shown that the current location of a mobile device can be determined from the SNMP traps sent by APs. Since the SNMP-based approach doesn't need any particular software or hardware in mobile devices, location-based services can be widely deployed, especially in public WLAN hotspots. To further enable location-based services through the WWW, this paper also considers the location determination of a mobile device from its IP address, retrieved in a WWW environment. In addition, we propose a web service framework for location-based services in WLAN hotspots. Thus, location-based services can be developed in a standard way.

REFERENCES

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	1	1. IEEE Computer Society LAN MAN Standards Committee. Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) Specifications, IEEE Std 802.11, 1999. The Institute of Electrical and Electronics Engineers, 1999.
	2	2. Case J, Fedor M, Schoffstall M, Davin J. Simple Network Management Protocol. IETF, RFC 1157, http://www.ietf.org/rfc/, May 1990.
	3	3. SnapTrack Incorporated. Location Technologies for GSM, GPRS and UMTS Networks. http://www. cematech.com/resources/pdf/location_tech_wp_1- 03.pdf. Jan. 2003.
	4	Jeffrey Hightower , Gaetano Borriello, Location Systems for Ubiquitous Computing, Computer, v.34 n.8, p.57-66, August 2001 [doi>10.1109/2.940014]
	5	5. Bahl P, Padmanabhan VN. RADAR: an in -building RF-based user location and tracking system. Proceeding of IEEE INFOCOM, March 2000, Vol. 2: 775-784.
	6	Paul Castro , Patrick Chiu , Ted Kremenek , Richard R. Muntz, A Probabilistic Room Location Service for Wireless Networked Environments, Proceedings of the 3rd international conference on Ubiquitous Computing, p.18-34, September 30-October 02, 2001, Atlanta, Georgia, USA
	7	7. Smailagic A, Kogan D. Location sensing and privacy in a context-aware computing environment. IEEE Wireless Communications 2002; 9(5): 10-17.
	8	Kaveh Pahlavan , Prashant Krishnamurthy, Principles of Wireless Networks: A Unified Approach, Prentice Hall PTR, Upper Saddle River, NJ, 2001
	9	9. Prasithsangaree P, Krishnamurthy P, Chrysanthis PK. On indoor position location with Wireless LANs. Proceeding of the 13th IEEE International Symposium on Personal, Indoor, and Mobile Radio Communications, Sept. 2002, Lisbon, Portugal.
	10	10. Koo SGM, Rosenberg C, Chan H-H, Lee YC. Location discovery in enterprise-based wireless networks: Implementation and applications. Proceeding of the 2nd IEEE Workshop on Applications and Services in Wireless Networks, July 2002, Paris, France.
	11	11. Rigney C, Willens S, Rubens A, Simpson W. Remote Authentication Dial in User Service (RADIUS). IETF, RFC 2865, http://www.ietf.org/rfc/, June 2000.
	12	12. Koo SGM, Rosenberg C, Chan H, Lee YC. Location discovery in enterprise-based wireless networks: Case studies and applications. Annals of Telecommunications 2003; 58(3-4): 531-552.
	13	13. McCloghrie K, Rose T. Management Information Base for Network Management of TCP/IP -based Internets. IETF, RFC 1213, http://www.ietf.org/ rfc/, March 1991.
	14	14. Cisco Systems, Inc. Cisco Aironet 350 Series Access Points, 2003. http://www.cisco.com/warp/public/ cc/pd/witc/ao350ap/prodlit/carto_in.pdf.
	15	15. Symbol Technologies Inc. Spectrum24 4131 Access Point, 2003. http://www.symbol.com/products/ wireless/ap4131.html
	16	16. Intel Corporation. Intel® PRO/Wireless 2011 LAN Access Point, 2003. http://www.intel.com/ support/network/wireless/pro2011/accesspoint/ index.htm
	17	17. Linksys, Cisco Systems, Inc. WAP11--Instant Wireless Network Access Point, 2003. ftp://ftp.linksys. com/datasheet/wapIIds.pdf
	18	18. Rekhter Y, Moskowitz B, Karrenberg D, de Groot G, Lear E. Address Allocation for Private Internets, IETF, RFC 1918, http://www.ietf.org/rfc/, February 1996.
	19	19. Srisuresh P, Egevang K. Traditional IP Network Address Translator (Traditional NAT), IETF, RFC 3022, http://www.ietf.org/rfc/, January 2001.
	20	20. Rohit R, Srisuresh P, Raghunarayan R, Pai N, Wang C. Definitions of Managed Objects for Network Address Translators, Internet Draft, http://www. ietf.org/internet-drafts/draft-ietf-nat-natmib-09.txt, April 2004.
	21	21. W3C. Simple Object Access Protocol, June 2003. http://www.w3.org/TR/SOAP/