Enabling faster and smoother handoffs in AP-dense 802.11 wireless networks

Nowadays, 802.11-based wireless networks have gained greater popularity as they cover more schools, restaurants, offices, and cities. Unlike static wireless connections, people expect user-friendly features from 802.11 wireless networking infrastructures such as support for seamless roaming. In this paper, we study the handoff process in large AP-dense 802.11 networks, which are among the most commonly used forms of 802.11 networks. To enable faster and smoother handoffs in these AP-dense networks, we focus on improving the AP scan process, which is a bottleneck to such handoffs. We carry out a series of field experiments and evaluate critical handoff parameters through extensive analysis of the acquired data. From these experiments, we discover two key features, differentiated probe response time and rich AP information hidden in wireless traffic, which can improve the AP scan process. We present our solution, Scan in AP-dense 802.11 Networks (D-Scan for short), that leverages these features to do so. We conduct real-world experiments that show D-Scan's strong performance compared with current AP scan solutions.

[1]  Gurpal Singh,et al.  A Signalling Technique for Disseminating Neighbouring AP Channel Information to Mobile Stations , 2006, ICDCN.

[2]  Ranveer Chandra,et al.  A virtualization architecture for wireless network cards , 2006 .

[3]  William A. Arbaugh,et al.  An empirical analysis of the IEEE 802.11 MAC layer handoff process , 2003, CCRV.

[4]  Stefan Savage,et al.  SyncScan: practical fast handoff for 802.11 infrastructure networks , 2005, Proceedings IEEE 24th Annual Joint Conference of the IEEE Computer and Communications Societies..

[5]  I. Moerman,et al.  Access network controlled fast handoff for streaming multimedia in WLAN , 2007, 2007 16th IST Mobile and Wireless Communications Summit.

[6]  Peng Manman Summarization of Investigation on IEEE 802.11 AP Handoff Based on Load , 2006 .

[7]  Mike Y. Chen,et al.  Improved access point selection , 2006, MobiSys '06.

[8]  William A. Arbaugh,et al.  Improving the latency of 802.11 hand-offs using neighbor graphs , 2004, MobiSys '04.

[9]  Suman Banerjee,et al.  Eliminating handoff latencies in 802.11 WLANs using multiple radios: applications, experience, and evaluation , 2005, IMC '05.

[10]  Srinivasan Seshan,et al.  Self-management in chaotic wireless deployments , 2005, MobiCom '05.

[11]  Haitao Wu,et al.  Proactive Scan: Fast Handoff with Smart Triggers for 802.11 Wireless LAN , 2007, IEEE INFOCOM 2007 - 26th IEEE International Conference on Computer Communications.

[12]  Gurpal Singh,et al.  Effect of background scan on performance of neighbouring channels in 802.11 networks , 2008 .

[13]  Yu-Chee Tseng,et al.  A Fast Handoff Mechanism for IEEE 802.11 and IAPP Networks , 2006, 2006 IEEE 63rd Vehicular Technology Conference.

[14]  Chaewoo Lee,et al.  A fast handoff algorithm using intelligent channel scan for IEEE 802.11 WLANs , 2004, The 6th International Conference on Advanced Communication Technology, 2004..

[15]  Konstantina Papagiannaki,et al.  Using smart triggers for improved user performance in 802.11 wireless networks , 2006, MobiSys '06.

[16]  Weijia Jia,et al.  D-Scan: Enabling Fast and Smooth Handoffs in AP-Dense 802.11 Wireless Networks , 2009, IEEE INFOCOM 2009.