Jigsaw: solving the puzzle of enterprise 802.11 analysis

The combination of unlicensed spectrum, cheap wireless interfaces and the inherent convenience of untethered computing have made 802.11 based networks ubiquitous in the enterprise. Modern universities, corporate campuses and government offices routinely de-ploy scores of access points to blanket their sites with wireless Internet access. However, while the fine-grained behavior of the 802.11 protocol itself has been well studied, our understanding of how large 802.11 networks behave in their full empirical complex-ity is surprisingly limited. In this paper, we present a system called Jigsaw that uses multiple monitors to provide a single unified view of all physical, link, network and transport-layer activity on an 802.11 network. To drive this analysis, we have deployed an infrastructure of over 150 radio monitors that simultaneously capture all 802.11b and 802.11g activity in a large university building (1M+ cubic feet). We describe the challenges posed by both the scale and ambiguity inherent in such an architecture, and explain the algorithms and inference techniques we developed to address them. Finally, using a 24-hour distributed trace containing more than 1.5 billion events, we use Jigsaw's global cross-layer viewpoint to isolate performance artifacts, both explicit, such as management inefficiencies, and implicit, such as co-channel interference. We believe this is the first analysis combining this scale and level of detail for a production 802.11 network.

[1]  Dan Duchamp,et al.  Measured performance of a wireless LAN , 1992, [1992] Proceedings 17th Conference on Local Computer Networks.

[2]  Randy H. Katz,et al.  A trace-based approach for modeling wireless channel behavior , 1996, Winter Simulation Conference.

[3]  Peter Steenkiste,et al.  Measurement and analysis of the error characteristics of an in-building wireless network , 1996, SIGCOMM 1996.

[4]  Mary Baker,et al.  Analysis of a local-area wireless network , 2000, MobiCom '00.

[5]  Deborah Estrin,et al.  Proceedings of the 5th Symposium on Operating Systems Design and Implementation Fine-grained Network Time Synchronization Using Reference Broadcasts , 2022 .

[6]  Paramvir Bahl,et al.  Characterizing user behavior and network performance in a public wireless LAN , 2002, SIGMETRICS '02.

[7]  Andreas Willig,et al.  Measurements of a wireless link in an industrial environment using an IEEE 802.11-compliant physical layer , 2002, IEEE Trans. Ind. Electron..

[8]  David Kotz,et al.  Analysis of a Campus-Wide Wireless Network , 2002, MobiCom '02.

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

[10]  Magdalena Balazinska,et al.  Characterizing mobility and network usage in a corporate wireless local-area network , 2003, MobiSys '03.

[11]  Deborah Estrin,et al.  Optimal and Global Time Synchronization in Sensornets , 2003 .

[12]  Robert Tappan Morris,et al.  Link-level measurements from an 802.11b mesh network , 2004, SIGCOMM '04.

[13]  Donald F. Towsley,et al.  Inferring TCP connection characteristics through passive measurements , 2004, IEEE INFOCOM 2004.

[14]  Kevin C. Almeroth,et al.  DAMON: a distributed architecture for monitoring multi-hop mobile networks , 2004, 2004 First Annual IEEE Communications Society Conference on Sensor and Ad Hoc Communications and Networks, 2004. IEEE SECON 2004..

[15]  David Schwab,et al.  Characterising the use of a campus wireless network , 2004, IEEE INFOCOM 2004.

[16]  Tristan Henderson,et al.  The changing usage of a mature campus-wide wireless network , 2004, MobiCom '04.

[17]  Moustafa Youssef,et al.  A framework for wireless LAN monitoring and its applications , 2004, WiSe '04.

[18]  Moustafa Youssef,et al.  An accurate technique for measuring the wireless side of wireless networks , 2005, WiTMeMo '05.

[19]  Ratul Mahajan,et al.  Measurement-based characterization of 802.11 in a hotspot setting , 2005, E-WIND '05.

[20]  Kevin C. Almeroth,et al.  Understanding link-layer behavior in highly congested IEEE 802.11b wireless networks , 2005, E-WIND '05.

[21]  Kevin C. Almeroth,et al.  Understanding congestion in IEEE 802.11b wireless networks , 2005, IMC '05.

[22]  Geoffrey M. Voelker,et al.  Access and mobility of wireless PDA users , 2003, MOCO.

[23]  Félix Hernández-Campos,et al.  A comparative measurement study the workload of wireless access points in campus networks , 2005, 2005 IEEE 16th International Symposium on Personal, Indoor and Mobile Radio Communications.

[24]  Ratul Mahajan,et al.  Analyzing the MAC-level behavior of wireless networks in the wild , 2006, SIGCOMM.