research-article

Augmenting mobile 3G using WiFi

Authors:

Aruna Balasubramanian,

Arun VenkataramaniAuthors Info & Claims

MobiSys '10: Proceedings of the 8th international conference on Mobile systems, applications, and services

Pages 209 - 222

https://doi.org/10.1145/1814433.1814456

Published: 15 June 2010 Publication History

Abstract

We investigate if WiFi access can be used to augment 3G capacity in mobile environments. We rst conduct a detailed study of 3G and WiFi access from moving vehicles, in three different cities. We find that the average 3G and WiFi availability across the cities is 87% and 11%, respectively. WiFi throughput is lower than 3G through-put, and WiFi loss rates are higher. We then design a system, called Wiffler, to augments mobile 3G capacity. It uses two key ideas leveraging delay tolerance and fast switching -- to overcome the poor availability and performance of WiFi. For delay tolerant applications, Wiffler uses a simple model of the environment to predict WiFi connectivity. It uses these predictions to delays transfers to offload more data on WiFi, but only if delaying reduces 3G usage and the transfers can be completed within the application's tolerance threshold. For applications that are extremely sensitive to delay or loss (e.g., VoIP), Wiffler quickly switches to 3G if WiFi is unable to successfully transmit the packet within a small time window. We implement and deploy Wiffler in our vehicular testbed. Our experiments show that Wiffler significantly reduces 3G usage. For a realistic workload, the reduction is 45% for a delay tolerance of 60 seconds.

References

[1]

T-Mobile @ Home. http://support.t--mobile.com/doc/tm23449.xml.

[2]

A. Balasubramanian, R. Mahajan, A. Venkataramani, B. Levine, and J. Zahorjan. Interactive WiFi Connectivity For Moving Vehicles. In Proc. ACM Sigcomm, August 2008.

Digital Library

[3]

A. Balasubramanian, Y. Zhou, W. B. Croft, B. N. Levine, and A. Venkataramani. Web Search From a Bus. In Proc. CHANTS workshop, September 2007.

Digital Library

[4]

N. Banerjee, M. D. Corner, and B. N. Levine. An Energy-Efficient Architecture for DTN Throwboxes. In Proc. IEEE Infocom, May 2007.

Digital Library

[5]

T. Bishop and A. James. Microsoft Giving Workers Free Ride with its Own Bus Service. http://seattlepi.nwsource.com/business/330745_msfttranspo07.html, 2007.

[6]

M. Buddhikot, G. Chandranmenon, S. J. Han, Y. W. Lee, and S. amd L. Salgarelli. Integration of 802.11 and Third Generation Wireless Data Networks. In Proc. IEEE Infocom, April 2003.

[7]

P. Deshpande, A. Kashyap, C. Sung, and S. R. Das. Predictive methods for improved vehicular wifi access. In Proc. MobiSys '09, June 2009.

Digital Library

[8]

A. Giannoulis, M. Fiore, and E. W. Knightly. Supporting Vehicular Mobility in Urban Multi-hop Wireless Networks. In Proc. MobiSys, June 2008.

Digital Library

[9]

D. Hadaller, S. Keshav, T. Brecht, and S. Agarwal. Vehicular Opportunistic Communication Under the Microscope. In Proc. MobiSys, June 2007.

Digital Library

[10]

D. Hadaller, S. Keshav, T. Brecht, and S. Agarwal. Vehicular Opportunistic Communication Under the Microscope. In Proc. MobiSys, June 2007.

Digital Library

[11]

M. Helft. Google Buses Help its Workers Beat the Rush. http://www.nytimes.com/2007/03/10/technology/10google.html, 2007.

[12]

B. Hull, V. Bychkovsky, Y. Zhang, K. Chen, M. Goraczko, A. Miu, E. Shih, H. Balakrishnan, and S. Madden. CarTel: a Distributed Mobile Sensor Computing System. In Proc. SenSys, October 2006.

Digital Library

[13]

X. Liu, A. Sridharan, S. Machiraju, M. Seshadri, and H. Zang. Experiences in a 3G Network: Interplay between the Wireless Channel and Applications. In Proc. MobiCom, September 2008.

Digital Library

[14]

R. Mahajan, J. Padhye, S. Agarwal, and B. Zill. E PluriBus Unum: High Performance Connectivity On Buses. Technical Report 2008-147, Microsoft Research, 2008.

[15]

R. Mahajan, J. Zahorjan, and B. Zill. Understanding WiFi-based Connectivity From Moving Vehicles. In Proc. IMC, October 2007.

Digital Library

[16]

A. J. Nicholson and B. D. Noble. BreadCrumbs: Forecasting Mobile Connectivity. In Proc. MobiCom, September 2008.

Digital Library

[17]

J. Ormont, J. Walker, S. Banerjee, A. Sridharan, M. Seshadri, and S. Machiraju. A City-wide Vehicular Infrastructure for Wide-area Wireless Experimentation. In WiNTECH, September 2008.

Digital Library

[18]

A. Rahmati and L. Zhong. Context-for-wireless: Context-sensitive Energy-efficient Wireless Data Transfer. In Proc. MobiSys, June 2007.

Digital Library

[19]

P. Rodriguez, R. Chakravorty, J. Chesterfield, I. Pratt, and S. Banerjee. MARS: A Commuter Router Infrastructure for the Mobile Internet. In Proc. MobiSys, June 2004.

Digital Library

[20]

E. Shih, P. Bahl, and M. J. Sinclair. Wake on Wireless: An Event Driven Energy Saving Strategy for Battery Operated Devices. In Proc. MobiCom, September 2002.

Digital Library

[21]

H. Soroush, N. Banerjee, A. Balasubramanian, M. D. Corner, B. N. Levine, and B. Lynn. DOME: A Diverse Outdoor Mobile Testbed. In Proc. HotPlanet workshop, June 2009.

Digital Library

[22]

K. Srinivasan, M. A. Kazandjieva, S. Agarwal, and P. Levis. The Beta-factor: Measuring Wireless Link Burstiness. In Proc. SenSys, October 2008.

Digital Library

[23]

P. Svennson. AT&T: Tighter Control of Cell Data Usage Ahead. http://seattletimes.nwsource.com/html/businesstechnology/2010461891_apustecattdatausage.html, 2009.

[24]

Economy + Internet Trends: Web 2.0 Summit. http://www.morganstanley.com/institutional/techresearch/pdfs/MS_Economy_Internet_Trends_102009_FINAL.pdf, 2009.

[25]

J. Wortham. Customers Angered as iPhones Overload 3G. http://www.nytimes.com/2009/09/03/technology/companies/03att.html?_r=2&partner=MYWAY&ei=5065/, 2009.

[26]

C. Ziegler. Sprint Falls in Line, Caps "Unlimited" Data at 5GB. http://www.engadgetmobile.com/2008/05/19/sprint-falls-in-line-caps-unlimited-data-at-5gb/, 2008.

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Index Terms

Augmenting mobile 3G using WiFi
1. Networks
  1. Network types
    1. Mobile networks
    2. Wireless access networks

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Published In

cover image ACM Conferences

MobiSys '10: Proceedings of the 8th international conference on Mobile systems, applications, and services

June 2010

382 pages

ISBN:9781605589855

DOI:10.1145/1814433

General Chair:
Sujata Banerjee
Hewlett-Packard Labs., USA
,
Program Chairs:
Srinivasan Keshav
University of Waterloo, Ontario, Canada
,
Alec Wolman
Microsoft Research Redmond, USA

Copyright © 2010 ACM.

Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

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SIGMOBILE: ACM Special Interest Group on Mobility of Systems, Users, Data and Computing

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SIGOPS: ACM Special Interest Group on Operating Systems

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Association for Computing Machinery

New York, NY, United States

Publication History

Published: 15 June 2010

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MobiSys'10

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SIGMOBILE

MobiSys'10: The 8th International Conference on Mobile Systems, Applications, and Services

June 15 - 18, 2010

California, San Francisco, USA

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Overall Acceptance Rate 274 of 1,679 submissions, 16%

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https://doi.org/10.1007/s42380-023-00204-7
Gupta AShanker U(2024)Caching in Location Based Services: Approaches, Challenges and Emerging TrendsWireless Personal Communications: An International Journal10.1007/s11277-024-11132-0135:3(1581-1615)Online publication date: 1-Apr-2024
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Stergiou CKoidou MPsannis K(2023)IoT-Based Big Data Secure Transmission and Management over Cloud System: A Healthcare Digital Twin ScenarioApplied Sciences10.3390/app1316916513:16(9165)Online publication date: 11-Aug-2023
https://doi.org/10.3390/app13169165
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Hu MWu DWu WCheng JChen M(2022)Quantifying the Influence of Intermittent Connectivity on Mobile Edge ComputingIEEE Transactions on Cloud Computing10.1109/TCC.2019.292670210:1(619-632)Online publication date: 1-Jan-2022
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