BreadCrumbs: Forecasting Mobile Connectivity Presented by Hao He Slides adapted from Dhruv Kshatriya Anthony J. Nicholson and Brian D. Noble.

Slides:

Advertisements

Similar presentations

Pengfei Zhou, Yuanqing Zheng, Mo Li -twohsien

Advertisements

BreadCrumbs: Forecasting Mobile Connectivity Presented by Dhruv Kshatriya Paper by Anthony J. Nicholson Brian D. Noble.

BreadCrumbs: Forecasting Mobile Connectivity Anthony Nicholson and Brian Noble University of Michigan Presented by: Scott Winkleman.

VTrack: Energy-Aware Traffic Delay Estimation Using Mobile Phones Lenin Ravindranath, Arvind Thiagarajan, Katrina LaCurts, Sivan Toledo, Jacob Eriksson,

IODetector: A Generic Service for Indoor Outdoor Detection Pengfei Zhou†, Yuanqing Zheng†, Zhenjiang Li†, Mo Li†, and Guobin Shen‡ †Nanyang Technological.

WiFi-Reports: Improving Wireless Network Selection with Collaboration Presented By Tim McDowell.

ParkSense: A Smartphone Based Sensing System For On-Street Parking

VTrack: Accurate, Energy-Aware Road Traffic Delay Estimation Using Mobile Phones Arvind Thiagarajan, Lenin Ravindranath, Katrina LaCurts, Sivan Toledo,

3G v.s WIFI Radio Energy with YouTube downloads. Energy in Mobile Phone Data Transfers In 3G, there are three states –Idle –DCH (Dedicated Channel), do.

Augmenting Mobile 3G Using WiFi Sam Baek Ran Li Modified from University of Massachusetts Microsoft Research.

Energy-Efficient Positioning for Smartphone Applications using Cell-ID Sequence Matching Jeongyeup Paek *, Kyu-Han Kim +, Jatinder P. Singh +, Ramesh Govindan.

Institute of Networking and Multimedia, National Taiwan University, Jun-14, 2014.

Presented at ICC 2012 – Wireless Network Symposium – June 14 th 2012.

Accuracy Characterization for Metropolitan-scale Wi-Fi Localization Yu-Chung Cheng (UCSD, Intel Research) Yatin Chawathe (Intel Research) Anthony LaMarca.

ACCURACY CHARACTERIZATION FOR METROPOLITAN-SCALE WI-FI LOCALIZATION Presented by Jack Li March 5, 2009.

Accuracy Characterization for Metropolitan-scale Wi-Fi Localization Ying Wang, Xia Li Ying Wang, Xia Li.

P-1. P-2 Outline  Principles of cellular geo-location  Why Geo-Location?  Radio location principles  Urban area challenges  HAWK – suggested solution.

Tracking Fine-grain Vehicular Speed Variations by Warping Mobile Phone Signal Strengths Presented by Tam Vu Gayathri Chandrasekaran*, Tam Vu*, Alexander.

Probabilistic Aggregation in Distributed Networks Ling Huang, Ben Zhao, Anthony Joseph and John Kubiatowicz {hling, ravenben, adj,

Network and Systems Laboratory nslab.ee.ntu.edu.tw Kaisen Lin, Aman Kansal, Dimitrios Lymberopoulos, and Feng Zhao Archiang.

EnLoc: Energy-Efficient Localization for Mobile Phones Written By, Ionut Constandache (Duke), Shravan Gaonkar (UIUC), Matt Sayler (Duke), Romit Roy Choudhary.

Wireless “ESP”: Using Sensors to Develop Better Network Protocols Hari Balakrishnan Lenin Ravindranath, Calvin Newport, Sam Madden M.I.T. CSAIL.

Review: Accuracy Characterization for Metropolitan-scale Wi-Fi Localization Authors: Cheng, Chawathe, LaMacra, Krumm 2005 Slides Adapted from Cheng, MobiSys.

BluEyes Bluetooth Localization and Tracking Ei Darli Aung Jonathan Yang Dae-Ki Cho Mario Gerla Ei Darli Aung Jonathan Yang Dae-Ki Cho Mario Gerla.

April 20, 2008Emmett Nicholas ECE Drive-by Localization of Roadside WiFi Networks Anand Prabhu Subramanian, Pralhad Deshpande, Jie Gao, Samir R.

Power Consumption Measurement and Clock Synchronization on Low-Power Wireless Sensor Networks Author : Yu-Ping Chen, Quincy Wu 1.

Author : Yu-Ping Chen, Quincy Wu

Niranjan Balasubramanian Aruna Balasubramanian Arun Venkataramani University of Massachusetts Amherst Energy Consumption in Mobile Phones: A Measurement.

Presented by Tao HUANG Lingzhi XU. Context Mobile devices need exploit variety of connectivity options as they travel. Operating systems manage wireless.

ALBERT PARK EEL 6788: ADVANCED TOPICS IN COMPUTER NETWORKS Energy-Accuracy Trade-off for Continuous Mobile Device Location, In Proc. of the 8th International.

Rutgers: Gayathri Chandrasekaran, Tam Vu, Marco Gruteser, Rich Martin,

EXPLOITING VOIP SILENCE FOR WIFI ENERGY SAVINGS IN SMART PHONES Andrew J. Pyles 1, Zhen Ren 1, Gang Zhou 1, Xue Liu 2 1 College of William and Mary, 2.

Sensys 2009 Speaker:Lawrence.  Introduction  Overview & Challenges  Algorithm  Travel Time Estimation  Evaluation  Conclusion.

A measurement study of vehicular internet access using in situ Wi-Fi networks Vladimir Bychkovsky, Bret Hull, Allen Miu, Hari Balakrishnan, and Samuel.

PERSONAL MEDICAL MONITOR Jason Ewing, Morgan Hinchcliffe, Dina Irgebayeva and Aida Kulmambetova.

Detecting Movement Type by Route Segmentation and Classification Karol Waga, Andrei Tabarcea, Minjie Chen and Pasi Fränti.

Beyond Cognitive Radio: Lower Layer Protocols Venu Veeravalli Yingbin Liang.

Physical Layer Informed Adaptive Video Streaming Over LTE Xiufeng Xie, Xinyu Zhang Unviersity of Winscosin-Madison Swarun KumarLi Erran Li MIT Bell Labs.

1 Energy-efficient Localization Via Personal Mobility Profiling Ionut Constandache Co-authors: Shravan Gaonkar, Matt Sayler, Romit Roy Choudhury and Landon.

UbiStore: Ubiquitous and Opportunistic Backup Architecture. Feiselia Tan, Sebastien Ardon, Max Ott Presented by: Zainab Aljazzaf.

WiFi-Reports: Improving Wireless Network Selection Jeffrey Pang (CMU) with Ben Greenstein (IRS) Michael Kaminsky (IRP) Damon McCoy (U. Colorado) Srinivasan.

By: Emma Barnett CELL PHONE GPS: SAFETY OR STALKING DEVICES?

Machine Learning Approach to Report Prioritization with an Application to Travel Time Dissemination Piotr Szczurek Bo Xu Jie Lin Ouri Wolfson.

Energy Consumption in Mobile Phones: A Measurement Study and Implications for Network Applications REF:Balasubramanian, Niranjan, Aruna Balasubramanian,

Energy Efficient Location Sensing Brent Horine March 30, 2011.

A Survey of Spectrum Sensing Algorithm for Cognitive Radio Applications YaGun Wu netlab.

© 2010 IBM Corporation IBM Research - Ireland © 2014 IBM Corporation xStream Data Fusion for Transport Smarter Cities Technology Centre IBM Research.

Inhomogeneous Wireless Network Load Distribution Kuang-Hui Chi* Meng-Hsuan Chiang Institute of Electrical Engineering National Yunlin University of Science.

ECO-DNS: Expected Consistency Optimization for DNS Chen Stephanos Matsumoto Adrian Perrig © 2013 Stephanos Matsumoto1.

Accuracy Characterization for Metropolitan-scale Wi-Fi Localization Yu-Chung Cheng (UCSD, Intel Research) Yatin Chawathe (Intel Research) Anthony LaMarca.

Sybot: An Adaptive and Mobile Spectrum Survey System for WiFi Networks Kyu-Han Kim, Alexander W. Min,Kang G. Shin Mobicom Twohsien

Human Tracking System Using DFP in Wireless Environment 3 rd - Review Batch-09 Project Guide Project Members Mrs.G.Sharmila V.Karunya ( ) AP/CSE.

Wireless Trace Analysis. Project Goals Summary of project goals: First goal: analyze wireless access patterns Second goal: implement Markov predictor.

1.Research Motivation 2.Existing Techniques 3.Proposed Technique 4.Limitations 5.Conclusion.

Performance of Adaptive Beam Nulling in Multihop Ad Hoc Networks Under Jamming Suman Bhunia, Vahid Behzadan, Paulo Alexandre Regis, Shamik Sengupta.

War Walking vs. War Driving Trying to find the reasons why war walking radio map performs better.

Bus Detection Device For The Passenger Using GPS And Gsm Application Student Name USN NO Guide Name H.O.D Name Name Of The College & Dept.

COGNITIVE NETWORK ACCESS USING FUZZY DECISION MAKING Nicola Baldo and Michele Zorzi Department of Information Engineering – University of Padova, Italy.

Dejavu:An accurate Energy-Efficient Outdoor Localization System SIGSPATIAL '13.

Indoor positioning systems Kyle Hampton. Outline Introduction Uses Players Techniques Challenges Future Conclusion.

GSU Indoor Navigation Senior Project Fall Semester 2013 Michael W Tucker.

Accurate WiFi Packet Delivery Rate Estimation and Applications Owais Khan and Lili Qiu. The University of Texas at Austin 1 Infocom 2016, San Francisco.

Adaptive Roaming between LTE and Wi-Fi 1 Daeguil Science high school, Daegu, Republic of Korea. 2 Daegu Gyeongbuk Institute of Science and Technology,

How to Track the Location of a Mobile Phone.

Networks and Connecting to the Internet

PERFORMANCE ANALYSIS OF SPECTRUM SENSING USING COGNITIVE RADIO

Net 435: Wireless sensor network (WSN)

Sentio: Distributed Sensor Virtualization for Mobile Apps

Panagiotis G. Ipeirotis Luis Gravano

E-MiLi: Energy-Minimizing Idle Listening in Wireless Networks

Presentation transcript:

BreadCrumbs: Forecasting Mobile Connectivity Presented by Hao He Slides adapted from Dhruv Kshatriya Anthony J. Nicholson and Brian D. Noble

2 Observations Access points come and go as users move Not all network connections created equal Limited time to exploit a given connection

The big idea(s) in this paper ‏ Introduce the concept of connectivity forecasts Show how such forecasts can be accurate for everyday situations w/o GPS or centralization Illustrate through example applications 3

Road Map Background knowledge Connectivity forecasting Evaluation Conclusion

Background knowledge Determining AP quality Wifi-Reports: Improving Wireless Network Selection with Collaboration Estimating Client Location

6 Improved Access Point Selection Conventionally AP’s with the highest signal strength are chosen. Probe application-level quality of access points  Bandwidth, latency, open ports  AP quality database guides future selection Real-world evaluation  Significant improvement over link-layer metrics

7 Determining location Best: GPS on device  Unreasonable assumption? PlaceLab  Triangulate beacons  Wardriving databases Other options  Accelerometer, GSM beacons

8 Connectivity Forecasting Maintain a personalized mobility model on the user's device to predict future associations Combine prediction with AP quality database to produce connectivity forecasts Applications use these forecasts to take domain-specific actions

9 Mobility model Humans are creatures of habit  Common movement patterns Second-order Markov chain  Reasonable space and time overhead (mobile device) ‏  Literature shows as effective as fancier methods State: current GPS coord + last GPS coord  Coords rounded to one-thousandth of degree (110m x 80m box)

Mobility model example

11 Connectivity forecasts Applications and kernel query BreadCrumbs Expected bandwidth (or latency, or...) in the future Recursively walk tree based on transition frequency

12 Forecast example: downstream BW current What will the available downstream bandwidth be in 10 seconds (next step)? * * * = KB/s

13 Evaluation methodology Tracked weekday movements for two weeks  Linux 2.6 on iPAQ + WiFi  Mixture of walking, driving, and bus Primarily travel to/from office, but some noise  Driving around for errands  Walk to farmers' market, et cetera Week one as training set, week two for eval

14 AP statistics

15 Forecast accuracy

16 Application: opportunistic writeback

Application: Radio Deactivation Goal  Conserving energy Implementation  Query BreadCrumbs to get a connectivity forecast  If radio on & no connectivity in next 30 secs Turn radio off  Else If radio off & BreadCrumbs predicts connectivity in next 30 secs

Application: Radio Deactivation

Application: Phone network vs. WiFi

20 Summary Humans (and their devices) are creatures of habit Mobility model + AP quality DB = connectivity forecasts Minimal application modifications yield benefits to user

Future work Evaluation: not representative Energy efficient Modification to software Limited to certain applications: ex. download

Thank you!