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MoteTrack: A Robust, Decentralized Approach to RF Based Location Tracking

MoteTrack: A Robust, Decentralized Approach to RF Based Location Tracking. Paper Presentation CSE: 535 – mobile computing Weijia Che Phd student, CSE Dept, ASU. Paper Selection. Title: MoteTrack: A Robust, Decentralized Approach to RFBased Location Tracking

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MoteTrack: A Robust, Decentralized Approach to RF Based Location Tracking

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  1. MoteTrack: A Robust, Decentralized Approach to RF Based Location Tracking Paper Presentation CSE: 535 – mobile computing Weijia Che Phd student, CSE Dept, ASU

  2. Paper Selection • Title: MoteTrack: A Robust, Decentralized Approach to RFBased Location Tracking • Authors: Konnrad Lorincz and matt Welsh • Published: tech. report TR-19-04, Division of Eng. and Applied Sciences, Harvard Univ., 2004.

  3. Agenda • Motivation Scenario • Background and Related Work • MoteTrack Overview • Robust Design • Implementation • Evaluation • Novelty and Drawbacks • Relationship with our Project • References

  4. Motivation Scenario • Firefighters entering a large building • Heavy smoke coverage • No priori notion of building layout • Indications: • Centralized approaches not suitable (central server/user’s roaming node may be destroyed) • Approaches require whole-network wireless connectivity not suitable (large num of wireless access points may have failed)

  5. Background and Related Work • Indoor Localization based on different context • Infrared • Ultrasound • RF-RSSI

  6. Indoor Localization based on Infrared • Eg. Active Badge [1] • Advantage • suitable for both indoor and outdoor use • Disadvantage • Many receiver nodes are required due to short range of infrared signals • Require line-of-sight exposure • Suffer errors in the presence of strong light

  7. Indoor Localization based on ultrasound • Eg. Cricket [2,3] and Active Bat [4] • Advantage • Higher accuracy • Disadvantage • Requires of accurate synchronization of the sensor nodes • Requires line-of-sight exposure • Requires careful orientation of the receivers

  8. Indoor Localization based on RF • Eg. RADAR[5] • Advantage • No additional hardware is required except for the sensor nodes • Low power, inexpensive, easy to deploy • Disadvantage • Signal strength are generally unstable • Vary over time • Affected by other factors (building structure, people moving around …

  9. RF Indoor localization -triangulation • Model signal propagation together with current RSSI to triangulate the position of a sensor node • advantage • No requirement of pre-setup database • disadvantage • Requires detailed models of RF propagation • Does not account for variations in receiver sensitivity and orientation

  10. RF Indoor localization -fingerprinting • Use empirical measurements of RSSI to set up a database and together with current RSSI to estimate the position of a sensor node • advantage • No need for detailed models of RF propagation • disadvantage • An offline calibration to set up the database is required

  11. MoteTrack Overview

  12. Two Phases of Estimate • Offline collection of reference signatures • Reference signature format? • Online location estimation

  13. Online location estimation • Estimation steps • I, Compute the signature distances • II, Option 1, take the centroid of the geographic location of the k nearest reference signatures (weighting with the signature distances). • II, Take the centroid of the geographic location of the nearest reference within some ratio(weighting with the signature distances). (NOTE:C is constant, gained from experiment 1.1~1.2 works well)

  14. Robust Design • Definition of robustness • Graceful degradation in location accuracy as base stations fail • Resiliency to information loss (poor antenna orientation) • Work well with perturbations in RF (people moving around, movement of furniture, opening or closing of doors, solar radiation …) • No single point of failure (no central server)

  15. Robust Design • Challenges • For decentralization consideration, beacon nodes should perform localization estimation, which leads to questions about the required resources and cost of the base stations to be answered. • In order for the technique to be resilient to loss of information, the system should be able to detect beacon failure and able to handle it

  16. Robust Design • Methodology • Decentralized location estimation protocol • GOAL: compute the mobile node’s location in a way that only relies upon local communication and at the same time to achieve low communication overhead. • Distributing the reference signature database to beacon nodes • GOAL: ensure balanced distribution of reference signatures (improve robustness) while attempting to assign reference signatures to their closest beacon nodes (guarantee accuracy) • Adaptive signature distance metric • GOAL: handle beacon failures

  17. Decentralized location estimation protocol TRY_1: k beacon nodes send their reference signature slice • mobile node acquires its signature s by listening to beacon nodes • mobile node broadcasts a request for reference signatures and gathers the slices of the reference database from k nearby beacon nodes • The mobile node then computes its location using the received reference signatures Advantage very accurate Disadvantage requires a great deal of communication overhead Alternative: contacting n<k nearby beacon nodes and ask each one only send m reference signatures that are closest to s

  18. Decentralized location estimation protocol TRY_2: k beacon nodes send their location estimate • mobile node acquires its signature s by listening to beacon nodes • mobile node broadcasts its signature s to k nearby beacons • the beacon node then computes the mobile node’s location estimate and sends it back • mobile node receives K estimate and compute the final estimate with these values (“centroid of centroids”) Advantage less communication overhead Disadvantage does not produce accurate location estimates

  19. Decentralized location estimation protocol FINAL-SOLUTION: Max-RSSI beacon node sends its location estimate • mobile node acquires its signature s by listening to beacon nodes • mobile node broadcasts its signature s to the beason with the strongest RSSI • the beacon node computes the mobile node’s location estimate and sends it back Advantage • less communication overhead • as long as the beacon stores an appropriate slice of reference signature database, this should produce very accurate results

  20. Decentralized location estimation protocol FINAL-SOLUTION: Max-RSSI beacon node sends its location estimate • mobile node acquires its signature s by listening to beacon nodes • mobile node broadcasts its signature s to the beason with the strongest RSSI • the beacon node computes the mobile node’s location estimate and sends it back Advantage • less communication overhead • as long as the beacon stores an appropriate slice of reference signature database, this should produce very accurate results

  21. Distributing the reference signature database to beacon nodes • Greedy distribution algorithm • maxRefSigs specifies the maximum signatures each beacon node will store • For each reference signature, the beacon accepts and stores it if: • The current reference signature num is less than maxRefSigs • The new reference signature contains a higher RSSI (average) value than one of the stored signature Advantage: simplicity and no requirement for global knowledge or coordination between nodes Disvantage: some reference signatures may be stored many times with some other not stored at all

  22. Adaptive signature distance metric • Greedy distribution algorithm • Always stores the reference signature with the strongest RSSI to the beacon node. Advantage: simplicity and no requirement for global knowledge or coordination between nodes Disvantage: some reference signatures may be stored many times with some other not stored at all

  23. Distributing the reference signature database to beacon nodes • Balanced distribution algorithm • Variant of a stable marriage algorithm refer to “algorithm design” Jon Kleinberg for details Advantage ensure balanced distribution of reference signatures while attempting to assign reference signatures to their closest beacon nodes Disadvantage requires global knowledge of all reference signature and beacon node pairings individually update of beacon nodes is impossible Note:both of those two algorithms are implemented and examined in this paper

  24. Adaptive signature distance metric • Bidirectional signature distance metric Indicates mobile node’s signature is taken at a different place rather than place of reference node r Indicates either mobile node’s signature is taken at a different place or beacon nodes failure Note: Bidirectional signature distance metric put a penalty on both distance and nodes failure. is gained from experiments 0.95~1.0

  25. Adaptive signature distance metric • Unidirectional signature distance metric Note: unidirectional signature distance metric only penalizes distance Eg.

  26. Adaptive signature distance metric • Scheme:dynamically switches between the unidirectional and bidirectional metrics based on the fraction of local beacon nodes failure. • When few beacon nodes fail, bidirectional distance metric achieves greater accuracy • When a lot beacon nodes fail, unidirectional distance metric achieves greater accuracy (only operational nodes are considered) Beacon nodes failure are determined dynamically by beacons periodically measure their local neighborhood.

  27. Adaptive signature distance metric

  28. Implementation • MoteTrack is implemented on the Mica2 mote platform using TinyOS operating system • 20 beacon nodes are deployed at Hard University’s CS building measuring 1742 m2, with 412 m2 hallway area and 1330 m2 in room area. • 482 reference signatures are measured, each with 7 power levels

  29. Implementation

  30. Evaluation • Location estimation protocols Employed protocol; Maintains Similar Accuracy While Achieve Very low Communication overhead

  31. Evaluation • Selection of reference signatures

  32. Evaluation • Distribution of the reference signature database

  33. Evaluation • Transmission of beacons at multiple power levels

  34. Evaluation • Density of beacon nodes

  35. Evaluation • Density of reference signatures

  36. Evaluation • Robustness to perturbed signatures

  37. Evaluation • Time of day and different motes

  38. Evaluation • Hallways, rooms, and door position

  39. Evaluation • Robustness to beacon node failure

  40. Novelty • Decentralized location estimation protocol • Distribution of partial reference signature database to beacon nodes • Dynamic adapt to nodes failure through employing different distance metric • Employ multiple power levels

  41. Drawbacks • The beacons have to be installed and the database be set up before the scheme could be used • Tricky Point: the system actually employs more beacons than needed to achieve the same accuracy and also stores redundancy information However, this enables it to handle with beacon nodes failure and achieve robustness

  42. Relationship with our Project

  43. References [1] A. Smailagic, J. Small, and D. P. Siewiorek. “Determining User Location For Context Aware Computing Through the Use of a Wireless LAN infrastructure.” December 2000. [2]N. B. Priyantha, A. Miu, H. Balakrishnan, and S. Teller. “The Cricket Compass for Context-Aware Mobile Applications.” In Proc. 7th ACM MobiCom, July 2001. [3] S. Ray, D. Starobinski, A. Trachtenberg, and R. Ungrangsi. “Robust Location Detection with Sensor Networks.”IEEE JSAC, 22(6), August 2004. [4] G. Slack. “Smart Helmets Could Bring Firefighters Back Alive.”FOREFRONT, 2003. Engineering Public Affairs Office, Berkeley. [5] P. Bahl and V. Padmanabhan, "RADAR: An In-Building RF-Based User Location and Tracking System,“ Proc. IEEE Infocom 2000, IEEE CS Press

  44. Pseudo code for greedy algorithm foreach (BN in allBNs) { foreach (refSig in allRefSigs) { if (BN.size < maxNbrRefSigs) BN.assign(refSig) else if (refSig.RSSIValFromBN(BN) > BN.minRSSI) BN.remove(BN.minRSSI) BN.assign(refSig) } } Pseudo code for balanced algorithm Invariants ---------- (1) no refSig is assigned more than one additional time from any other refSig (i.e., every refSig has to be assigned at least once before a refSig can be assigned a second time) (2) no BN is assigned a refSig more than one additional time from any other BN Algorithm --------- L <= construct a list of all <BN,refSig> pairs and sort them by distance between BN and refSig while (there are more elements to assign) { if (possible to assign the next pair from L such that no invariant is violated) make assignment else { // resolve deadlock b <= next BN from L that has been assigned a refSig the least number of times r <= next refSig from L that has been assigned to a BN the least number of times pair <b,r> // note: this violates an invariant while (an invariant is violated) // backtrack swap r with the previously assigned refSig } } Appendix

  45. End Thanks ! Questions?

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