1 / 26

Underwater Localization with Time-Synchronization and Propagation Speed Uncertainties

Underwater Localization with Time-Synchronization and Propagation Speed Uncertainties . Roee Diamant, Lutz Lampe. Outline. Brief overview on underwater communication Localization in the underwater acoustic channel Suggested localization protocol Future work. Motivations.

adamma
Download Presentation

Underwater Localization with Time-Synchronization and Propagation Speed Uncertainties

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Underwater Localization with Time-Synchronization and Propagation Speed Uncertainties Roee Diamant, Lutz Lampe

  2. Outline • Brief overview on underwater communication • Localization in the underwater acoustic channel • Suggested localization protocol • Future work

  3. Motivations • Most underwater activities require underwater communications [1] • Cables are heavy, deployment is expensive. Solution: wireless information transmission through the ocean • Wireless communication: • Radio (30Hz-300Hz, very high attenuation)‏ • Optical (short distances, pointing precision)‏ • Large body of relevant applications [2]: • Ocean exploration • warning systems, pollution control • Military underwater surveillance • Underwater oil exploration

  4. Challenges of UWAC • Fast time-varying frequency-selective channel • Large Doppler shift and Doppler spread • Power attenuation increase with frequency • Ambient noise decreases with frequency • Half duplex communication • Slow propagation speed [3] Limited signal bandwidth

  5. Example of measured channel responses Sea trial

  6. Character RF UWAC Effect Propagation delay T low throughput Transmission rate ~1MB ~1Kb Errorprobabilities ~10-7 ~10^-4 Low reliability SNR high low Substantial multiple access interference Challenges of UWAC ~10^5 T

  7. Localization in UWAC Networks : • GPS is only used by surface nodes [4] • Accurate attenuation models are hard to find [3] • Propagation speed is an unknown parameter [5] • Network nodes are not time-synchronized • Nodes permanently move in the channel Joint time-synchronization and location estimation where the propagation speed is an unknown variable

  8. Outline • Brief overview on underwater communication • Localization in the underwater acoustic channel • Suggested localization protocol • Future work

  9. System Model • Network of L anchor nodes at known time-varying locations • At least one unlocalized node at time-varying location • Nodes are not time-synchronized such that • Unlocalized node has INS system to self evaluate its location • Self-evaluated locations are not accurate but are used to accurately measure movements for a short period of time Anchor node index Location index Location index Node’s m time Offset Node’s l time Skew

  10. System Model (2) • Propagation delay is where is the unknown propagation speed within • The objective is to estimate at the end of a localization window with duration

  11. Available Measurements Anchor node Unlocalized node time We assume that time-of-arrival (ToA) measurements are affected by i.i.d white Gaussian noise

  12. Problem Formulation Given

  13. Time-Synchronization Followed by Localization • Eq. (1) and (2) can be rearranged in a matrix form where depend on the skew and offset of the unlocalized node relative to the anchor node • Using separate LS estimators we estimate the clock skew and offset of the unlocalized node relative to all anchor nodes • Next, we obtain the propagation delay at all points,

  14. Localization • Motion vectors can be represented as • We get the following Eq.

  15. Localization (2) • Using simple manipulation we represent the localization problem in the matrix form where depends on the elements of • Following [6], we use the rough estimator to construct vector and its covariance matrix, • Next, we refine the rough estimator to get a weighted LS estimator

  16. Localization (3) • Finally, we represent the inner connection between the variables of (related by the motion vectors) in to estimate • Refinement step: use to construct Then, is used instead of the rough LS estimator

  17. Flow Chart Online measurements : ToA and INS Initial processing: ToA noise mitigation, motion vectors Time synchronization for each anchor: Estimate skew and offset Estimate propagation delay Localization: Rough LS estimator Construct error covariance matrix WLS estimator Utilize inner connection, WLS estimator Iterative refinement

  18. Simulation Results • Simulations were performed using 2 anchor nodes and an unlocalized node, moving at random speed and directions • To simulate errors, we added i.i.dGuassian noise to ToA measurements, and motion vectors • Anchor nodes offset and skew where generated as i.i.dGuassian noise • Results were compared to the simple multileteration method and a benchmark method (joint protocol) [6]. Reference methods are given nominal propagation speed of 1500m/sec

  19. Localization Simulation Results All nodes time-synchronized Sound speed known All nodes are time-synchronized Sound speed is unknown

  20. Localization Simulation Results (2) All nodes not time-synchronized, sound speed is unknown

  21. Trial Sea

  22. Sea Trial • Four vessels: three anchors and one unlocalized node, each deployed transceiver at 10m depth • Vessels moved freely with ocean current • Achieved localization accuracy ~10m (compared with GPS positioning of the vessels)

  23. Summary and future work • We suggested a heuristic algorithm for UWAL • The algorithm compensates time-synchronization and sound-speed uncertainties • Extension of this work will include formalization of the Cramér–Raobound for the considered problem, propagation speed estimation using localization and results from the sea trial • Follow-up research will be continuous tracking of already localized nodes

  24. Bibliography [1]M.Chitre, S.Shahabodeen, and M.Stojanovic, “Underwater acoustic communications and networking: Recent advances and future challenges,” in Marine Technology Society Journal, vol. 42, no. 1,2008, pp.103–116 [2] W. Burdic, Underwater Acoustic System Analysis. Los Altos, CA, USA: Peninsula Publishing, 2002. [3] Stojanovic and J. G. Proakis, Acoustic (underwater) Communications in Encyclopedia of Telecommunications. Hoboken, NJ, USA: John Wiley and Sons, 2003 [4] Lee, P. Lee, S. Hong, and S. Kim, “Underwater navigation system based on inertial sensor and doppler velocity log using indirect feedback kalman filter,” in Journal of Offshore and Polar Engineering, vol. 15, no. 2, jun 2005, pp. 88–95 [5] Tan, R. Diamant, W. Seah, and M. Waldmeyer, “A survey of techniques and challenges in underwater localization,” Accepted for Publication in the ACM Journal of Ocean Engineering [6] J. Zheng and Y. Wu, “Localization and time synchronization in wireless sensor networks: A unified approach,” in IEEE Asia Pacific Conf. on Circuits and Sys., Macao, China, Nov. 2008 [7] S. Kay, Fundamentals of Statistical Signal Processing: Estimation Theory. Englewood Cliffs, NJ: Prentice-Hall, 1993.

  25. Thank you! Questions? Roee Diamant, Lutz Lampe roeed@ece.ubc.ca

More Related