TRACKING AND MAPPING SYSTEM FOR AN UNDERWATER VEHICLE IN REAL POSITION USING SONAR SYSTEM

Ali Jebelli,∗ Hicham Chaoui,∗ Arezoo Mahabadi,∗∗ and Balbir Dhillon∗∗∗

References

  1. [1] [1] A. Jebelli, M.C.E. Yagoub, and B.S. Dhillon, Using a highspeed mini-PC to control an autonomous underwater vehicle, American Journal of Mechanical Engineering, 7(3), 2019, 116–128.
  2. [2] A. Jebelli, M.C.E. Yagoub, B.S. Dhillon, and N. Lotfi, Effect of low-frequency noise on humpback whale behaviors, Oceanography and Marine Research, 6(4), 2018, 1–5.
  3. [3] G. Wenyang, Z. Daqi, and X.Y. Simon, A speed jumpingfree tracking controller with trajectory planner for unmanned underwater vehicle, International Journal of Robotics and Automation, 35(5), 2020.
  4. [4] A. Selvakumar A. Doss, D. Venkatesh, and M. Ovinis, Simulation and experimental studies of a mobile robot for underwater applications, International Journal of Robotics and Automation, 35, 2020.
  5. [5] A. Jebelli, M.C.E. Yagoub, and B.S. Dhillon, Design and control of a self-balancing autonomous underwater vehicle with vision capabilities, Journal of Marine Science: Research & Development, 8(1), 2018, 1–7.
  6. [6] Z. Daqi, M. Man, and S. Bing, The tracking control of unmanned underwater vehicles based on model predictive control, International Journal of Robotics and Automation, 32(4), 2017.
  7. [7] A. Jebelli, M.C.E. Yagoub, and B.S. Dhillon, Modeling of an autonomous underwater robot with rotating thrusters, Advances in Robotics and Automation, 6(1), 2017, 1–10.
  8. [8] D.A. Schoenwald, AUVs: In space, air, water, and on the ground, IEEE Control Systems Magazine, 20(6), 2000, 15–18.
  9. [9] F. Mandic, I. Rendulic, N. Mikovic, and Nad, Underwater object tracking using sonar and USBL measurements, Journal of Sensors, special issue, 2016, 1–10.
  10. [10] D.C. Brown, S.F. Johnson, I.D. Gerg, and C.F. Brownstead, Simulation and testing results for a sub-bottom imaging sonar. Proceedings of Meetings on Acoustics, 36(1), 2019, 070001.
  11. [11] T. Zhang, S. Liu, X. He, H. Huang, and K. Hao, Underwater target tracking using forward-looking sonar for autonomous underwater vehicles, Sensors, 20(1), 2020, 102.
  12. [12] J. Folkesson, J. Leonard, J. Leederkerken, and R. Williams, Feature tracking for underwater navigation using sonar, 2007 IEEE/RSJ International Conference on Intelligent Robots and System, San Diego, CA, 2007, 3678–3684.
  13. [13] P. Jonsson, I. Sillitoe, B. Dushaw, J. Nystuen, and J. Heltne, Observing using sound and light–a short review of underwater acoustic and video-based methods, Ocean Science Discussions, 6(1), 2009, 819–870.
  14. [14] L. Bjørnø, Developments in sonar technologies and their applications, IEEE International Underwater Technology Symposium (UT), Tokyo, Japan, 2013.
  15. [15] R.J. Urick, Principles of underwater sound, 3rd ed. (Peninsula Publishing, Connecticut, USA, 2013).
  16. [16] M.A. Ainslie and J.G. McColm, A simplified formula for viscous and chemical absorption in sea water, The Journal of the Acoustical Society of America, 103(3), 1998, 1671–1672.
  17. [17] K.G. Foote and D.T.I. Francis, Comparing Kirchhoffapproximation and boundary-element models for computing gadoid target strengths, The Journal of the Acoustical Society of America, 111(4), 2002, 1644–1654.
  18. [18] K.V. Mackenzie, Nine-term equation for sound speed in the oceans, The Journal of the Acoustical Society of America, 70(3), 1981, 807–812.
  19. [19] Kuperman, William A., and Philippe Roux, Underwater acoustics, Handbook of Acoustics, (Springer, 2014) 157-212.
  20. [20] H.M. Manik, Seabed identification and characterization using sonar, Advances in Acoustics and Vibration, 2012(1), 2012, 5.
  21. [21] L. Brekhovskikh and Y. Lysanov, Fundamentals of ocean acoustics, Springer Series in Electrophysics (Volume 8), Springer, Berlin, Heidelberg, 1982.
  22. [22] C.M. McKinney and C.D. Anderson, Measurements of backscattering of sound from the ocean bottom, The Journal of the Acoustical Society of America, 36(1), 1964, 158–163.
  23. [23] R.H. Love, Target strength of an individual fish at any aspect, The Journal of the Acoustical Society of America, 62(6), 1977, 1397–1403.
  24. [24] G. Wang, L.K. Wang, and L. Qin, High-frequency underwater transducer, Ferroelectrics, 408(1), 2010, 129–136.
  25. [25] A. Sahoo, S.K. Dwivedy, and P.S. Robi, Advancements in the field of autonomous underwater vehicle, Ocean Engineering, 181, 2019, 145–160.
  26. [26] S. Chutia, N.M. Kakoty, and D. Deka, A review of underwater robotics, navigation, sensing techniques and applications, Proceedings of the Advances in Robotics, Association, New York, 2017, 1–6.
  27. [27] D. Hiranandani, C. White, C. Clark, T. Gambin, and K. Buhagiar, Underwater robots with sonar and smart tether for underground cistern mapping and exploration, 10th International Symposium on Virtual Reality, Archaeology and Cultural Heritage, St. Julians, 2009, 1–5.
  28. [28] L. Paull, S. Saeedi, M. Seto, and H. Li, AUV navigation and localization: A review, IEEE Journal of Oceanic Engineering, 39(1), 2013, 131–149. 10

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