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Real-Time Navigation for Autonomous Surface Vehicles In Ice-Covered Waters

Published 22 Feb 2023 in cs.RO | (2302.11601v2)

Abstract: Vessel transit in ice-covered waters poses unique challenges in safe and efficient motion planning. When the concentration of ice is high, it may not be possible to find collision-free trajectories. Instead, ice can be pushed out of the way if it is small or if contact occurs near the edge of the ice. In this work, we propose a real-time navigation framework that minimizes collisions with ice and distance travelled by the vessel. We exploit a lattice-based planner with a cost that captures the ship interaction with ice. To address the dynamic nature of the environment, we plan motion in a receding horizon manner based on updated vessel and ice state information. Further, we present a novel planning heuristic for evaluating the cost-to-go, which is applicable to navigation in a channel without a fixed goal location. The performance of our planner is evaluated across several levels of ice concentration both in simulated and in real-world experiments.

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References (30)
  1. K. Bergman, O. Ljungqvist, J. Linder, and D. Axehill, “An optimization-based motion planner for autonomous maneuvering of marine vessels in complex environments,” in IEEE Conference on Decision and Control, 2020, pp. 5283–5290.
  2. Government of Canada, “Ice navigation in Canadian waters,” May 2019. [Online]. Available: https://www.ccg-gcc.gc.ca/publications/icebreaking-deglacage/ice-navigation-glaces/page05-eng.html
  3. F. Goerlandt, J. Montewka, W. Zhang, and P. Kujala, “An analysis of ship escort and convoy operations in ice conditions,” Safety science, vol. 95, pp. 198–209, 2017.
  4. K. Murrant, R. Gash, and J. Mills, “Dynamic path following in ice-covered waters with an autonomous surface ship model,” in IEEE OCEANS, San Diego–Porto, 2021, pp. 1–4.
  5. H.-T. L. Chiang and L. Tapia, “COLREG-RRT: An RRT-based COLREGS-compliant motion planner for surface vehicle navigation,” IEEE Robotics & Automation Letters, vol. 3, no. 3, pp. 2024–2031, 2018.
  6. T. Shan, W. Wang, B. Englot, C. Ratti, and D. Rus, “A receding horizon multi-objective planner for autonomous surface vehicles in urban waterways,” in IEEE Conference on Decision and Control, 2020, pp. 4085–4092.
  7. M. Choi, H. Chung, H. Yamaguchi, and K. Nagakawa, “Arctic sea route path planning based on an uncertain ice prediction model,” Cold Regions Science and Technology, vol. 109, pp. 61–69, 2015.
  8. V. Aksakalli, D. Oz, A. F. Alkaya, and V. Aydogdu, “Optimal naval path planning in ice-covered waters,” International Journal of Maritime Engineering, vol. 159, no. A1, 2017.
  9. M. Pivtoraiko, R. A. Knepper, and A. Kelly, “Differentially constrained mobile robot motion planning in state lattices,” Journal of Field Robotics, vol. 26, no. 3, pp. 308–333, 2009.
  10. C. Daley, S. Alawneh, D. Peters, and B. Colbourne, “GPU-event-mechanics evaluation of ice impact load statistics,” in OTC Arctic Technology Conference, 2014.
  11. M. Stilman and J. Kuffner, “Planning among movable obstacles with artificial constraints,” The International Journal of Robotics Research, vol. 27, no. 11-12, pp. 1295–1307, Nov. 2008.
  12. Hai-Ning Wu, M. Levihn, and M. Stilman, “Navigation among movable obstacles in unknown environments,” in IEEE/RSJ International Conference on Intelligent Robots and Systems, Taipei, Oct. 2010, pp. 1433–1438.
  13. J.-y. Zhuang, Y.-m. Su, Y.-l. Liao, and H.-b. Sun, “Motion planning of usv based on marine rules,” Procedia Engineering, vol. 15, pp. 269–276, 2011.
  14. Y. Kuwata, M. T. Wolf, D. Zarzhitsky, and T. L. Huntsberger, “Safe maritime autonomous navigation with COLREGS, using velocity obstacles,” IEEE Journal of Oceanic Engineering, vol. 39, no. 1, pp. 110–119, 2013.
  15. T.-H. Hsieh, S. Wang, H. Gong, W. Liu, and N. Xu, “Sea ice warning visualization and path planning for ice navigation based on radar image recognition,” Journal of Marine Science and Technology, vol. 29, no. 3, pp. 280–290, 2021.
  16. R. M. Gash, K. A. Murrant, J. W. Mills, and D. E. Millan, “Machine vision techniques for situational awareness and path planning in model test basin ice-covered waters,” in IEEE Global Oceans, 2020, pp. 1–8.
  17. H. Kim, D. Kim, J.-U. Shin, H. Kim, and H. Myung, “Angular rate-constrained path planning algorithm for unmanned surface vehicles,” Ocean Engineering, vol. 84, pp. 37–44, 2014.
  18. X. Liang, P. Jiang, and H. Zhu, “Path planning for unmanned surface vehicle with Dubins curve based on GA,” in IEEE Chinese Automation Congress, 2020, pp. 5149–5154.
  19. J.-B. Caillau, S. Maslovskaya, T. Mensch, T. Moulinier, and J.-B. Pomet, “Zermelo-Markov-Dubins problem and extensions in marine navigation,” in IEEE Conference on Decision and Control, 2019, pp. 517–522.
  20. L. E. Dubins, “On curves of minimal length with a constraint on average curvature, and with prescribed initial and terminal positions and tangents,” American Journal of Mathematics, vol. 79, no. 3, pp. 497–516, 1957.
  21. A. Botros and S. L. Smith, “Multi-start n-dimensional lattice planning with optimal motion primitives,” arXiv preprint arXiv:2107.11467, 2021.
  22. P. E. Hart, N. J. Nilsson, and B. Raphael, “A formal basis for the heuristic determination of minimum cost paths,” IEEE Transactions on Systems Science and Cybernetics, vol. 4, no. 2, pp. 100–107, 1968.
  23. Government of Canada, “Ice glossary,” Nov 2020. [Online]. Available: https://www.canada.ca/en/environment-climate-change/services/ice-forecasts-observations/latest-conditions/glossary.html
  24. Y. N. Popov, O. Faddeev, D. Kheisin, and A. Yakovlev, “Strength of ships sailing in ice,” Army Foreign Science and Technology Center Charlottesville Va, Tech. Rep., 1969.
  25. C. Daley, “Energy based ice collision forces,” in International Conference on Port and Ocean Engineering under Arctic Conditions, vol. 2, 1999, pp. 674–686.
  26. X.-N. Bui, J.-D. Boissonnat, P. Soueres, and J.-P. Laumond, “Shortest path synthesis for Dubins non-holonomic robot,” in IEEE International Conference on Robotics and Automation, 1994, pp. 2–7.
  27. X. Ma and D. A. Castanon, “Receding horizon planning for Dubins traveling salesman problems,” in IEEE Conference on Decision and Control, 2006, pp. 5453–5458.
  28. H. Ahani, M. Familian, and R. Ashtari, “Optimum design of a dynamic positioning controller for an offshore vessel,” Journal of Soft Computing and Decision Support Systems, vol. 7, no. 1, pp. 13–18, 2020.
  29. M. Mehrzadi, Y. Terriche, C.-L. Su, M. B. Othman, J. C. Vasquez, and J. M. Guerrero, “Review of dynamic positioning control in maritime microgrid systems,” Energies, vol. 13, no. 12, p. 3188, 2020.
  30. V. Blomqvist, “Pymunk: A easy-to-use pythonic rigid body 2d physics library (version 6.2.1),” 2007. [Online]. Available: https://www.pymunk.org
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