Abstract
Hybrid-driven underwater glider is a new type of unmanned underwater vehicle, which combines the advantages of autonomous underwater vehicles and traditional underwater gliders. The autonomous underwater vehicles have good maneuverability and can travel with a high speed, while the traditional underwater gliders are highlighted by low power consumption, long voyage, long endurance and good stealth characteristics. The hybrid-driven underwater gliders can realize variable motion profiles by their own buoyancy-driven and propeller propulsion systems. Stability of the mechanical system determines the performance of the system. In this paper, the Petrel-II hybrid-driven underwater glider developed by Tianjin University is selected as the research object and the stability of hybrid-driven underwater glider unitedly controlled by buoyancy and propeller has been targeted and evidenced. The dimensionless equations of the hybrid-driven underwater glider are obtained when the propeller is working. Then, the steady speed and steady glide path angle under steady-state motion have also been achieved. The steady-state operating conditions can be calculated when the hybrid-driven underwater glider reaches the desired steady-state motion. And the steadystate operating conditions are relatively conservative at the lower bound of the velocity range compared with the range of the velocity derived from the method of the composite Lyapunov function. By calculating the hydrodynamic coefficients of the Petrel-II hybrid-driven underwater glider, the simulation analysis has been conducted. In addition, the results of the field trials conducted in the South China Sea and the Danjiangkou Reservoir of China have been presented to illustrate the validity of the analysis and simulation, and to show the feasibility of the method of the composite Lyapunov function which verifies the stability of the Petrel-II hybrid-driven underwater glider.
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References
Alvarez, A., Caffaz, A., Caiti, A., Casalino, G., Gualdesi, L., Turetta, A. and Viviani, R., 2009. Folaga: A low-cost autonomous underwater vehicle combining glider and AUV capabilities, Ocean Engineering, 36(1), 24–38.
Bhatta, P. and Leonard, N.E., 2004. A Lyapunov function for vehicles with lift and drag: Stability of gliding, Proceedings of the 43rd IEEE Conference on Decision and Control, IEEE, Nassau, pp. 4101–4106.
Bhatta, P., 2006. Nonlinear Stability and Control of Gliding Vehicles, Ph. D. Thesis, Princeton University.
Bhatta, P. and Leonard, N.E., 2008. Nonlinear gliding stability and control for vehicles with hydrodynamic forcing, Automatic, 44(5), 1240–1250.
Caffaz, A., Caiti, A., Casalino, G. and Turetta, A., 2010. The hybrid glider/AUV Folaga, IEEE Robotics & Automation Magazine, 17(1), 31–44.
Caiti, A. and Calabro, V., 2010. Control-oriented modelling of a hybrid AUV, Proceedings of 2010 IEEE International Conference on Robotics and Automation (ICRA), IEEE, Anchorage, pp. 5275–5280.
Chen, Z.E., Yu, J.C., Zhang, A.Q., Yi, R. and Zhang, Q.F., 2013. Folding propeller design and analysis for a hybrid driven underwater glider, Proceedings of 2013 OCEANS, IEEE, San Diego, pp. 1–9.
Chen, Z.E., Yu, J.C., Zhang A.Q. and Song, S.M., 2015. Control system for long-range survey hybrid-driven underwater glider, Proceedings of 2015 OCEANS, IEEE, Genova, pp. 1–6.
Eriksen, C.C., Osse, T.J., Light, R.D. Wen, T., Lehman, T.W., Sabin, P.L., Ballard, J.W. and Chiodi, A.M., 2001. Seaglider: A long-range autonomous underwater vehicle for oceanographic research, IEEE Journal of Oceanic Engineering, 26(4), 424–436.
Fan, S.S., Wolek, A. and Woolsey, C.A., 2012. Stability and performance of underwater gliders, Proceedings of 2012 OCEANS, IEEE, Hampton, pp.1–10.
Graver, J.G., 2005. Underwater Gliders: Dynamics, Control and Design, Ph. D. Thesis, Princeton University, New Jersey, USA.
Isa, K. and Arshad, M. R., 2012. Neural networks control of hybriddriven underwater glider, Proceedings of 2012 OCEANS, IEEE, Yeosu, pp. 1–7.
Isa, K. and Arshad, M.R., 2013. An analysis of homeostatic motion control system for a hybrid-driven underwater glider, Proceedings of 2013 IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM), IEEE, Wollongong, pp. 1570–1575.
Isa, K., Arshad, M.R. and Ishak, S., 2014. A hybrid-driven underwater glider model. hydrodynamics estimation, and analysis of the motion control, Ocean Engineering, 81(2), 111–129.
Jenkins, S.A., Humphreys, D.E., Sherman, J., Osse, J., Jones, C., Leonard, N., Graver, J., Bachmayer, R., Clem, T., Carroll, P., Davis, P., Berry, J., Worley, P. and Wasyl, J., 2003. Underwater Glider System Study, Technical Report No. 53, Scripps Institution of Oceanography, University of California, San Diego, CA, 97–225.
Khalil, H.K., 1987. Stability analysis of nonlinear multiparameter singularly perturbed systems, Proceedings of 1987 American Control Conference, IEEE, Minneapolis, pp. 1219–1223.
Khalil, H.K. and Grizzle, J.W., 1996. Nonlinear Systems, Prentice hall, New Jersey, pp. 423–449.
Leonard, N.E. and Marsden, J.E., 1997. Stability and drift of underwater vehicle dynamics: Mechanical systems with rigid motion symmetry, Physica D: Nonlinear Phenomena, 105(1–3), 130–162.
Leonard, N.E., 1997a. Stability of a bottom-heavy underwater vehicle, Automatica, 33(3), 331–346.
Leonard, N.E., 1997b. Stabilization of underwater vehicle dynamics with symmetry-breaking potentials, Systems & Control Letters, 32(1), 35–42.
Leonard, N.E. and Graver J.G., 2001. Model-based feedback control of autonomous underwater gliders, IEEE Journal of Oceanic Engineering, 26(4), 633–645.
Liu, F., 2014. System Design and Motion Behaviors Analysis of the Hybrid Underwater Glider, Ph. D. Thesis, Tianjin University, Tianjin. (in Chinese)
Niu, W.D., Wang, Y.H., Yang, Y.P., Zhu, Y.Q. and Wang, S.X., 2016. Hydrodynamic parameter identification of hybrid-driven underwater glider, Chinese Journal of Theoretical and Applied Mechanics, 48(4), 813–822. (in Chinese)
Sherman, J., Davis, R.E., Owens, W.B. and Valdes, J., 2001. The autonomous underwater glider “Spray”, IEEE Journal of Oceanic Engineering, 26(4), 437–446.
Wang, C.F., Zhang, F.M. and Schaefer, D., 2015. Dynamic modeling of an autonomous underwater vehicle, Journal of Marine Science and Technology, 20(2), 199–212.
Wang, T., 2012. Research of Efficient Thruster of Deep Sea Unmanned Submersible, Ph. D. Thesis, Harbin Engineering University, Harbin. (in Chinese)
Webb, D.C., Simonetti, P.J. and Jones, C.P., 2001. SLOCUM: An underwater glider propelled by environmental energy, IEEE Journal of Oceanic Engineering, 126(4), 447–452.
Woolsey, C.A. and Leonard, N.E., 2002. Stabilizing underwater vehicle motion using internal rotors, Automatica, 38(12), 2053–2062.
Zhao, B., Wang, X., Yao, B. and Lian, L., 2015. Lyapunov stability analysis of the underwater glider, Journal of Harbin Engineering University, 36(1), 83–87. (in Chinese)
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Foundation item: This work was financially supported by the National Natural Science Foundation of China (Grant Nos. 51475319 and 51722508), the National Key R&D Plan (Grant No. 2016YFC0301100), and Aoshan Talents Program of Qingdao National Laboratory for Marine Science and Technology.
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Niu, Wd., Wang, Sx., Wang, Yh. et al. Stability analysis of hybrid-driven underwater glider. China Ocean Eng 31, 528–538 (2017). https://doi.org/10.1007/s13344-017-0061-y
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DOI: https://doi.org/10.1007/s13344-017-0061-y