Configuration optimization of supercavitating underwater vehicles with maneuvering constraints

IEEE Journal of Oceanic Engineering

Volumn 35, Issue 3, 2010, Pages 647-662

  Ahn, Seong Sik ^a   Ruzzene, Massimo ^b   Scorcelletti, Francesco ^c   Bottasso, Carlo L ^c  

^a SAMSUNG Electronics   (South Korea)

^b Georgia Institute of Technology   (United States)

^c POLITECNICO DI MILANO   (Italy)

Author keywords

Design methodology; marine vehicles; optimal control; optimization methods

Indexed keywords

CONFIGURATION OPTIMIZATION; DESIGN METHODOLOGY; DESIGN PROCESS; DYNAMIC BEHAVIORS; GUIDANCE AND CONTROL; HIGHLY NONLINEAR; INTEGRATED DESIGN TOOLS; LIMITED SPECTRUM; MARINE VEHICLES; MASS DISTRIBUTION; MISSION REQUIREMENTS; OPERATING CONDITION; OPERATIONAL CONSTRAINTS; OPERATIONAL REQUIREMENTS; OPTIMAL CONTROL PROBLEM; OPTIMAL CONTROLS; OPTIMAL VEHICLES; OPTIMIZATION METHODS; OPTIMIZATION PROBLEMS; SUPERCAVITATING VEHICLES; TIME HISTORY; UNDERWATER VEHICLES; VEHICLE CONFIGURATION; VEHICLE STATE;

CONTROL; DESIGN; MANEUVERABILITY; SUBMERSIBLES; UNDERWATER EQUIPMENT; WATER CRAFT;

OPTIMIZATION;

EID: 77956344453     PISSN: 03649059     EISSN: None     Source Type: Journal    
DOI: 10.1109/JOE.2010.2043576     Document Type: Article

References (39)

1. K. W. Ng, "Overview of the ONR supercavitating high-speed bodies program," in Coll. Tech. Papers-AIAA Guid. Navig. Control Conf., 2006, vol. 5, pp. 3088-3091.
2. D. Hammick, "Darpa study looks into high-speed underwater capability," Jane's Navy Int., no. V, 2006.
3. S. Ashley, "Warp-drive underwater," Sci. Amer., May 2001.
4. D. Miller, "Going to war in a bubble," Int. Defense Rev., 1995.
5. J. Hargrove, "Supercavitation and aerospace technology in the development of high-speed underwater vehicles," in Proc. AIAA Aerosp. Sci. Conf., Reno, NV, 2004, pp. 3547-3555.
6. E. V. Paryshev, "Approximate mathematical models in high-speed hydrodynamics," J. Eng. Math., vol. 55, no. 1-4, pp. 41-64, 2006.
7. V. V. Serebryakov, "Supercavitation for high speed motion in water-Prediction and drag reduction problems," ASME Fluids Eng. Div. (Publication) FED, vol. 257, no. 1 A, pp. 411-417, 2002.
8. X. Wu and G. L. Chahine, "Characterization of the content of the cavity behind a high-speed supercavitating body," J. Fluids Eng./Trans. ASME, vol. 129, no. 2, pp. 136-145, 2007.
9. I. N. Kirschner, N. E. Fine, J. S. Uhlman, D. C. Kring, B. J. Rosenthal, T. A. Gieseke, R. Kuklinski, A. N. Varghese, D. R. Stinebring, J. E. Dzielski, J. W. Lindau, and R. F. Kunz, "Supercavitation research and development," presented at the 4th Int. Symp. Cavitat, Pasadena, CA, June 20-23, 2001.
10. J.-Y. Choi, M. Ruzzene, and O. A. Bauchau, "Dynamic analysis of flexible supercavitating vehicles using modal-based elements," Simul. -Trans. Soc. Model. Simul. Int., vol. 80, no. 11, pp. 619-633, 2004.
11. M. Ruzzene and F. Soranna, "Impact dynamics of stiffened elastic supercavitating underwater vehicles," J. Vib. Control, vol. 10, no. 2, pp. 243-267, 2004.
12. J. Dzielski and A. Kurdila, "A benchmark control problem for supercavitating vehicles and an initial investigation of solutions," J. Vib. Control, vol. 9, pp. 791-804, 2003.
13. I. N. Kirschner, D. C. Kring, A. W. Stokes, N. E. Fine, J. James, and S. Uhlman, "Control strategies for supercavitating vehicles," J. Vib. Control, vol. 8, pp. 219-242, 2002.
14. M. Howe, A. Colgan, and T. Brungart, "On self-noise at the nose of a supercavitating vehicle," J. Sound Vib., vol. 322, no. 4-5, pp. 772-784, 2009.
15. B. Vanek, J. Bokor, G. J. Balas, and R. E. Arndt, "Longitudinal motion control of a high-speed supercavitation vehicle," J. Vib. Control, vol. 13, no. 2, pp. 159-184, 2007.
16. M. Wang, G. Zhao, and J. Li, "Robust controller design for supercavitating vehicles based on BTT maneuvering strategy," in Proc. IEEE Int. Conf. Mechatron. Autom., Harbin, China, 2007, pp. 227-231.
17. W. Yang, Y. Zhang, L. Kan, and H. Fan, "Experimental investigation to supercavitation flow with ventilated method," Yingyong Lixue Xuebao/ Chin. J. Appl. Mech., vol. 24, no. 4, pp. 504-508, 2007.
18. G. Lin, B. Balachandran, and E. H. Abed, "Dynamics and control of supercavitating vehicles," J. Dyn. Syst. Meas. Control/Trans. ASME, vol. 130, no. 2, pp. 0210031-02100311, 2008.
19. V. Nguyen, B. Balachandran, and A. N. Varghese, "Supercavitating vehicle dynamics with non-cylindrical, non-symmetric cavities," in Proc. ASME Int. Mech. Eng. Congr. Expo., Seattle, WA, 2008, vol. 9, pp. 265-272, part A.
20. R. Shafaghat, S. Hosseinalipour,N. Nouri, and I. Lashgari, "Shape optimization of two-dimensional cavitators in supercavitating flows, using NSGA II algorithm," Appl. Ocean Res., vol. 30, no. 4, pp. 305-310, 2008.
21. I. N. Kirschner, N. E. Fine, J. James, S. Uhlman, and D. C. Kring, "Numerical modeling of supercavitating flows," in RTO AVT Lecture Series on Supercavitating Flows. Brussels, Belgium: Von Karman Institute, Feb. 2001.
22. A. N. Varghese, J. S. Uhlman, and I. N. Kirschner, "Numerical analysis of high-speed bodies in partially cavitating axisymmetric flow," J. Fluids Eng./Trans. ASME, vol. 127, no. 1, pp. 41-54, 2005.
23. G. Lin, B. Balachandran, and E. H. Abed, "Nonlinear dynamics and bifurcations of a supercavitating vehicle," IEEE J. Ocean. Eng., vol. 32, no. 4, pp. 753-761, Oct. 2007.
24. B. Vanek, J. Bokor, and G. Balas, "High-speed supercavitation vehicle control," in Coll. Tech. Papers-AIAA Guid. Navig. Control Conf., Keystone, CO, 2006, vol. 5, pp. 3165-3172.
25. F. Scorcelletti, C. L. Bottasso, and M. Ruzzene, "Multiple shooting solution of optimal control problems for time-delayed dynamic systems," ASME J. Syst. Dyn. Controls, vol. 131, 2009, 011009.
26. R. Kamada, M. Ruzzene, C. Bottasso, and F. Scorcelletti, "Trajectory optimization strategies for supercavitating underwater vehicles," J. Vib. Control, vol. 14, no. 5, pp. 611-644, 2008.
27. T. Kiceniuk, "An experimental study of the hydrodynamic forces acting on a family of cavity producing conical bodies of revolution inclined to the flow," California Inst. Technol., Pasadena, CA, CIT Hydrodyn. Rep. E-12.17, 1954.
28. A. May, "Water entry and the cavity-running behavior of missiles," Naval Surface Weapons Cntr., White Oak Lab., Silver Spring, MD, SEAHAC Tech. Rep. 75-2, 1975.
29. S. E. Hassan, "Analysis of hydrodynamic planing forces associated with cavity riding vehicles," Personal Communication, 2004.
30. G. V. Logvinovich, "Hydrodynamics of free-boundary flow," U.S. Dept. Commerce, Washington, DC, Tech. Rep., 1972.
31. J. Arthur, E. Bryson, and Y.-C. Ho, Applied Optimal Control. New York: Hemisphere, 1975, ch. 7.
32. J. T. Betts, Practical Methods for Optimal Control Using Non-Linear Programming. Philadelphia, PA: SIAM, 2001, ch. 4.
33. A. Barclay, P. E. Gill, and J. B. Rosen, "SQP methods and their application to numerical optimal control," Dept. Math., Univ. California, San Diego, CA, Rep. NA 97-3, 1997.
34. J. Renegar, A Mathematical View of Interior Point Methods in Convex Optimization. Philadelphia, PA: SIAM, 2001, ch. 1.
35. E. L. Fleeman, Tactical Missile Design, ser. Education. Reston, VA: AIAA, 2001, ch. 5.
36. M. Asselin, An Introduction to Aircraft Performance, ser. Education. Reston, VA: AIAA, 1997, ch. 3.
37. W. T. Thomson, Introduction to Space Dynamics, 2nd ed. New York: Dover, 1986, ch. 7.
38. P. G. Hill and C. R. Peterson, Mechanics and Thermodynamics of Propulsion, 2nd ed. Reading, MA: Addison-Wesley, 1992, ch. 2.
39. S. S. Ahn, "An integrated approach to the design of supercavitating underwater vehicles," Ph.D. dissertation, Schl. Aerosp. Eng., Georgia Inst. Technol., Atlanta, GA, 2007.