State of the Art Review of the Application of Computational Fluid Dynamics for High Speed Craft

  • H. A. Ahmad School of Ocean Engineering, Universiti Malaysia Terengganu, Terengganu, Malaysia
  • A. F. Ayob School of Ocean Engineering, Universiti Malaysia Terengganu, Terengganu, Malaysia
DOI: http://dx.doi.org/10.36842/jomase.v39i1.391

Abstract

Computational Fluid Dynamics (CFD) field of research continues to advance with several new accomplishments, especially in the field of high speed craft design. This paper presents the application of advanced CFD simulations reported in the literatures in terms of software tools available, hull form optimization, resistance, and seakeeping analysis and propulsion system. It aims to review case studies of several methods utilized to conduct operational simulations that result in useful performance prediction of high speed craft. The simulations reviewed in this paper are referring to the research reported in the literatures over the last decade on patrol boats, catamarans, rescue boats and so on. Some notable analysis were discussed, e.g. resistance and seakeeping analysis, propulsion system, hull form optimization and multi physics We conclude that based on the vast resources available in the literature, CFD is one the best tool for designing high speed craft, however such work could be impacted more by its combination with optimization methods.

##Keywords:## Computational Fluid Dynamics; High Speed Craft; Simulation; Resistance and Seakeeping Analysis.
Published
Jan 30, 2017
How to Cite
AHMAD, H. A.; AYOB, A. F.. State of the Art Review of the Application of Computational Fluid Dynamics for High Speed Craft. Journal of Ocean, Mechanical and Aerospace -science and engineering-, [S.l.], v. 39, n. 1, p. 7 - 17, jan. 2017. ISSN 2527-6085. Available at: <https://isomase.org/Journals/index.php/jomase/article/view/391>. Date accessed: 04 june 2026. doi: http://dx.doi.org/10.36842/jomase.v39i1.391.
Citation Formats
Issue
Vol 39 No 1 (2017): Journal of Ocean, Mechanical and Aerospace -science and engineering- (JOMAse)
Section
Articles

References

1. A. A. Aksenov, A. V. Pechenyuk, and D. Vucinic, "Ship hull form design and optimization based on CFD," presented at the Towards Green Marine Technology and Transport, London, 2015. 2.D. Kuzmin, "Introduction to Computational Fluid Dynamics," ed, 2015.
3. H. Ghassemi, M. Kamarlouei, and S. T. G. Veysi, "A Hydrodynamic Methodology And CFD Analysis For Performance Prediction Of Stepped Planing Hulls," Polish Maritime Research, vol. 22, pp. 23-31, 2015.
4. T. Turner and F. v. Walree, "Validation Studies of the Numerical Tool PANSHIP for Predicting the Calm Water Resistance of the Armidale Class Patrol Boat," M. D. D. S. a. T. Organisation, Ed., ed. Australia: Maritime Research Institute Netherlands, 2015, p. 46.
5. M. Mousaviraad, S. Bhushan, and F. Stern, "CFD Prediction of Free-Running SES/ACV Deep and Shallow Water Maneuvering and Course Keeping in Calm Water and Waves," presented at the International Conference on Marine Simulation and Ship Manouverability, Singapore, 2012.
6. F. Stern, Z. Wang, J. Yang, H. Sadat-Hossaini, and S. M. Mousaviraad, " Recent progress in CFD for naval architecture and ocean engineering " in Proceedings of the 11th International Conference on Hydrodynamics (ICHD 2014), Singapore, 2014, p. 26.
7. T. Turner and F. v. Walree, "Validation Studies of the Numerical Tool PANSHIP for Predicting the Calm Water Resistance of the Armidale Class Patrol Boat," p. 46, 2015.
8. R. Grin, "On the Prediction of Wave-added Resistance with Empirical Methods," Ship Production and Design, vol. 31, pp. 181-191, 2015.
9. C.-b. Ni and R.-c. Zhu, "Hull gesture and resistance prediction of high-speed vessels," Journal of Hydrodynamics, Ser. B, vol. 23, pp. 234-240, 2011.
10. A. Papanikolaou, "Holistic ship design optimization," Computer Aided Design, vol. 42, pp. 1028–1044, 2010.
11. V. A. Subramanian, P. V. V. Subramanyam, and N. Sulficker Ali, "Pressure and drag influences due to tunnels in high-speed planing craft," presented at the International Shipbuilding Progress, 2007.
12. H. Ghassemi, M. Kamarlouei, and S. T. G. Veysi, "A Hydrodynamic Methodology And CFD Analysis For Performance Prediction Of Stepped Planing Hulls," Polish Maritime Research, vol. 22, pp. 22-31, 2015.
13. I. Mizine and B. Wintersteen, "Multi Level Approach to Hull Form Development," in Proceeding on COMPIT 2011, 2011, p. 15.
14. M. A. Gammon, "Optimization of fishing vessels using a Multi-Objective Genetic Algorithm," Ocean Engineering, vol. 38, pp. 1054–1064, 2011.
15. H. Cui and O. Turan, "Application of a new multi-agent Hybrid Co-evolution based Particle Swarm Optimisation methodology in ship design," Computer Aided Design, vol. 42, pp. 1013–1027, 2011.
16. H. Cui, O. Turan, and P. Sayer, "Learning-based ship design optimization approach," Computer Aided Design, vol. 44, pp. 186–195, 2012.
17. I. Mizine, C. Rogers, and B. D. Wintersteen, "Hull Form Exploration in the Early Stage of Design," presented at the 13th International Conference on Fast Sea Transportation FAST 2015, Washington DC, 2015. 18. C. Papandreou and A. Papanikolaou, "Parametric Design and Multi-objective Optimization of SWATH," presented at the 5th Innternational Symposium on Ship Operations, Management and Economics, Athens, 2015.
19. Z. Sekulski, "Multi-objective topology and size optimization of high-speed vehicle-passenger catamaran structure by genetic algorithm," Marine Structures, vol. 23, pp. 405-433, 2010.
20. Z. Sekulski, "Multi-objective optimization of high speed vehicle-passenger catamaran by genetic algorithm: Part II Computational simulations," Polish Maritime Research, vol. 18, pp. 3-30, 2012.
21. T. Castiglione, F. Stern, S. Bova, and M. Kandasamy, "Numerical investigation of the seakeeping behavior of a catamaran advancing in regular head waves," Journal of Ocean Engineering, vol. 38, pp. 1806-1822, 2011.
22. Y. Su, Q. Chen, H. Shen, and W. Lu, "Numerical simulation of a planing vessel at high speed," Journal of Marine Science and Application, vol. 11, pp. 178-183, 2012.
23. S. Wang, Y. Su, X. Zhang, and J. Yang, "RANSE simulation of high-speed planning craft in regular waves," Journal of Marine Science and Application, vol. 11, pp. 447-452, 2012.
24. R. Yousefia, R. Shafaghat, and M. Shakeri, "Hydrodynamic analysis techniques for high-speed planing hulls," Applied Ocean Research, vol. 42, pp. 105-113, 2013.
25. S. Zaghi, R. Broglia, and A. D. Mascio, "Analysis of the interference effects for high-speed catamarans by model tests and numerical simulations," Journal of Ocean Engineering, vol. 38, pp. 2110-2122, 2011.
26. W. R. Garland and K. J. Maki, "A Numerical Study of a Two-Dimensional Stepped Planing Surface," Journal of Ship Production and Design, vol. 28, pp. 60-72, 2012.
27. Y. Chao-bang, D. Wen-cai, X. Yong, and Y. Guo-qiang, "Application of RBF neural networks to resistance prediction of deep-V planning craft," Naval University of Engineering, pp. 39-44, 2010.
28. "Ship design spiral," ed. MarineWiki.org, 2011.
29. J. H. Evans, "Basic Design Concepts," Naval Engineers Journal, vol. 71, pp. 671-678, 1959.
30. J. Chalfant, B. Langland, S. Abdelwahed, C. Chryssostomidis, and R. Dougal, "A Collaborative Early-Stage Ship Design Environment," in CEM Publications, U. o. Texas, Ed., ed: University of Texas Libraries, 2012.
31. Igor Mizine and B. Wintersteen, "Multi Level Hierarchical System Approach in Ship Design," presented at the 9th International Conference on Computer and IT Applications in the Maritime Industries, 2010.
32. I. Mizine, B. Wintersteen, and S. Wynn, "A Multi-Level Hierarchical System Approach to Ship Concept Formulation Tools," Naval Engineers Journal, vol. 124, pp. 93-119, 2012.
33. B.-S. Jang, C.-H. Lee, and Y.-S. Yang, "A process-centric ship design management framework," Journal of Maritime Science and Technology, vol. 15, pp. 23-33, 2010.
34. H. Hefazi, A. Schmitz, I. Mizine, and G. Boals, "Multi-Disciplinary Synthesis Design and Optimization for Multi-Hull Ships," Naval Engineers Journal, p. 15, 2011.
35. S. Harries, F. Tillig, M. Wilken, and G. Zaraphonitis, "An Integrated Approach for Simulation in the Early Ship Design of a Tanker," presented at the 10th International Conference on Computer and IT Applications in the Maritime Industries, Berlin, Germany, 2011.
36. A. Papanikolaou, S. Harries, M. Wilken, and G. Zaraphonitis, "Integrated Design and Multi objective Optimization Approach to Ship Design," presented at the 15th International Conference on Computer Applications in Shipbuilding, Trieste, 2011.
37. H. Nowacki, "Five decades of Computer-Aided Ship Design," Computer-Aided Design, vol. 42, pp. 956–969, 2011.
38. H. Z. Yang, J. F. Chen, N. Ma, and D. Y. Wang, "Implementation of knowledge-based engineering methodology in ship structural design," Computer Aided Design, vol. 44, pp. 196-202, 2012.
39. N. A. Tepper, "Exploring the use of Model-based Systems Engineering (MBSE) to develop systems architectures in naval ship design," Master of Science in Engineering and Management, Department of Mechanical Engineering and the System Design and Management, Massachusetts Institute of Technology, 2010. 40. C. Piaszczyk, "Model Based Systems Engineering with Department of Defense Architectural Framework," Journal of Systems Engineering, vol. 14, pp. 305-326, 2011.
41. C. Kerns, "Naval Ship Design and Synthesis Model Architecture Using a Model-Based Systems Engineering Approach " Master of Science in Ocean Engineering Faculty of Virginia Polytechnic Institute and State University, Virginia Polytechnic Institute and State University, Blacksburg, Virginia, 2011.
42. J. Fox, "A Capability-Based, Meta-Model Approach to Combatant Ship Design " Master of Science in Systems Engineering, Department of Systems Engineering, Naval Postgraduate School, Monterey, California, 2011.
43. C. Kerns, D. A. Brown, and M. D. Woodward, "Application of a DoDAF Total-Ship System Architecture in Building a Design Reference Mission for Assessing Naval Ship Operational Effectiveness," presented at the ASNE Global Deterrence and Defense Symposium, Bloomington, 2011.
44. G. D. S. Gaitan, "Alternatives impact in combatant-ship design," Master of Science in Mechanical Engineering, Department of Mechanical and Aerospace Engineering,Naval Postgraduate School, 2011. 45. M. A. Payam Lotfia, Reza Kowsari Esfahan "Numericalinvestigation of a stepped planing hull in calm water," Journal of Ocean Engineering 94, pp. 103-110, 2015.
46. D. Svahn, "Performance Prediction of Hulls with Transverse Steps," Centre for Naval Architecture, Royal Institute of Technology, 2009.
47. M. Morgut and E. Nobile, "Influence of the Mass Transfer Model on the Numerical Prediction of the Cavitating Flow Around a Marine Propeller," presented at the Second International Symposium on Marine Propulsors, Hamburg, Germany, 2011.
48. Y.-S. L. Soonhung Han, Young Bok Choi, "Hydrodynamic hull form optimization using parametric models," Journal of Marine Science and Technology, vol. 17, pp. 1-17, 2012.
49. G. J. Grigoropoulos and D. S. Chalkias, "Hull-form optimization in calm and rough water," Computer Aided Design, vol. 42, pp. 977-984, 2010.
50. M. Atlar, K. Seo, R. Sampson, and D. B. Danisman, "Anti-slamming bulbous bow and tunnel stern applications on a novel Deep-V catamaran for improved performance," International Journal of Naval Architecture and Ocean Engineering, vol. 5, pp. 302-312, 2013.
51. A. D. Papanikolaou, "Holistic Design and Optimization of High Speed Marine Vehicles," presented at the The 9th HMSV Symposium, Naples, 2011.
52. R.G.Latorre, "Wave Resistance On High Speed Catamaran," 2013.
53. R. Tinsdeall. (2012). Scottish sailing engineers have designs on world speed record. Available: https://www.theengineer.co.uk/issues/23-january-2012/scottish-sailing-engineers-have-designs-on-world-speed-record/
54. L. I. Vishnevsky, "Improvement Of High Speed Craft Propulsion By Using Of Propellers With Shifted Blade Connection To The Hub," presented at the International Conference on Fast Sea Transportation, St. Petersburg, Russia, 2015.
55. K. U. Ralf Leidenberger, "Automatic differentiation for the optimization of a ship propulsion and steering system: a proof of concept," Journal of Global Optimization, vol. 49, pp. 497-504, 2011.
56. F. Stern, J. Yang, Z. Wang, H. Sadat-Hosseini, M. Mousaviraad, S. Bhushan, et al., "Computational ship hydrodynamics: Nowadays and way forward," International Shipbuilding Progress, vol. 60, pp. 3-105, 2012.
57. M. S. Gordon, D. A. Jamshidi, S. Mahlke, and Z. M. Mao, "COMET: Code Offload by Migrating Execution Transparently," presented at the 10th UNISEX Symposium on Operating System Designs and Exploration, Hollywood, 2012.
58. M. Hopfensitz, J. C. Matutat, and K. Urban, "Numerical Modelling and Simulation of Ship Hull Geometries," Progress in Industrial Mathematics at ECMI 2010, vol. 17, pp. 465-471, 2010.
59. R. Azcueta and N. Rousselon, "CFD Applied to Mega and Super Yacht Design," presented at the International Conference on Design, Construction and Operation on Super and Mega Yachts, Geneo, Italy, 2009. 60. H. Islam, "Prediction of ship resistance in oblique waves using RaNS based solver," Master of Science in Engineering, Division of Ocean Systems Engineering, School of Mechanical, Aerospace and Systems Engineering, 2015.
61. D. H. Shahid Mahmood, "Computational fluid dynamics based bulbous bow optimization using a genetic algorithm," Journal of Marine Science and Application, vol. 11, pp. 286-294, 2012.
62. Q. C. Yumin Su, Hailong Shen, Wei Lu, "Numerical simulation of a planning vessel at high speed," Journal of Marine Science and Application, vol. 11, pp. 178-183, 2012.
63. D. B. H. Rui Deng, Guang Li Zhou, Hua Wei Sun, "Preliminary Numerical Investigation of Effect of Interceptor on Ship Resistance," Journal of Applied Mechanics and Materials, vol. 97-98, pp. 1085-1090, 2011.
64. R. Yousefi, R. Shafaghat, and M. Shakeri, "High-speed planing hull drag reduction using tunnels," Ocean Engineering, vol. 84, pp. 54-60, 2014.
65. M. Ghassabzadeh and H. Ghassemi, "Determining of the hydrodynamic forces on the multi-hull tunnel vessel in steady motion," Journal of the Brazilian Society of Mechanical Sciences and Engineering, p. 15, 2013.
66. F. v. Walree and N. F. A. J. Carette, "Validation of time domain seakeeping codes for a destroyer hull form operating in steep stern-quartering seas," International Journal of Naval Architecture and Ocean Engineering, vol. 3, pp. 9-19, 2011.
67. F. v. Walree and P. d. Jong, "Deterministic Validation of a Time Domain Panel Code for Parametric Roll," in Proceedings of the 12th International Ship Stability Workshop, Washington DC, 2011, p. 7.
68. E. Verboom and F. v. Walree, "Validation of Time Domain Panel Codes for Prediction of Large Amplitude Motions of Ships " in Proceedings of the 12th International Conference on the Stability of Ships and Ocean Vehicles, Glasgow, United Kingdom, 2015.
69. P. Ghadimi, A. Dashtimanesh, S. R. Djeddi, and Y. F. Maghrebi, "Development of a mathematical model for simultaneous heave, pitch and roll motions of planing vessel in regular waves," International Journal of Scientific World, vol. 1, pp. 44-56, 2013.
70. T. M. Sayeed, L. M. Lye, and H. Peng, "Response Surface Models for Analyzing Planing Hull Motions in a Vertical Plane," presented at the ASME 2014 33rd International Conference on Ocean, Offshore and Arctic Engineering, San Fransisco, California, 2014.
71. T. M. Sayeed, H. Peng, B. Veitch, and R. Billard, "Numerical Simulation of Fast Rescue Crafts in Waves and Its Application in a Training Simulator," Journal of Marine Technology, vol. 8, p. 23, 2013.
72. G. Hassan and Y. Su, "Determining the hydrodynamic forces on a planing hull in steady motion," Journal of Marine Science and Application, vol. 7, pp. 147-156, 2008.
73. Sadk Özum, Bekirenera, and Kaan Ünlugencoglu, "Resistance prediction of a high speed craft by using CFD," 2010.
74. D. Radojcic, A. Zgradic, M. Kalajdzic, and A. Simic, "Resistance Prediction for Hard Chine Hulls in the Pre-Planing Regime," Polish Maritime Research, vol. 21, pp. 9-26, 2014.
75. D. Savitsky and M. Morabito, "Surface Wave ContoursAssociated With the Forebody Wake of Stepped Planing Hulls," Journal of Marine Technology, vol. 47, pp. 1-16, 2010.
76. A. R. Kohansal and H. Ghassemi, "A numerical modeling of hydrodynamic characteristics of various planing hull forms," Journal of Ocean Engineering, vol. 37, pp. 498-510, 2010.
77. E. Begovic and C. Bertorello, "Resistance assessment of warped hullform," Journal of Ocean Engineering, vol. 56, pp. 28-42, 2012.
78. D. J. Kim, S. Y. Kim, Y. J. You, K. P. Rhee, S. H. Kim, and Y. G. Kim, "Design of high-speed planning hulls for the improvement of resistance and seakeeping performance," International Journal of Naval Architecture and Ocean Engineering, vol. 5, pp. 161-177, 2013.
79. A. A. K. Rijkens, J. A. Keuning, and R. H. M. Huijsmans, "A computational tool for the design of ride control systems for fast planing vessels," International Shipbuilding Progress, vol. 58, pp. 165-190, 2011. 80. A. R. Kohansal, H. Ghassemi, and M. Ghaisi, "Hydrodynamic characteristics of high speed planing hulls, including trim effects," Turkish Journal of Engineering & Environmental Sciences, vol. 34, pp. 155-170, 2010. 81. M. Bagherzadeh, H. Ghassemi, M. Kamarlouei, and D. Nemati, "Wave Wash Prediction of the River Craft Using Numerical Approach," presented at the HSMV 2014 10th Symposium On High Speed Marine Vehicles, 2014.
82. M. Ghassabzadeh and H. Ghassemi, "An innovative method for parametric design of planing tunnel vessel Hull form," Journal of Ocean Engineering, vol. 60, pp. 14-27, 2012.
83. M. Ghassabzadeh and H. Ghassemi, "Numerical Hydrodynamic of Multihull Tunnel Vessel," Open Journal of Fluid Dynamics, vol. 3, p. 7, 2013.
84. H. G. Morteza Ghassabzadeh, "Dynamics and Stability of Boats With Aerodynamic Support," Journal of Ship Production and Design, vol. 29, pp. 17-24, 2013.
85. C. S. Chaneya and K. I. Matveeva, "Modeling of steady motion and vertical-plane dynamics of a tunnel hull," International Journal of Naval Architecture and Ocean Engineering, vol. 6, pp. 323-332, 2014. 86. H. K. Moghadam, R. Shafaghat, and R. Yousefi, "Numerical investigation of the tunnel aperture on drag reduction in a high-speed tunneled planing hull," Journal of the Brazilian Society of Mechanical Sciences and Engineering, vol. 37, pp. 1719-1730, 2015.
87. S. Brizzolara and F. Serra, "Accuracy of CFD Codes In The Prediction of Planing Surfaces Hydrodynamics Characteristics," p. 12, 2007.
88. M. Kandasamy, D. Peri, S. K. Ooi, P. Carrica, F. Stern, and E. F. Campana, "Multi-fidelity optimization of a high-speed foil-assisted semi-planing catamaran for low wake,"Journal of Marine Science and Technology, vol. 16, pp. 143-156, 2011.
89. M. Kandasamy, S. K. Ooi, P. Carrick, F. Stern, E. F. Campana, and D. Peri, "CFD validation studies for a high-speed foil-assisted semi-planing catamaran," Journal of Marine Science and Technology, vol. 16, pp. 157-167, 2011.
90. Z. Sheingart, "Hydrodynamics of High Speed Planing Hulls with Partially Ventilated Bottom and Hydrofoils," Master of Engineering in Mechanical Engineering, Department of Mechanical Engineering, Massachusetts Institute of Technology, 2014.
91. S. P. Kim, "CFD as a seakeeping tool for ship design," Inter J Nav Archit Oc Engng, 2011.
92. Y.-l. Li, R.-c. Zhu, G.-p. Miao, and J. Fan, "Simulation of tank sloshing based on OpenFOAM and coupling with ship motions in time domain," Hydrodynamics, Ser B., vol. 24, pp. 450-457, 2012.
93. D. GL. (2016, 14/9/2016). Sea-keeping analysis. Available:https://www.dnvgl.com/services/sea-keeping-analysis-4713.
94. B. B. R. Broglia, B. Jacob, A. Olivieri, S. Zaghi and F. Stern, "Calm Water and Seakeeping Investigation for a Fast Catamaran," presented at the 11th International Conference on Fast Sea Transportation, Hawaii, USA, 2011.
95. Z. Guo, Q. Ma, and Z. Lin, "A Comparison of Seakeeping Predictions for Wave-Piercing Catamarans Using STF and URANS Methods," presented at the The Twenty-fourth International Ocean and Polar Engineering Conference, Busan, Korea, 2014.
96. Z. Q. Guo, Q. W. Ma, and J. L. Yang, "A seakeeping analysis method for a high-speed partial air cushion supported catamaran (PACSCAT)," Journal of Ocean Engineering, vol. 110, pp. 357-376, 2015.
97. S. G. Lewis, D. A. Hudson, S. R. Turnock, and D. J.Taunton, "Impact of a free-falling wedge with water: synchronized visualization, pressure and acceleration measurements," Fluid Dynamics Research, vol. 42, 2010.
98. Z. Guo, Q. Ma, and H. Sun, "A seakeeping analysis method for T-Craft," Proceedia Engineering, vol. 126, pp. 265-269, 2015.
99. T. Castiglione and S. Bova, "CFD Simulation for Seakeeping of DELFT Catamaran in Regular Head and Oblique Waves," presented at the FAST-2013 International Conference on Fast Sea Transportation, Netherlands, 2013.
100. S. M. Mousaviraad, Z. Wang, and F. Stern, "URANS studies of hydrodynamic performance and slamming loads on high-speed planing hulls in calm water and waves for deep and shallow conditions," Journal of Applied Ocean Research, vol. 51, pp. 222-240, 2015.
101. F. Stern, H. Sadat-Hosseini, M. Mousaviraad, and S.Bhushan, "Evaluation of Seakeeping Predictions," inNumerical Ship Hydrodynamics, L. Larsson, F. Stern, and M. Visonneau, Eds., 1 ed: Springer Netherlands, 2014, pp. 141-202.
102. F. Prini, S. Benson, R. W. Birmingham, and R. S. Dow, "Seakeeping Analysis Of A High-Speed Search and Rescue Craft by Linear Potential Theory," p. 10, 2015.
103. H. Sun and O. M. Faltinsen, "Numerical study of planing vessels in waves," Journal of Hydrodynamics, Ser. B, vol. 22, pp. 468-475, 2010.
104. A. Iafrati and R. Broglia, "Comparisons Between 2d + T Potential Flow Models And 3d Rans For Planing Hull Hydrodynamics," in Proceedings 25th International Workshop on Water Waves and Floating Bodies Harbin, China, 2010, p. 4.
105. (2016). Fishing Vessel Safety. Available: http://www.imo.org/en/OurWork/Safety/Regulations/FishingVessels.
106. M. Tello, S. R. e. Silva, and C. G. Soares, "Seakeeping performance of fishing vessels in irregular waves,"Ocean Engineering, vol. 38, pp. 763-773, 2011.
107. A. Scamardella and V. Piscopo, "The overall induced interruptions in seakeeping optimization analysis," presented at the Developments in Maritime Transportation and Exploitation of Sea Resources, London, 2014.
108. M. Greco and C. Lugni, "Numerical Study of Parametric Roll on a Fishing Vessel," presented at the ASME 2013 32nd International Conference on Ocean, Offshore and Arctic Engineering, Nates, france, 2013.
109. K. A. Lay, R. Yakushiji, S. Mäkiharju, M. Perlin, and S. L. Ceccio, "Partial Cavity Drag Reduction at High Reynolds Numbers," Ship Research, vol. 54, pp. 109-119, 2010.
110. A. H. Day and C. Cooper, "An experimental study of interceptors for drag reduction on high-performance sailing yachts," Ocean Engineering, vol. 38, pp. 983-994, 2011.
111. J. Hemmel. (2011). Outboard Advantages. Available: http://www.boatingmag.com/boats/outboard-advantages.
112. J. Bowles and D. L. Blount, "Turning Characteristics and Capabilities of High-Speed Monohulls," presented at the The Third Cheasepeake Power Boat Symposium, Maryland, USA, 2012.
113. t. f. e. Wikipedia. (2016). Inboard Motor. Available: https://en.wikipedia.org/wiki/Inboard_motor.
114. E. Luetjens, "Modern high speed propulsion systems and their impact on marine transmission design," presented at the FAST 2005, St. Petersburg, Russia, 2005.
115. E. Colby. (2014). Surface Drive. Available: http://www.boatingmag.com/boats/basics-surface-drives.
116. "Evinrude E-Tec G2 300HP," vol. 44.7 KB, showroom_cat_etec_20.png, Ed., ed, 2016.
117. "Inboard Engine," vol. 21.4 KB, Maintain-marine-engines-with-an-ultarsonic-cleaner, Ed., ed, 2016.
118. "Waterjets," vol. 33KB, waterjets-stainless-steel-740x637, Ed., ed, 2016.
119. "Surface Drive," vol. 75 KB, 24647-206815, Ed., ed, 2016.
120. C. Ballin. (2016). Torqeedo Outboards. Available: http://www.torqeedo.com/en/products/outboards 121. Choeng Hoon Choi, Sungju Yu, and I.-S. Han, "Development and demonstration of PEM fuel-cell-battery hybrid system for propulsion of tourist boat," International Journal of Hydrogen Energy, vol. 41, 2016. 122. A. Bassam, "Hybrid fuel cell electric propulsion for marine transport applications: case study of a domestic ferry," presented at the Next Generation Marine Power & Propulsion Conference, Southampton, United Kingdom, 2016.
123. L. Zimmerman, "Development and Validation of Momentum Source Propeller Model in Open-Water Conditions," Master Thesis, 2015.
124. H. Afshar and M. A. Keshvari, "3D Numerical Simulation of Propeller and Its Aerodynamic Interference Effects on Tail of a Flying Boat," Journal of Applied Sciences, vol. 4, pp. 644-653, 2015.
125. M. A. Elghorab, A. Abou El-Azm Aly, A. S. Elwetedy, and M. A. Kotb, "Open Water Performance of a Marine Propeller Model Using CFD," presented at the Proceedings of International Conference on Fluid Dynamics, Egypt, 2013.
126. M. Mansouri, B. Radi, and A. E. Hami, "Vibroacoustic Analysis of Boat Propeller Using Reliability Techniques," in Design and Modelling of Mechanical Systems, M. Haddar, L. Romdhane, J. Louati, and A. B. Amara, Eds., ed Tunisia: Springer Berlin Heidelberg, 2013, pp. 315-322.
127. J.O. Egerton, M.G. Rasul, and R.J. Brown, "Outboard Engine Emissions: Modelling and Simulation of Underwater Propeller Velocity Profile using the CFD Code FLUENT," presented at the 16th Australasian Fluid Mechanics Conference, Crown Plaza, Gold Coast, Australia, 2007.
128. M. Chapple and M. Renilson, "A viable approach to propeller safety for small craft: Ringed Propellers," presented at the First International Symposium on Marine Propulsors, Norway, 2009.
129. A. Guha and J. Falzaranoa, "Application of multi objective genetic algorithm in ship hull optimization," Ocean Systems Engineering, vol. 5, pp. 91-107, 2015.
130. G. J. Grigoropoulos and D. S. Chalkias, "Hull-form optimization in calm and rough water," Computer-Aided Design, vol. 42, pp. 977-984, 2010.
131. S. B. Iacopo Biliotti, Michele Viviani, Giuliano Vernengo, "Automatic Parametric Hull Form Optimization of Fast Naval Vessels," presented at the 11th InternationalConference on Fast Sea Transportation, Honolulu, Hawaii, USA,, 2011.
132. D. P. Emilio F. Campana , Yusuke Tahara , Frederick Stern "Shape optimization in ship hydrodynamics using computational fluid dynamics," Comput. Methods Appl. Mech. Engrg. 196, p. 18, 2006.
133. H. Bagheri, H. Ghassemi, and A. Dehghanian, "Optimizing the Seakeeping Performance of Ship Hull Forms Using Genetic Algorithm," Trans Nav, the International Journal on Marine Navigation and Safety of Sea Transportation,vol. 8, pp. 49-57, 2014.
134. A. I. G. K.V. Kostasa, C.G. Politisa, P.D. Kaklisc, "Ship-hull shape optimization with a T-spline based BEM–isogeometric solver," Comput. Methods Appl. Mech. Engrg. 284, pp. 611-622, 2015.
135. Ahmad F. Ayob, T. Ray, and W. F. S. U, "A Framework for Scenario-Based Hydrodynamic Design Optimization of Hard Chine Planing Craft," presented at the International Conference on Computer Applications and Information Technology in the Maritime Industries, Gubbio, Italy, 2010.
136. A. F. M. Ayob, T. Ray, and W. F. Smith, "Scenario-based Hydrodynamic Design Optimization of High Speed Planing Craft for Coastal Surveillance," presented at the Proceedings of the IEEE Congress on Evolutionary Computation, Los Angeles, USA, 2011.
137. A.F. Ayob, W. B. W. Nik, T. Ray, and W. F. Smith, "Hull Surface Information Retrieval and Optimization of High Speed Planing Craft," presented at the IOP Conference Series: Materials Science and Engineering, 2012.
138. Mohsen Khosravi Babadi and H. Ghassemi, "Parametric Study on Vessel Body Lines Modeling to Optimize Seakeeping Performance," Journal of Ocean Research, vol. 2, pp. 5-10, 2014.
139. S. Jeong and H. Kim, "Development of an Efficient Hull Form Design Exploration Framework," Mathematical Problems in Engineering, vol. 2013, pp. 1-12, 2013.
140. F. Cimolin, F. Serra, and G. Vatteroni, "Optimization of the hull resistance for the Azimut 95’ yacht with CFD," p. 9, 2014.
141. B.-J. Zhang, "The Optimization of The Hull Form With The Minimum Wave Making Resistance Based On Rankine Source Method," Journal of Hydrodynamics, vol. 21, pp. 277-284, 2009.
142. B.-J. Zhang, "Research on Optimization of Hull Lines For Minimum Resistance Based On Rankine Source Method, "Journal of Marine Science and Technology, vol. 20, 2012.
143. D.-W. Park and H.-J. Choi, "Hydrodynamic Hull Form Design Using an Optimization Technique," International journal of Ocean System Engineering, vol. 3, pp. 1-9, 2013.
144. H. Kim, C. Yang, and F. Noblesse, "Hull Form Optimization for Reduced Resistance and Improved Seakeeping via Practical Designed-Oriented CFD Tools," p. 11, 2010.
145. T. Cepowski, "Determination of optimum hull form for passenger car ferry with regard to its sea-keeping qualities and additional resistance in waves," Polish Maritime Research, vol. 15, pp. 3-11, 2008. 146 .T. Cepowski, "On the modeling of car passenger ferry ship design parameters with respect to selected sea-keeping qualities and additional resistance in waves," Polish Maritime Research, vol. 16, pp. 3-10, 2009. 147 .J. Lavroffa, M. R. Davisa, D. S. Hollowaya, and G. Thomasb, "Wave slamming loads on wave-piercer catamarans operating at high-speed determined by hydro-elastic segmented model experiments," Marine Structures, vol. 33, pp. 120-142, 2013.
148. D. J. Piro and K. J. Maki, "Hydroelastic analysis of bodies that enter and exit water," Fluids and Structures, vol. 73, pp. 134-150, 2013.
149. T. Magoga, R. O. Rabanal, and G. Thomas, "Indentification of slam events experienced by a high-speed craft," presented at the Safety & Reliability of Ships, Offshore & Subsea Structures International Conference, Scotland, 2014.
150. Christine Ikeda, Parisa Ghandehari, Felipe S. Castro, Chance R. Aucoin, and B. H. Bye, "Slamming Load Effects on the Bottom of High-Speed Aluminum Planing Craft," 2015.
151. Silvia Volpi, Hamid Sadat-Hosseini, and M. Diez, "Validation of High Fidelity CFD/FE FSI for Full-Scale High-Speed Planing Hull With Composite Bottom Panels Slamming," presented at the VI International Conference on Computational Methods for Coupled Problems in Science and Engineering, 2015.
152. S. Zamanirad, M. S. Seif, M. R. Tabeshpur, and O. Yaakob, "Investigation of hydroelastic effect in analysis of high-speed craft," Ships and Offshore Structures, pp. 1-9, 2014.
153. D. J. T. P. T. J. Camilleri, "Slamming impact loads on high-speed craft sections using two-dimensional modelling," Analysis and Design of Marine Structures, p. 9, 2015.
154. Josef Camilleri, Pandeli Temarel, and D. Taunton, "Two-Dimensional Numerical Modelling of Slamming Impact Loads on High-Speed Craft," presented at the 7th International Conference on HYDROELASTICITY IN MARINE TECHNOLOGY, Split, Croatia, 2015.
155. S. R. Johannessen, "Use of CFD to Study Hydrodynamic Loads on Free-Fall Lifeboats in the Impact Phase., "Department of Marine Technology, Norwegian University of Science and Technology, Norway, 2012.
156. M. D. G. Oger, B. Alessandrini, P. Ferrant, "Two-dimensional SPH simulations of wedge water entries," Journal of Computational Physics, pp. 803-822, 2006.
157. M. Viviani and S. Brizzolara, "Evaluation of slamming loads using smoothed particle hydrodynamics and Reynolds-averaged Navier–Stokes methods," presented at the Proceedings of the Institution of Mechanical Engineers Part M Journal of Engineering for the Maritime Environment 2009.
158. D. J. V. a. T. P. Gourlay, "An Investigation of Slam Events in Two-Dimensions Using Smoothed Particles Hydrodynamics," presented at the 10th International Conference on Fast Sea Transportation, Athens, Greece, 2009.
159. J. R. S. I. P. G. Thomas, "Prediction of Slamming Behaviour of Monohull and Multihull Forms using Smoothed Particle Hydrodynamics," 2011.