[1] Okumoto Y, Takeda Y, Mano M, Okada T (2009) Design of ship hull structures: A practical guide for engineers. SSBM.

[2] AlaviMehr J, Lavroff J, Davis MR, Holloway DS, Thomas G (2017) An experimental investigation of ride control algorithms for high-speed catamarans Part 1: Reduction of ship motions. J Ship Res 61(1): 35-49.

[3] Lavroff J, Davis M, Holloway D, Thomas G (2009) The vibratory response of high-speed catamarans to slamming investigated by hydroelastic segmented model experiments. Int J Marit Eng 151(4): 1-13.

[4] Thomas G, Davis M, Holloway D (2003) The whipping vibration of large high speed catamarans. Transactions of the Royal Institution of Naval Architects Part A, Int J Marit Eng 145: 289-304.

[5] Thomas G (2011) Slam events of high-speed catamarans in irregular waves. J Mar Sci Technol 16(1): 8-21.

[6] Townsend P, Suárez-Bermejo JC, Horcajo E, PazPinilla-Cea (2018) Reduction of slamming damage in the hull of high-speed crafts manufactured from composite materials using viscoelastic layers. Ocean Eng 159: 253-267.

[7] Townsend P, Suárez-Bermejo JC, Sanz-Horcajo E, PazPinilla-Cea (2018) Reduction of slamming damage in the hull of high-speed crafts manufactured from composite materials using viscoelastic layers. Ocean Eng 159: 253-267.

 [8] Kim B, Choung J (2020) A study on prediction of whipping effect of very large container ship considering multiple sea states. Int J Nav Archit 12: 387-398.

[9] Storhaug G (2007) Experimental investigation of wave induced vibrations and their effect on the fatigue loading of ships. NTNU.

[10] Barhoumi M, Storhaug G (2014) Assessment of whipping and springing on a large container vessel. Int J Nav Archit 6 (2): 442-458.

[11] Drummen I, Holtman M (2014) Benchmark study of slamming and whipping. Ocean Eng86: 3-10.

[12] Hirdaris S (2009) Hydroelasticity of ships: recent advances and future trends. P I Mech Eng M-J Eng 223(3): 305-330.

[13] Storhaug G (2014) The measured contribution of whipping and springing on the fatigue and extreme loading of container vessels. Int J Nav Archit Ocean Eng 46: 1096-1110.

[14] Storhaug G, Malenica S, Choi BK, Zhu S (2010) Consequence of whipping and springing on fatigue and extreme loading for a 13000TEU container vessel based on model tests. Proc. PRADS-2010, COPPE/UFRJ, Rio de Janeiro, Brazil, 1200-1209.

[15] Kim H, Kim Y, Yuck RH, Lee OY (2015) Comparison of slamming and whipping loads by fully coupled hydroelastic analysis and experimental measurement. J Fluids Struct 52: 145-152.

[16] Henry JR (1970) Slammig of ships: A critical review of the current state of knowledge ship structure committee, Technical paper.

[17] Piro D, Maki K (2011) Hydroelastic  wedge  entry  and  exit. Proceedings of the 11th International Conference on FAST2011.

[18] Tveitnes T, Fairlie-Clark A, Varyani K (2008) An experimental investigation into the constant ve-locity water entry of wedge-shaped sections. Ocean Eng 35(14-15): 1463-1478.

[19] Tassin A, Korobkin A, Cooker M (2012) Modelling  of  the  oblique  impact  of  an  elongated body  by  2D+ t  approach. 27th Int  Wkshp on  Water  Waves  &  Floating  Bodies.

[20]  Tassin A, Piro D, Korobkin A, Maki K, Cooker M (2013) Two-dimensional  water  entry and exit of a body whose shape varies in time. J Fluids Struct 28: 211-231.

[21] Piro D, Maki KJK (2013) Hydroelastic analysis of bodies that enter and exit water. J Fluids Struct 37: 60-74.

[22] Andersen I, Jensen JJ (2014) Measurements  in  a  containership  of  wave  induced  hull girder stresses in excess of design values. Mar Struct 37: 54-85.

[23] Wang S, Soares CG (2013) Slam induced loads on bow flared sections with various roll angles. Ocean Eng 67: 45-57.

[24] Koo J, Kim B, Jang K, Suh Y, Bigot F (2012) Fatigue assessment of the 18,000TEUcontainer  vessel  considering  the  effect  of  springing, 23rdInt.  ISOPE.

[29] Park J (2006) Time domain simulation of hydroelastic response of ships in large amplitude waves. Phd Thesis, University Southampton.

[30] Jensen JJ (2001) Load and global response of ships. Amsterdam Elsevier.

[31] Najmeh M (2016) Estimation of waves and ship responses using onboard measurements. Phd Thesis, Technical University of Denmark.

[32] Das SK,  Baghfalaki M (2014) Mathematical modelling of response amplitude operator for roll motion of a floating body: Analysis in frequency domain with numerical validation. J Marine Sci Appl 13: 143-157

[33]  https://www.aqwa.com.au/

[34] https: //www.ansys.com/ products/ fluids/ ansys - fluent

[35] Mathews, Nandakumar G (2013) Fatigue life estimation of ship structure. Int J Sci Eng Res 4(5).