Global wave loads on intact and damaged Ro-Ro ships in regular oblique waves

Salvesen, 1970, Ship motions and sea loads, Trans SNAME, 78, 250 Kim, 1980, Motions and hydrodynamic loads of a ship advancing in oblique waves, Trans SNAME, 88, 225 Chan, 1992, Dynamic structural responses of a mono-hull vessel to regular waves, Int Shipbuild Progr, 39, 287 Papanikolaou, 1992, A three-dimensional panel method for motions and loads of ships with forward speed, Ship Tech Res, 39, 147 Yamamoto, 1980, Motion and longitudinal strength of a ship in head sea and effects of nonlinearities, Nav Archit and Ocean Eng, 18, 91 Chiu, 1989, Nonlinear prediction of vertical motions and wave loads of high-speed crafts in head sea, Int Shipbuild Progr, 36, 193 Turan, 1994, Dynamic stability assessment of damaged passenger ships, Trans RINA, 136, 79 De Kat, 1990, The numerical modeling of ship motions and capsizing in severe seas, J Ship Res, 34, 289, 10.5957/jsr.1990.34.4.289 Adegeest LJM. Nonlinear hull girder loads in ships. PhD thesis, Faculty of Mechanical Engineering and Marine Technology, Delft University of Technology, 1994. Chan HS. Prediction of large amplitude motions, wave loads on a Ro-Ro ship in regular oblique waves in intact and damage conditions. DTR-4.1-NEW-12.98, DEXTREMEL project BE97-4375, 1998. Atlar M, Korkut E, Lamb DA. Small scale tests for the measurements of global loads with an intact and damaged Model. DTR-4.2-NEW-11.99. DEXTREMEL project BE97-4375, 1999. Cummins, 1962, The impulse response function and ship motions, Schiffstechnik, 9, 101 Wehausen JV, Laitone EV. Surface waves. Handbuch der physik, Band IX. Berlin: Springer, 1960. p. 446–78. Chan, 2002, Large-amplitude motion responses of a Ro-Ro ship to regular oblique waves in intact and damaged conditions, J Marine Sci Technol, 7, 91, 10.1007/s007730200017