A harmonic polynomial cell (HPC) method for 3D Laplace equation with application in marine hydrodynamics YL Shao, OM Faltinsen Journal of Computational Physics 274, 312-332, 2014 | 145 | 2014 |
Design and comparative analysis of alternative mooring systems for floating wind turbines in shallow water with emphasis on ultimate limit state design K Xu, K Larsen, Y Shao, M Zhang, Z Gao, T Moan Ocean Engineering 219, 108377, 2021 | 92 | 2021 |
Numerical potential-flow studies on weakly-nonlinear wave-body interactions with/without small forward speeds YL Shao Phd Thesis, NTNU, 2010 | 64 | 2010 |
Towards efficient fully-nonlinear potential-flow solvers in marine hydrodynamics YL Shao, OM Faltinsen International Conference on Offshore Mechanics and Arctic Engineering 44915 …, 2012 | 62 | 2012 |
Linear seakeeping and added resistance analysis by means of body-fixed coordinate system YL Shao, OM Faltinsen Journal of marine science and technology 17, 493-510, 2012 | 59 | 2012 |
Use of body-fixed coordinate system in analysis of weakly nonlinear wave–body problems YL Shao, OM Faltinsen Applied Ocean Research 32 (1), 20-33, 2010 | 54 | 2010 |
Fully-nonlinear wave-current-body interaction analysis by a harmonic polynomial cell method YL Shao, OM Faltinsen Journal of offshore mechanics and Arctic engineering 136 (3), 031301, 2014 | 47 | 2014 |
A study on fully nonlinear wave load effects on floating wind turbine K Xu, Y Shao, Z Gao, T Moan Journal of Fluids and Structures 88, 216-240, 2019 | 45 | 2019 |
Effect of wave nonlinearity on fatigue damage and extreme responses of a semi-submersible floating wind turbine K Xu, M Zhang, Y Shao, Z Gao, T Moan Applied Ocean Research 91, 101879, 2019 | 44 | 2019 |
Investigation of higher-harmonic wave loads and low-frequency resonance response of floating offshore wind turbine under extreme wave groups X Zeng, W Shi, X Feng, Y Shao, X Li Marine Structures 89, 103401, 2023 | 43 | 2023 |
Application of a 2D harmonic polynomial cell (HPC) method to singular flows and lifting problems H Liang, OM Faltinsen, YL Shao Applied Ocean Research 53, 75-90, 2015 | 40 | 2015 |
Transient response of a TLP-type floating offshore wind turbine under tendon failure conditions H Wu, Y Zhao, Y He, Y Shao, W Mao, Z Han, C Huang, X Gu, Z Jiang Ocean Engineering 220, 108486, 2021 | 37 | 2021 |
Second-order diffraction and radiation of a floating body with small forward speed YL Shao, OM Faltinsen Journal of offshore mechanics and Arctic engineering 135 (1), 011301, 2013 | 34 | 2013 |
Liquid sloshing in an upright circular tank under periodic and transient excitations H Liang, H Santo, Y Shao, YZ Law, ES Chan Physical Review Fluids 5 (8), 084801, 2020 | 32 | 2020 |
A numerical study of the second-order wave excitation of ship springing by a higher-order boundary element method YL Shao, OM Faltinsen International Journal of Naval Architecture and Ocean Engineering 6 (4 …, 2014 | 31 | 2014 |
Efficient methods free of irregular frequencies in wave and solid/porous structure interactions H Liang, CO Housseine, X Chen, Y Shao Journal of Fluids and Structures 98, 103130, 2020 | 30 | 2020 |
Challenges in wave force modelling for mooring design in high seas CT Stansberg, KE Kaasen, BC Abrahamsen, A Nestegård, Y Shao, ... Offshore technology conference, OTC-25944-MS, 2015 | 30 | 2015 |
Water wave scattering by impermeable and perforated plates H Liang, S Zheng, Y Shao, KH Chua, YS Choo, D Greaves Physics of Fluids 33 (7), 2021 | 29 | 2021 |
Experimental and numerical studies on the low-frequency responses of a spar-type floating offshore wind turbine J Yang, YP He, YS Zhao, YL Shao, ZL Han Ocean Engineering 222, 108571, 2021 | 29 | 2021 |
Higher-order gap resonance between two identical fixed barges: A study on the effect of water depth Y Ding, JH Walther, Y Shao Physics of Fluids 34 (5), 2022 | 25 | 2022 |