Dynamic response and power performance of a combined spar-type floating wind turbine and coaxial floating wave energy converter MJ Muliawan, M Karimirad, T Moan Renewable energy 50, 47-57, 2013 | 226 | 2013 |
Offshore energy structures: for wind power, wave energy and hybrid marine platforms M Karimirad Springer, 2014 | 222 | 2014 |
Wave and Wind Induced Dynamic Response of Catenary Moored Spar Wind Turbine M Karimirad, T Moan press, Journal of Waterway, Port, Coastal, and Ocean Engineering, doi 10, 0 | 212* | |
A simplified method for coupled analysis of floating offshore wind turbines M Karimirad, T Moan Marine Structures 27 (1), 45-63, 2012 | 158 | 2012 |
Extreme responses of a combined spar-type floating wind turbine and floating wave energy converter (STC) system with survival modes MJ Muliawan, M Karimirad, Z Gao, T Moan Ocean Engineering 65, 71-82, 2013 | 154 | 2013 |
Offshore code comparison collaboration within IEA Wind Task 23: Phase IV results regarding floating wind turbine modeling J Jonkman, T Larsen, A Hansen, T Nygaard, K Maus, M Karimirad, Z Gao, ... National Renewable Energy Lab.(NREL), Golden, CO (United States), 2010 | 147* | 2010 |
Extreme dynamic structural response analysis of catenary moored spar wind turbine in harsh environmental conditions M Karimirad, T Moan | 122 | 2011 |
Dynamic response analysis of wind turbines under blade pitch system fault, grid loss, and shutdown events Z Jiang, M Karimirad, T Moan Wind Energy 17 (9), 1385-1409, 2014 | 120 | 2014 |
Second-order hydrodynamic effects on the response of three semisubmersible floating offshore wind turbines L Zhang, W Shi, M Karimirad, C Michailides, Z Jiang Ocean Engineering 207, 107371, 2020 | 113 | 2020 |
Hydroelastic code-to-code comparison for a tension leg spar-type floating wind turbine M Karimirad, Q Meissonnier, Z Gao, T Moan Marine Structures 24 (4), 412-435, 2011 | 106 | 2011 |
V-shaped semisubmersible offshore wind turbine: An alternative concept for offshore wind technology M Karimirad, C Michailides Renewable Energy 83, 126-143, 2015 | 102 | 2015 |
Modeling and analysis of floating wind turbine drivetrain YH Xing, M Karimirad, T Moan Wind Energy, 2012 | 87* | 2012 |
STC (Spar-Torus Combination): a combined spar-type floating wind turbine and large point absorber floating wave energy converter—promising and challenging MJ Muliawan, M Karimirad, T Moan, Z Gao International Conference on Offshore Mechanics and Arctic Engineering 44946 …, 2012 | 86 | 2012 |
WindWEC: Combining Wind and Wave Energy Inspired by Hywind and Wavestar M Karimirad, K Koushan International Conference on Renewable Energy Research and Applications …, 2016 | 80 | 2016 |
Modeling aspects of a floating wind turbine for coupled wave–wind-induced dynamic analyses M Karimirad Renewable Energy 53, 299-305, 2013 | 79 | 2013 |
Real-time hybrid model tests of a braceless semi-submersible wind turbine: part III—calibration of a numerical model PA Berthelsen, EE Bachynski, M Karimirad, M Thys International conference on offshore mechanics and arctic engineering 49972 …, 2016 | 67 | 2016 |
Stochastic dynamic response analysis of spar-type wind turbines with catenary or taut mooring systems M Karimirad Norges teknisk-naturvitenskapelige universitet, Fakultet for …, 2011 | 67 | 2011 |
A review of floating photovoltaic design concepts and installed variations D Friel, M Karimirad, T Whittaker, WJ Doran, E Howlin 4th International Conference on Offshore Renewable Energy. CORE2019 …, 2019 | 61 | 2019 |
Feasibility of the application of a spar-type wind turbine at a moderate water depth M Karimirad, T Moan Energy Procedia 24, 340-350, 2012 | 52 | 2012 |
Combined effects of aerodynamic and second-order hydrodynamic loads for floating wind turbines at different water depths W Shi, L Zhang, M Karimirad, C Michailides, Z Jiang, X Li Applied Ocean Research 130, 103416, 2023 | 47 | 2023 |