A reliability based design methodology for extreme responses of offshore wind turbines PW Cheng DUWIND Delft University Wind Energy Research Institute, 2002 | 117 | 2002 |
Field testing of feedforward collective pitch control on the CART2 using a nacelle-based lidar scanner D Schlipf, P Fleming, F Haizmann, A Scholbrock, M Hofsäß, A Wright, ... Journal of Physics: Conference Series 555 (1), 012090, 2014 | 116 | 2014 |
Nonlinear model predictive control of floating wind turbines with individual pitch control S Raach, D Schlipf, F Sandner, D Matha, PW Cheng 2014 American control conference, 4434-4439, 2014 | 108 | 2014 |
Stochastic gust model for design calculations of wind turbines W Bierbooms, PW Cheng Journal of Wind Engineering and Industrial Aerodynamics 90 (11), 1237-1251, 2002 | 71 | 2002 |
Model of the correlation between lidar systems and wind turbines for lidar-assisted control D Schlipf, PW Cheng, J Mann Journal of Atmospheric and Oceanic Technology 30 (10), 2233-2240, 2013 | 66 | 2013 |
Reliability‐based design methods to determine the extreme response distribution of offshore wind turbines PW Cheng, GJW Van Bussel, GAM van Kuik, JH Vugts Wind Energy: An International Journal for Progress and Applications in Wind …, 2003 | 60 | 2003 |
Comparison of feedforward and model predictive control of wind turbines using LIDAR D Schlipf, LY Pao, PW Cheng 2012 IEEE 51st IEEE Conference on Decision and Control (CDC), 3050-3055, 2012 | 58 | 2012 |
Efficient preliminary floating offshore wind turbine design and testing methodologies and application to a concrete spar design D Matha, F Sandner, C Molins, A Campos, PW Cheng Philosophical Transactions of the Royal Society A: Mathematical, Physical …, 2015 | 55 | 2015 |
Lidar-based wake tracking for closed-loop wind farm control S Raach, D Schlipf, PW Cheng Wind Energy Science 2 (1), 257-267, 2017 | 54 | 2017 |
Control design methods for floating wind turbines for optimal disturbance rejection F Lemmer, D Schlipf, PW Cheng Journal of Physics: Conference Series 753 (9), 092006, 2016 | 53 | 2016 |
The triple spar campaign: Implementation and test of a blade pitch controller on a scaled floating wind turbine model W Yu, F Lemmer, H Bredmose, M Borg, A Pegalajar-Jurado, ... Energy Procedia 137, 323-338, 2017 | 51 | 2017 |
Coupled MBS-CFD simulation of the IDEOL floating offshore wind turbine foundation compared to wave tank model test data F Beyer, T Choisnet, M Kretschmer, PW Cheng ISOPE International Ocean and Polar Engineering Conference, ISOPE-I-15-272, 2015 | 51 | 2015 |
Comparison of linear and nonlinear model predictive control of wind turbines using LIDAR D Schlipf, P Grau, S Raach, R Duraiski, J Trierweiler, PW Cheng 2014 American Control Conference, 3742-3747, 2014 | 51 | 2014 |
Nonlinear model predictive control of floating wind turbines D Schlipf, F Sandner, S Raach, D Matha, PW Cheng ISOPE International Ocean and Polar Engineering Conference, ISOPE-I-13-191, 2013 | 51 | 2013 |
Reduced nonlinear model of a spar-mounted floating wind turbine F Sandner, D Schlipf, D Matha, R Seifried, PW Cheng | 50 | 2012 |
Collective pitch feedforward control of floating wind turbines using lidar D Schipf, E Simley, F Lemmer, L Pao, PW Cheng ISOPE International Ocean and Polar Engineering Conference, ISOPE-I-15-755, 2015 | 49 | 2015 |
Integrated optimization of floating wind turbine systems F Sandner, D Schlipf, D Matha, PW Cheng International Conference on Offshore Mechanics and Arctic Engineering 45547 …, 2014 | 45 | 2014 |
Multibody modeling for concept-level floating offshore wind turbine design F Lemmer, W Yu, B Luhmann, D Schlipf, PW Cheng Multibody system dynamics 49 (2), 203-236, 2020 | 44 | 2020 |
Robust gain scheduling baseline controller for floating offshore wind turbines F Lemmer, W Yu, D Schlipf, PW Cheng Wind Energy 23 (1), 17-30, 2020 | 42 | 2020 |
Three dimensional dynamic model based wind field reconstruction from lidar data S Raach, D Schlipf, F Haizmann, PW Cheng Journal of Physics: Conference Series 524 (1), 012005, 2014 | 42 | 2014 |