| A path planning strategy unified with a COLREGS collision avoidance function based on deep reinforcement learning and artificial potential field L Li, D Wu, Y Huang, ZM Yuan Applied Ocean Research 113, 102759, 2021 | 232 | 2021 |
| Experimental study of a new type of floating breakwater CY Ji, X Chen, J Cui, ZM Yuan, A Incecik Ocean Engineering 105, 295-303, 2015 | 134 | 2015 |
| Maximization of energy absorption for a wave energy converter using the deep machine learning L Li, Z Yuan, Y Gao Energy 165, 340-349, 2018 | 112 | 2018 |
| Experimental and numerical investigation of WEC-type floating breakwaters: A single-pontoon oscillating buoy and a dual-pontoon oscillating water column Y Cheng, L Fu, S Dai, M Collu, C Ji, Z Yuan, A Incecik Coastal Engineering 177, 104188, 2022 | 100 | 2022 |
| Dynamic response and power production of a floating integrated wind, wave and tidal energy system L Li, Y Gao, Z Yuan, S Day, Z Hu Renewable energy 116, 412-422, 2018 | 98 | 2018 |
| Experimental and numerical analysis of a hybrid WEC-breakwater system combining an oscillating water column and an oscillating buoy Y Cheng, L Fu, S Dai, M Collu, L Cui, Z Yuan, A Incecik Renewable and Sustainable Energy Reviews 169, 112909, 2022 | 93 | 2022 |
| Numerical study on a hybrid mooring system with clump weights and buoys ZM Yuan, A Incecik, C Ji Ocean engineering 88, 1-11, 2014 | 93 | 2014 |
| 3D experimental study on a cylindrical floating breakwater system CY Ji, GUO Yu-Chan, J Cui, ZM Yuan, XJ Ma Ocean Engineering 125, 38-50, 2016 | 72 | 2016 |
| Review on the development of marine floating photovoltaic systems W Shi, C Yan, Z Ren, Z Yuan, Y Liu, S Zheng, X Li, X Han Ocean Engineering 286, 115560, 2023 | 70 | 2023 |
| On the sensitivity and uncertainty of wave energy conversion with an artificial neural-network-based controller L Li, Z Gao, ZM Yuan Ocean Engineering 183, 282-293, 2019 | 70 | 2019 |
| Wind field effect on the power generation and aerodynamic performance of offshore floating wind turbines L Li, Y Liu, Z Yuan, Y Gao Energy 157, 379-390, 2018 | 65 | 2018 |
| Model test research of a semisubmersible floating wind turbine with an improved deficient thrust force correction approach L Li, Y Gao, Z Hu, Z Yuan, S Day, H Li Renewable energy 119, 95-105, 2018 | 56 | 2018 |
| Hydrodynamics and stability of oblique water entry in waves Z Li, H Hu, C Wang, Z Xie, X Chen, Z Yuan, P Du Ocean Engineering 292, 116506, 2024 | 55 | 2024 |
| Dynamic and structural performances of offshore floating wind turbines in turbulent wind flow L Li, Y Liu, Z Yuan, Y Gao Ocean Engineering 179, 92-103, 2019 | 55 | 2019 |
| Hydrodynamic characteristics of a hybrid oscillating water column-oscillating buoy wave energy converter integrated into a π-type floating breakwater Y Cheng, W Du, S Dai, C Ji, M Collu, M Cocard, L Cui, Z Yuan, A Incecik Renewable and Sustainable Energy Reviews 161, 112299, 2022 | 51 | 2022 |
| Wave energy extraction and hydroelastic response reduction of modular floating breakwaters as array wave energy converters integrated into a very large floating structure Y Cheng, C Xi, S Dai, C Ji, M Collu, M Li, Z Yuan, A Incecik Applied Energy 306, 117953, 2022 | 51 | 2022 |
| Short-term extreme response and fatigue damage of an integrated offshore renewable energy system L Li, Z Cheng, Z Yuan, Y Gao Renewable Energy 126, 617-629, 2018 | 50 | 2018 |
| Manoeuvring prediction based on CFD generated derivatives S He, P Kellett, Z Yuan, A Incecik, O Turan, E Boulougouris Journal of hydrodynamics 28 (2), 284-292, 2016 | 49 | 2016 |
| Hydrodynamic interactions between two ships travelling or stationary in shallow waters ZM Yuan, A Incecik, S Dai, D Alexander, CY Ji, X Zhang Ocean Engineering 108, 620-635, 2015 | 49 | 2015 |
| Study on applicability of energy-saving devices to hydrogen fuel cell-powered ships C Stark, Y Xu, M Zhang, Z Yuan, L Tao, W Shi Journal of Marine Science and Engineering 10 (3), 388, 2022 | 47 | 2022 |
Atilla IncecikProfessor of Ocean Engineering, University of Strathclydeبريد إلكتروني تم التحقق منه على strath.ac.uk
