| Improvement of boom control performance for hybrid hydraulic excavator with potential energy recovery T Wang, Q Wang, T Lin Automation in construction 30, 161-169, 2013 | 128 | 2013 |
| An energy-saving pressure-compensated hydraulic system with electrical approach T Wang, Q Wang IEEE/ASME transactions on mechatronics 19 (2), 570-578, 2014 | 116 | 2014 |
| Pendulum-based vibration energy harvesting: Mechanisms, transducer integration, and applications T Wang Energy Conversion and Management 276, 116469, 2023 | 77 | 2023 |
| Parameter identification and model-based nonlinear robust control of fluidic soft bending actuators T Wang, Y Zhang, Z Chen, S Zhu IEEE/ASME transactions on mechatronics 24 (3), 1346-1355, 2019 | 76 | 2019 |
| Efficiency analysis and evaluation of energy-saving pressure-compensated circuit for hybrid hydraulic excavator T Wang, Q Wang Automation in Construction 47, 62-68, 2014 | 72 | 2014 |
| Optimization design of a permanent magnet synchronous generator for a potential energy recovery system T Wang, Q Wang IEEE Transactions on Energy Conversion 27 (4), 856-863, 2012 | 63 | 2012 |
| A computationally efficient dynamical model of fluidic soft actuators and its experimental verification T Wang, Y Zhang, Y Zhu, S Zhu Mechatronics 58, 1-8, 2019 | 53 | 2019 |
| Design, modeling and experiments of a novel biaxial-pendulum vibration energy harvester H Lou, T Wang, S Zhu Energy 254, 124431, 2022 | 46 | 2022 |
| Model-free motion control of continuum robots based on a zeroing neurodynamic approach N Tan, P Yu, X Zhang, T Wang Neural Networks 133, 21-31, 2021 | 44 | 2021 |
| Design of permanent magnetic wheel-type adhesion-locomotion system for water-jetting wall-climbing robot W Song, H Jiang, T Wang, D Ji, S Zhu Advances in mechanical engineering 10 (7), 1687814018787378, 2018 | 41 | 2018 |
| Design and modeling of a hydraulic soft actuator with three degrees of freedom Q Xie, T Wang, S Yao, Z Zhu, N Tan, S Zhu Smart Materials and Structures 29 (12), 125017, 2020 | 39 | 2020 |
| Design and analysis of compound potential energy regeneration system for hybrid hydraulic excavator T Wang, Q Wang Proceedings of the Institution of Mechanical Engineers, Part I: Journal of …, 2012 | 34 | 2012 |
| Design, control, and experiments of a fluidic soft robotic eel Y Chen, T Wang, C Wu, X Wang Smart Materials and Structures 30 (6), 065001, 2021 | 24 | 2021 |
| Development and modeling of an electromagnetic energy harvester from pressure fluctuations H Ren, T Wang Mechatronics 49, 36-45, 2018 | 21 | 2018 |
| A compact hydrostatic-driven electric generator: Design, prototype, and experiment T Wang, Z Zhou IEEE/ASME Transactions on Mechatronics 21 (3), 1612-1619, 2015 | 20 | 2015 |
| Disturbance-observer-based sliding mode control design for nonlinear bilateral teleoperation system with four-channel architecture J Tang, F Huang, Z Chen, T Wang, J Gu, S Zhu IEEE Access 7, 72672-72683, 2019 | 19 | 2019 |
| A novel hybrid control strategy for potential energy regeneration systems of hybrid hydraulic excavators Q Chen, Q Wang, T Wang Proceedings of the Institution of Mechanical Engineers, Part I: Journal of …, 2016 | 18 | 2016 |
| In-situ wave energy harvesting for unmanned marine devices: A review F Zeng, T Wang Ocean Engineering 285, 115376, 2023 | 17 | 2023 |
| Analytical solution of magnetic field distribution in brushless permanent magnet machines with rotor axis deflection T Wang, Z Zhou IEEE Transactions on Magnetics 51 (4), 1-6, 2014 | 17 | 2014 |
| Analysis and experiments of a pendulum vibration energy harvester with a magnetic multi-stable mechanism T Wang, S Zhu IEEE Transactions on Magnetics 58 (8), 1-7, 2022 | 16 | 2022 |
