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Xiaowei Zhao 0001
Person information
- affiliation: University of Warwick, School of Engineering, Coventry, UK
- affiliation (former): University of Oxford, Department of Engineering Science, UK
- affiliation (former): Imperial College London, Department of Electrical and Electronic Engineering, UK
Other persons with the same name
- Xiaowei Zhao — disambiguation page
- Xiaowei Zhao 0002
— Northwestern Polytechnical University, School of Computer Science, iOPEN, Xi'an, China
- Xiaowei Zhao 0003
- Xiaowei Zhao 0004
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2020 – today
- 2024
- [j40]Zhaolong Wu
Parameter-Separable Prox-Lagrangian Method for Convex-Concave Saddle Point Problem. IEEE Control. Syst. Lett. 8: 253-258 (2024) - [j39]Haoyang Yang
Safety-Critical Control Allocation for Obstacle Avoidance of Quadrotor Aerial Photography. IEEE Control. Syst. Lett. 8: 1973-1978 (2024) - [j38]Jingjie Xie
Power Regulation and Load Mitigation of Floating Wind Turbines via Reinforcement Learning. IEEE Trans Autom. Sci. Eng. 21(3): 4328-4339 (2024) - [j37]Guilong Liu
Novel Nussbaum Design for Nonlinear Systems With Unknown Switching Control Directions. IEEE Trans. Circuits Syst. II Express Briefs 71(4): 2244-2248 (2024) - [j36]Yexin Fan, Hongyang Dong
Path-Following Control of Unmanned Underwater Vehicle Based on an Improved TD3 Deep Reinforcement Learning. IEEE Trans. Control. Syst. Technol. 32(5): 1904-1919 (2024) - [j35]Guilong Liu
Adaptive Fuzzy Practical Bipartite Synchronization for Multiagent Systems With Intermittent Feedback Under Multiple Unknown Control Directions. IEEE Trans. Fuzzy Syst. 32(5): 3211-3225 (2024) - [j34]Rui Li
LSwinSR: UAV Imagery Super-Resolution Based on Linear Swin Transformer. IEEE Trans. Geosci. Remote. Sens. 62: 1-13 (2024) - [j33]Yubo Huang
Reinforcement Learning-Based Multiobjective Control of Grid-Connected Wind Farms. IEEE Trans. Ind. Informatics 20(5): 7380-7390 (2024) - 2023
- [j32]Yongfeng Lv
Inverse-model-based iterative learning control for unknown MIMO nonlinear system with neural network. Neurocomputing 519: 187-193 (2023) - [j31]Yongfeng Lv
Data-Based Optimal Microgrid Management for Energy Trading With Integral Q-Learning Scheme. IEEE Internet Things J. 10(18): 16183-16193 (2023) - [j30]Hongyang Dong
Data-Driven Wind Farm Control via Multiplayer Deep Reinforcement Learning. IEEE Trans. Control. Syst. Technol. 31(3): 1468-1475 (2023) - [j29]Yanchang Liang
A Multiagent Reinforcement Learning Approach for Wind Farm Frequency Control. IEEE Trans. Ind. Informatics 19(2): 1725-1734 (2023) - [j28]Hongyang Dong
Reinforcement Learning-Based Wind Farm Control: Toward Large Farm Applications via Automatic Grouping and Transfer Learning. IEEE Trans. Ind. Informatics 19(12): 11833-11845 (2023) - [j27]Yongfeng Lv
Multi-H∞ Controls for Unknown Input-Interference Nonlinear System With Reinforcement Learning. IEEE Trans. Neural Networks Learn. Syst. 34(9): 5601-5613 (2023) - 2022
- [j26]Hongyang Dong
Learning-Based Attitude Tracking Control With High-Performance Parameter Estimation. IEEE Trans. Aerosp. Electron. Syst. 58(3): 2218-2230 (2022) - [j25]Hongyang Dong
Composite Experience Replay-Based Deep Reinforcement Learning With Application in Wind Farm Control. IEEE Trans. Control. Syst. Technol. 30(3): 1281-1295 (2022) - [j24]Haoyang Yang
ADP-Based Spacecraft Attitude Control Under Actuator Misalignment and Pointing Constraints. IEEE Trans. Ind. Electron. 69(9): 9342-9352 (2022) - [j23]Hongyang Dong
Wind-Farm Power Tracking Via Preview-Based Robust Reinforcement Learning. IEEE Trans. Ind. Informatics 18(3): 1706-1715 (2022) - [j22]Jingjie Xie
Wind Farm Power Generation Control Via Double-Network-Based Deep Reinforcement Learning. IEEE Trans. Ind. Informatics 18(4): 2321-2330 (2022) - [j21]Priyank Shah
Network Identification Using μ-PMU and Smart Meter Measurements. IEEE Trans. Ind. Informatics 18(11): 7572-7586 (2022) - [j20]Li Sun
Stability Analysis and Performance Improvement of Power Sharing Control in Islanded Microgrids. IEEE Trans. Smart Grid 13(6): 4665-4676 (2022) - [j19]Hongyang Dong
Optimal Tracking Control for Uncertain Nonlinear Systems With Prescribed Performance via Critic-Only ADP. IEEE Trans. Syst. Man Cybern. Syst. 52(1): 561-573 (2022) - [j18]Jincheng Zhang
Reinforcement Learning-Based Structural Control of Floating Wind Turbines. IEEE Trans. Syst. Man Cybern. Syst. 52(3): 1603-1613 (2022) - [c13]Hongyang Dong, Xiaowei Zhao:
Intelligent Wind Farm Control via Grouping-Based Reinforcement Learning. ECC 2022: 993-998 - [c12]Rui Li
Deep learning-based wind farm power prediction using Transformer network. ECC 2022: 1018-1023 - 2021
- [j17]Qinglei Hu
Learning-Based 6-DOF Control for Autonomous Proximity Operations Under Motion Constraints. IEEE Trans. Aerosp. Electron. Syst. 57(6): 4097-4109 (2021) - [j16]Hongyang Dong
Reinforcement Learning-Based Approximate Optimal Control for Attitude Reorientation Under State Constraints. IEEE Trans. Control. Syst. Technol. 29(4): 1664-1673 (2021) - [j15]Xiuxing Yin, Xiaowei Zhao
Deep Neural Learning Based Distributed Predictive Control for Offshore Wind Farm Using High-Fidelity LES Data. IEEE Trans. Ind. Electron. 68(4): 3251-3261 (2021) - 2020
- [j14]Xiuxing Yin
Composite Hierarchical Pitch Angle Control for a Tidal Turbine Based on the Uncertainty and Disturbance Estimator. IEEE Trans. Ind. Electron. 67(1): 329-339 (2020)
2010 – 2019
- 2019
- [j13]Xing Wei, Bing Feng Ng
Aeroelastic load control of large and flexible wind turbines through mechanically driven flaps. J. Frankl. Inst. 356(14): 7810-7835 (2019) - [j12]Pengyuan Qi
Autonomous Landing Control of Highly Flexible Aircraft Based on Lidar Preview in the Presence of Wind Turbulence. IEEE Trans. Aerosp. Electron. Syst. 55(5): 2543-2555 (2019) - 2018
- [j11]Pengyuan Qi
Aeroelastic and Trajectory Control of High Altitude Long Endurance Aircraft. IEEE Trans. Aerosp. Electron. Syst. 54(6): 2992-3003 (2018) - [j10]Xin Tong, Xiaowei Zhao
Power Generation Control of a Monopile Hydrostatic Wind Turbine Using an ℋ∞ Loop-Shaping Torque Controller and an LPV Pitch Controller. IEEE Trans. Control. Syst. Technol. 26(6): 2165-2172 (2018) - [c11]Pengyuan Qi, Xiaowei Zhao, Yinan Wang, Rafael Palacios, Andrew Wynn
Automatic Landing Control of a Very Flexible Flying Wing. ACC 2018: 2599-2604 - [c10]Xiaowei Zhao, George Weiss
Strong stability of a coupled system composed of impedance-passive linear systems which may both have imaginary eigenvalues. CDC 2018: 521-526 - [c9]Pengyuan Qi, Xiaowei Zhao, Rafael Palacios:
Preview-Based Altitude Control for a Very Flexible Flying Wing with Lidar Wind Measurements. CDC 2018: 4289-4294 - 2017
- [j9]Xiaowei Zhao
Stability Properties of Coupled Impedance Passive LTI Systems. IEEE Trans. Autom. Control. 62(11): 5769-5779 (2017) - [c8]Pengyuan Qi, Yinan Wang, Xiaowei Zhao, Rafael Palacios, Andrew Wynn
Trajectory control of a very flexible flying wing. ACC 2017: 4480-4485 - 2016
- [j8]Kevin Gouder
Experimental Aerodynamic Control of a Long-Span Suspension Bridge Section Using Leading- and Trailing-Edge Control Surfaces. IEEE Trans. Control. Syst. Technol. 24(4): 1441-1453 (2016) - 2015
- [c7]Xiaowei Zhao, George Weiss
Strong stabilization of the SCOLE model using a tuned mass damper. SIAM Conf. on Control and its Applications 2015: 447-453 - 2014
- [j7]Xiaowei Zhao, George Weiss
Strong stabilisation of a wind turbine tower model in the plane of the turbine blades. Int. J. Control 87(10): 2027-2034 (2014) - [c6]Xiaowei Zhao, Kevin Gouder
Experimental flutter and buffet suppression of a sectional suspended-bridge. CDC 2014: 3197-3202 - 2011
- [j6]David J. N. Limebeer, J. Michael R. Graham, Xiaowei Zhao:
Buffet suppression in long-span suspension bridges. Annu. Rev. Control. 35(2): 235-246 (2011) - [j5]Xiaowei Zhao, George Weiss
Well-posedness and controllability of a wind turbine tower model. IMA J. Math. Control. Inf. 28(1): 103-119 (2011) - [j4]Xiaowei Zhao, George Weiss
Suppression of the vibrations of wind turbine towers. IMA J. Math. Control. Inf. 28(3): 377-389 (2011) - [j3]Xiaowei Zhao, George Weiss
Controllability and Observability of a Well-Posed System Coupled With a Finite-Dimensional System. IEEE Trans. Autom. Control. 56(1): 88-99 (2011) - [c5]Xiaowei Zhao, David J. N. Limebeer, J. Michael R. Graham:
Flutter control of long-span suspension bridges. CDC/ECC 2011: 4195-4200 - 2010
- [j2]Xiaowei Zhao, George Weiss
Well-posedness, regularity and exact controllability of the SCOLE model. Math. Control. Signals Syst. 22(2): 91-127 (2010) - [c4]Xiaowei Zhao, George Weiss
Well-posedness and generic exact controllability of coupled systems. CDC 2010: 2560-2565 - [c3]Xiaowei Zhao, George Weiss
Exact controllability of a wind turbine tower model in the plane of the turbine blades. CDC 2010: 6914-6919
2000 – 2009
- 2009
- [j1]George Weiss
Well-Posedness and Controllability of a Class of Coupled Linear Systems. SIAM J. Control. Optim. 48(4): 2719-2750 (2009) - [c2]Xiaowei Zhao, George Weiss
Controllability and observability of coupled systems. CDC 2009: 5520-5525 - [c1]Xiaowei Zhao, George Weiss
Strong stabilization of a wind turbine tower model. CDC 2009: 5526-5531
Coauthor Index
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last updated on 2024-12-02 22:26 CET by the dblp team
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