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Wei Meng 0003
Person information
- affiliation: University of Leeds, School of Electronic and Electrical Engineering, UK
- affiliation (PhD 2016): Wuhan University of Technology, School of Information Engineering / Key Laboratory of Fiber Optic Sensing Technology and Information Processing, China
- affiliation (PhD 2016): University of Auckland, Department of Mechanical Engineering, New Zealand
Other persons with the same name
- Wei Meng — disambiguation page
- Wei Meng 0001
— The Chinese University of Hong Kong (and 1 more)
- Wei Meng 0002
- Wei Meng 0004
- Wei Meng 0005
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2020 – today
- 2024
- [j26]Qingsong Ai
Uncertainty Compensated High-Order Adaptive Iteration Learning Control for Robot-Assisted Upper Limb Rehabilitation. IEEE Trans Autom. Sci. Eng. 21(4): 7004-7015 (2024) - [j25]Zemin Liu
Human-Like Trajectory Planning Based on Postural Synergistic Kernelized Movement Primitives for Robot-Assisted Rehabilitation. IEEE Trans. Hum. Mach. Syst. 54(2): 152-161 (2024) - [j24]Fazheng Hou
MECAM: A Novel Multi-Axis EEG Channel Attention Model for Emotion Recognition. IEEE Trans. Instrum. Meas. 73: 1-13 (2024) - 2023
- [j23]Wei Meng
CBR-RBR fusion based parametric rapid construction method of bridge BIM model. Adv. Eng. Informatics 57: 102086 (2023) - [j22]Qingsong Ai
Machine Learning in Robot-Assisted Upper Limb Rehabilitation: A Focused Review. IEEE Trans. Cogn. Dev. Syst. 15(4): 2053-2063 (2023) - [j21]Jie Zuo
Event-Triggered Adaptive Hybrid Torque-Position Control (ET-AHTPC) for Robot-Assisted Ankle Rehabilitation. IEEE Trans. Ind. Electron. 70(5): 4993-5003 (2023) - [c45]Yujia Liao, Quan Liu, Jie Zuo, Wei Meng
The Application of Hybrid Dynamic Recurrent Fuzzy Neural Network in Lower Limb Rehabilitation Function Evaluation. ICIRA (2) 2023: 173-184 - [c44]Yunli Xia, Haojie Liu, Chang Zhu, Wei Meng
Prediction of Elbow Torque Using Improved African Vultures Optimization Algorithm in Neuromusculoskeletal Model. ICIRA (5) 2023: 291-302 - [c43]Zunmei Tian, Haojie Liu, Chang Zhu, Wei Meng
Hybrid APFPSO Algorithm for Accurate Model-Free Motion Control of a Knee Exoskeleton. ICIRA (2) 2023: 422-431 - [c42]Long Chen, Wei Meng, Chang Zhu, Haojie Liu, Yifei Zhou, Quan Liu:
Multi-Objective Trajectory Planning Based on Integrated NSGA-III for Isokinetic Rehabilitation. M2VIP 2023: 1-6 - [c41]Dong Liu, Yuxuan Zhang, Nian Peng, Haojie Liu, Wei Meng, Quan Liu:
Wearable Flexible Optical Fiber Sensors for Human Motion Intention Recognition. M2VIP 2023: 1-6 - [c40]Yifu Qiao, Wei Meng, Haojie Liu, Nian Peng, Quan Liu:
Design and Validation of Grid Structure Optical Fiber Sensor for Wearable Physiological Monitoring. M2VIP 2023: 1-6 - 2022
- [j20]Wei Meng
A lightweight CNN and Transformer hybrid model for mental retardation screening among children from spontaneous speech. Comput. Biol. Medicine 151(Part): 106281 (2022) - [j19]Quan Liu
Design and Hierarchical Force-Position Control of Redundant Pneumatic Muscles-Cable-Driven Ankle Rehabilitation Robot. IEEE Robotics Autom. Lett. 7(1): 502-509 (2022) - [j18]Quan Liu, Mengnan Li, Chaoyue Yin, Guoming Qian, Wei Meng
CNN-Based Hand Grasping Prediction and Control via Postural Synergy Basis Extraction. Sensors 22(3): 831 (2022) - [j17]Zhenhong Li
Bearing-Only Formation Control With Prespecified Convergence Time. IEEE Trans. Cybern. 52(1): 620-629 (2022) - [c39]Yunfei Dong, Qingsong Ai, Haojie Liu, Wei Meng
Design and Control of a SEA Driven Knee Exoskeleton for Walking Assistance. AIM 2022: 1243-1248 - [c38]Zhixiong Zhou, Qingsong Ai, Wei Meng
Design and Finite Element Modeling of Novel Flat Pneumatic Artificial Muscles. AIM 2022: 1341-1346 - [c37]Nian Peng, Wei Meng
Gait Analysis and Phase Recognition Based on Array Fiber Optic Sensing Insole. ICIRA (3) 2022: 37-48 - [c36]Wenbin Sun, Quan Liu, Qiang Luo, Qingsong Ai, Wei Meng
Flexible Lightweight Graphene-Based Electrodes and Angle Sensor for Human Motion Detection. ICIRA (3) 2022: 150-161 - [c35]Yanan Ma, Quan Liu, Haojie Liu, Wei Meng
sEMG-Based Estimation of Human Arm Endpoint Stiffness Using Long Short-Term Memory Neural Networks and Autoencoders. ICIRA (2) 2022: 699-710 - [c34]Xianliang Xie, Quan Liu, Wei Meng
ZNN-Based High-Order Model-Free Adaptative Iterative Learning Control of Ankle Rehabilitation Robot Driven by Pneumatic Artificial Muscles. ICIRA (2) 2022: 773-784 - [c33]Yao Dai, Wei Meng
Construction and Analysis of Balance Ability Test Model Based on Multi-modal Parameters. ICMRE 2022: 163-168 - [c32]Mengnan Li, Qingsong Ai, Wei Meng
Design and modeling of fiber reinforced bending pneumatic flexible actuator based on asymmetric chamber. ROBIO 2022: 2051-2056 - 2021
- [j16]Quan Liu
Design and Control of a Reconfigurable Upper Limb Rehabilitation Exoskeleton With Soft Modular Joints. IEEE Access 9: 166815-166824 (2021) - [j15]Qingsong Ai, Wei Meng
Editorial for FGCS special issue: Intelligent IoT systems for healthcare and rehabilitation. Future Gener. Comput. Syst. 125: 770-773 (2021) - [j14]Quan Liu, Yang Liu, Yi Li, Chang Zhu, Wei Meng
Path Planning and Impedance Control of a Soft Modular Exoskeleton for Coordinated Upper Limb Rehabilitation. Frontiers Neurorobotics 15: 745531 (2021) - [j13]Quan Liu
sEMG-Based Dynamic Muscle Fatigue Classification Using SVM With Improved Whale Optimization Algorithm. IEEE Internet Things J. 8(23): 16835-16844 (2021) - [c31]Chang Zhu, Quan Liu, Wei Meng
An Attention-Based CNN-LSTM Model with Limb Synergy for Joint Angles Prediction. AIM 2021: 747-752 - [c30]Lu Jia, Qingsong Ai, Wei Meng
Individualized Gait Trajectory Prediction Based on Fusion LSTM Networks for Robotic Rehabilitation Training. AIM 2021: 988-993 - [c29]Zhili Ruan, Qingsong Ai, Kun Chen, Li Ma, Quan Liu, Wei Meng
Simultaneous and Continuous Motion Estimation of Upper Limb Based on SEMG and LSTM. ICIRA (1) 2021: 313-324 - [c28]Feifei Shao, Wei Meng
Neural Network Adaptive Control of Hand Rehabilitation Robot Driven by Flexible Pneumatic Muscles. ICMRE 2021: 59-63 - [c27]Xuanqi Yu, Wei Meng
Multi-objective Trajectory Optimization of Redundant Manipulator for Patient Assistance. M2VIP 2021: 66-71 - [c26]Mengyuan Zhao, Qingsong Ai, Wenbin Sun, Rongguo Song, Wei Meng
Graphene-based Motion Angle and Pressure Sensors for Lightweight and Flexible Wearable Devices. M2VIP 2021: 509-514 - [c25]Chaoyue Yin, Quan Liu, Wei Meng
Quantitative evaluation of hand functions using a wearable glove with multiple sensors. RCAR 2021: 1093-1098 - 2020
- [j12]Qingsong Ai
High-Order Model-Free Adaptive Iterative Learning Control of Pneumatic Artificial Muscle With Enhanced Convergence. IEEE Trans. Ind. Electron. 67(11): 9548-9559 (2020) - [c24]Yi Li, Quan Liu, Wei Meng
MISO Model Free Adaptive Control of Single Joint Rehabilitation Robot Driven by Pneumatic Artificial Muscles. AIM 2020: 1700-1705 - [c23]Yuanlong Xie, Xiaolong Zhang, Wei Meng
Coupled Sliding Mode Control of an Omnidirectional Mobile Robot with Variable Modes*. AIM 2020: 1792-1797 - [c22]Jiaming Zhang, Lin Zhang, Shaocong Guo, Wei Meng
Iterative Learning Control of Functional Electrical Stimulation Based on Joint Muscle Model. CIIS 2020: 119-123
2010 – 2019
- 2019
- [j11]Quan Liu, Guoming Qian, Wei Meng
A new IMMU-based data glove for hand motion capture with optimized sensor layout. Int. J. Intell. Robotics Appl. 3(1): 19-32 (2019) - [j10]Qingsong Ai, Yuan Peng, Jie Zuo, Wei Meng
Hammerstein model for hysteresis characteristics of pneumatic muscle actuators. Int. J. Intell. Robotics Appl. 3(1): 33-44 (2019) - [c21]Wenhao Zheng, Quan Liu, Kun Chen, Qingsong Ai, Wei Meng
Brain-robot Shared Control Based on Motor Imagery and Improved Bayes Filter*. AIM 2019: 139-144 - [c20]Zemin Liu, Qingsong Ai, Yaojie Liu, Jie Zuo, Xiong Zhang, Wei Meng
An Optimal Motion Planning Method of 7-DOF Robotic Arm for Upper Limb Movement Assistance. AIM 2019: 277-282 - [c19]Ziad Abass, Wei Meng
A Robust, Practical Upper Limb Electromyography Interface Using Dry 3D Printed Electrodes*. AIM 2019: 453-458 - [c18]Wei Meng
Design and Modelling of a Compliant Ankle Rehabilitation Robot Redundantly Driven by Pneumatic Muscles. AIM 2019: 459-464 - [c17]Lin Wu, Sheng Quan Xie
Energy Efficiency of Gait Rehabilitation Robot: A Review. AIM 2019: 465-470 - [c16]Weifeng Wu, Da Li, Wei Meng
Iterative Feedback Tuning-based Model-Free Adaptive Iterative Learning Control of Pneumatic Artificial Muscle. AIM 2019: 954-959 - [c15]Jie Zuo
Coupling Disturbance Compensated MIMO Control of Parallel Ankle Rehabilitation Robot Actuated by Pneumatic Muscles. IROS 2019: 6608-6613 - 2018
- [j9]Naqash Rehmat, Jie Zuo
Upper limb rehabilitation using robotic exoskeleton systems: a systematic review. Int. J. Intell. Robotics Appl. 2(3): 283-295 (2018) - [j8]Qingsong Ai
Disturbance-Estimated Adaptive Backstepping Sliding Mode Control of a Pneumatic Muscles-Driven Ankle Rehabilitation Robot. Sensors 18(1): 66 (2018) - [j7]Mingming Zhang
Adaptive Patient-Cooperative Control of a Compliant Ankle Rehabilitation Robot (CARR) With Enhanced Training Safety. IEEE Trans. Ind. Electron. 65(2): 1398-1407 (2018) - [c14]Quan Liu, Liangyun Ma, Qingsong Ai, Kun Chen, Wei Meng
Knee Joint Angle Prediction Based on Muscle Synergy Theory and Generalized Regression Neural Network. AIM 2018: 28-32 - [c13]Xiaorong Feng, Qingsong Ai, Wei Meng
KUKA Real-Time Control through Angle Estimation of Wrist from sEMG with Support Vector Regression. CSAI/ICIMT 2018: 389-393 - [c12]Xingxing Guo, Quan Liu, Jie Zuo, Wei Meng
A Novel Pneumatic Artificial Muscle -driven Robot for Multi-joint Progressive Rehabilitation. ICDL-EPIROB 2018: 78-83 - [c11]Qingsong Ai, Congsheng Zhang, Weifeng Wu, Chi Zhang, Wei Meng
Design and implementation of haptic sensing interface for ankle rehabilitation robotic platform. ICNSC 2018: 1-6 - 2017
- [j6]Quan Liu, Aiming Liu, Wei Meng
Hierarchical Compliance Control of a Soft Ankle Rehabilitation Robot Actuated by Pneumatic Muscles. Frontiers Neurorobotics 11: 64 (2017) - [c10]Wei Meng
Compliance adaptation of an intrinsically soft ankle rehabilitation robot driven by pneumatic muscles. AIM 2017: 82-87 - [c9]Chi Zhang, Jiwei Hu, Qingsong Ai, Wei Meng
Impedance Control of a Pneumatic Muscles-Driven Ankle Rehabilitation Robot. ICIRA (1) 2017: 301-312 - [c8]Da Ke, Qingsong Ai, Wei Meng
Fuzzy PD-Type Iterative Learning Control of a Single Pneumatic Muscle Actuator. ICIRA (2) 2017: 812-822 - [c7]Congsheng Zhang, Qingsong Ai, Wei Meng
A Subject-Specific EMG-Driven Musculoskeletal Model for the Estimation of Moments in Ankle Plantar-Dorsiflexion Movement. ICONIP (4) 2017: 685-693 - [c6]Min Li, Wei Meng
Adaptive Sliding Mode Control of Functional Electrical Stimulation (FES) for Tracking Knee Joint Movement. ISCID (1) 2017: 346-349 - 2016
- [j5]Qingsong Ai, Bo Ding, Quan Liu, Wei Meng
A Subject-Specific EMG-Driven Musculoskeletal Model for Applications in Lower-Limb Rehabilitation Robotics. Int. J. Humanoid Robotics 13(3): 1650005:1-1650005:22 (2016) - [j4]Liang Zhou, Wei Meng
Bio-Inspired Design and Iterative Feedback Tuning Control of a Wearable Ankle Rehabilitation Robot. J. Comput. Inf. Sci. Eng. 16(4) (2016) - [j3]Mingming Zhang
A Robot-Driven Computational Model for Estimating Passive Ankle Torque With Subject-Specific Adaptation. IEEE Trans. Biomed. Eng. 63(4): 814-821 (2016) - 2015
- [c5]Wei Meng
Design and control of a robotic wrist orthosis for joint rehabilitation. AIM 2015: 1235-1240 - [c4]Mingming Zhang
Model based open-loop posture control of a parallel ankle assessment and rehabilitation robot. AIM 2015: 1241-1246 - 2014
- [j2]Quan Liu, Dong Liu, Wei Meng
Fuzzy Sliding Mode Control of a Multi-DOF Parallel Robot in Rehabilitation Environment. Int. J. Humanoid Robotics 11(1) (2014) - [j1]Wei Meng, Quan Liu, Zude Zhou, Qingsong Ai:
Active interaction control applied to a lower limb rehabilitation robot by using EMG recognition and impedance model. Ind. Robot 41(5): 465-479 (2014) - [c3]Wei Meng
Active interaction control of a rehabilitation robot based on motion recognition and adaptive impedance control. FUZZ-IEEE 2014: 1436-1441 - [c2]Wei Meng
An EMG-based force prediction and control approach for robot-assisted lower limb rehabilitation. SMC 2014: 2198-2203 - 2011
- [c1]Wei Meng
A Cyber-Physical System for Public Environment Perception and Emergency Handling. HPCC 2011: 734-738
Coauthor Index
[j26] [j25] [j24] [j23] [j22] [j21] [c45] [j19] [j18] [c39] [c38] [c36] [c34] [c33] [c32] [j16] [j15] [j14] [j13] [c31] [c30] [c29] [c28] [c27] [c26] [c25] [j12] [c24] [c22] [j11] [j10] [c21] [c20] [c18] [c16] [c15] [j8] [c14] [c13] [c12] [c11] [j6] [c10] [c9] [c8] [c7] [j5] [j4] [j2] [j1] [c3] [c2]
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last updated on 2024-11-19 20:43 CET by the dblp team
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