default search action
Shaoping Bai
Person information
SPARQL queries
Refine list
refinements active!
zoomed in on ?? of ?? records
view refined list in
export refined list as
2020 – today
- 2024
- [j32]Yu Zhu, Felix Balser, Ming Shen, Shaoping Bai:
Design and Evaluation of a Novel Passive Shoulder Exoskeleton Based on a Variable Stiffness Mechanism Torque Generator for Industrial Applications. Robotics 13(8): 120 (2024) - [j31]Lingzhou Yu, Shaoping Bai:
A Modified Dynamic Movement Primitive Algorithm for Adaptive Gait Control of a Lower Limb Exoskeleton. IEEE Trans. Hum. Mach. Syst. 54(6): 778-787 (2024) - [j30]Xiangyang Wang, Sheng Guo, Shaoping Bai:
A Cable-Driven Parallel Hip Exoskeleton for High-Performance Walking Assistance. IEEE Trans. Ind. Electron. 71(3): 2705-2715 (2024) - 2023
- [j29]Shaoping Bai:
Non-Orthogonal Moving Frame for the Kinematics of Parallel Pointing Mechanisms. IEEE Robotics Autom. Lett. 8(2): 997-1004 (2023) - [j28]Yu Zhu, Shaoping Bai:
Human Compatible Stiffness Modulation of a Novel VSA for Physical Human-Robot Interaction. IEEE Robotics Autom. Lett. 8(5): 3023-3030 (2023) - [j27]Majun Song, Weihai Chen, Sheng Guo, Zhongyi Li, John Rasmussen, Shaoping Bai:
Design, Simulation and Kinematic Verification of a Multi-Loop Ankle-Foot Prosthetic Mechanism. IEEE Robotics Autom. Lett. 8(9): 5767-5774 (2023) - [j26]Abdullah Tahir, Shaoping Bai, Ming Shen:
A Wearable Multi-Modal Digital Upper Limb Assessment System for Automatic Musculoskeletal Risk Evaluation. Sensors 23(10): 4863 (2023) - [j25]Abdullah Tahir, Zeliang An, Shaoping Bai, Ming Shen:
Robust Payload Recognition Based on Sensor-Over-Muscle-Independence Deep Learning for the Control of Exoskeletons. IEEE Trans. Circuits Syst. II Express Briefs 70(9): 3699-3703 (2023) - [j24]Xiangyang Wang, Sheng Guo, Bojian Qu, Shaoping Bai:
Design and Experimental Verification of a Hip Exoskeleton Based on Human-Machine Dynamics for Walking Assistance. IEEE Trans. Hum. Mach. Syst. 53(1): 85-97 (2023) - [c39]Changcong Wang, Chongyi Wei, Shaoping Bai, Yibin Li, Xincheng Tian, Lelai Zhou:
HCRI: A ROS2 Human Collision Object Interface for Robotic Manipulation Planning. RCAR 2023: 423-428 - [c38]Chongyi Wei, Changcong Wang, Shaoping Bai, Yibin Li, Xincheng Tian, Lelai Zhou:
Transfer Learning Based Multi-Perception Safety Strategy for Human-Robot Collaboration. RCAR 2023: 799-804 - 2022
- [j23]Felix Balser, Rohan Desai, Alexandros Ekizoglou, Shaoping Bai:
A Novel Passive Shoulder Exoskeleton Designed With Variable Stiffness Mechanism. IEEE Robotics Autom. Lett. 7(2): 2748-2754 (2022) - [j22]Felix Balser, Rohan Desai, Alexandros Ekizoglou, Shaoping Bai:
Corrections to "A Novel Passive Shoulder Exoskeleton Designed With Variable Stiffness Mechanism". IEEE Robotics Autom. Lett. 7(3): 7099 (2022) - [j21]Matteo Musso, Anderson Souza Oliveira, Shaoping Bai:
Modeling of a Non-Rigid Passive Exoskeleton-Mathematical Description and Musculoskeletal Simulations. Robotics 11(6): 147 (2022) - [j20]Mikkel Berg Thøgersen, Mostafa Mohammadi, Muhammad Ahsan Gull, Stefan Hein Bengtson, Frederik Victor Kobbelgaard, Bo Bentsen, Benjamin Yamin Ali Khan, Kåre Eg Severinsen, Shaoping Bai, Thomas Bak, Thomas Baltzer Moeslund, Anne Marie Kanstrup, Lotte N. S. Andreasen Struijk:
User Based Development and Test of the EXOTIC Exoskeleton: Empowering Individuals with Tetraplegia Using a Compact, Versatile, 5-DoF Upper Limb Exoskeleton Controlled through Intelligent Semi-Automated Shared Tongue Control. Sensors 22(18): 6919 (2022) - [j19]Weihai Chen, Libo Zhou, Jianhua Wang, Zheng Zhao, Wenjie Chen, Shaoping Bai:
A Maxwell-Slip Based Hysteresis Model for Nonlinear Stiffness Compliant Actuators. IEEE Trans. Ind. Electron. 69(11): 11510-11520 (2022) - [c37]Shaoping Bai:
Extended Rotation Matrix for Kinematics of Pointing Mechanisms. ARK 2022: 39-46 - [c36]Lotte N. S. Andreasen Struijk, Anne Marie Kanstrup, Shaoping Bai, Thomas Bak, Mikkel Thøgersen, Mostafa Mohammadi, Stefan Hein Bengtson, Frederik Victor Kobbelgaard, Muhammad Ahsan Gull, Bo Bentsen, Kåre Eg Severinsen, Helge Kasch, Thomas Baltzer Moeslund:
The impact of interdisciplinarity and user involvement on the design and usability of an assistive upper limb exoskeleton - a case study on the EXOTIC. ICORR 2022: 1-5 - [c35]Robin Otterbein, Elizabeth Jochum, Daniel Overholt, Shaoping Bai, Alex Dalsgaard:
Dance and Movement-Led Research for Designing and Evaluating Wearable Human-Computer Interfaces. MOCO 2022: 9:1-9:9 - [c34]Juwairiya Siraj Khan, Mostafa Mohammadi, John Rasmussen, Shaoping Bai, Lotte N. S. Andreasen Struijk:
A review on the design of assistive cable-driven upper-limb exoskeletons and their experimental evaluation. SMC 2022: 59-64 - 2021
- [c33]Juan de Dios Flores Mendez, Henrik Schiøler, Shaoping Bai, Ole Madsen:
Force estimation and control of Delta Robot for assembly. CCTA 2021: 640-647 - [c32]Kun Wang, Xiaoyong Wu, Yujin Wang, Bo Li, Bo Yuan, Shaoping Bai:
A Novel 2-SUR 6-DOF Parallel Manipulator Actuated by Spherical Motion Generators. IROS 2021: 8022-8028 - 2020
- [j18]Muhammad Raza Ul Islam, Shaoping Bai:
Effective Multi-Mode Grasping Assistance Control of a Soft Hand Exoskeleton Using Force Myography. Frontiers Robotics AI 7: 567491 (2020) - [j17]Muhammad Ahsan Gull, Shaoping Bai, Thomas Bak:
A Review on Design of Upper Limb Exoskeletons. Robotics 9(1): 16 (2020) - [j16]Yukio Takeda, Giuseppe Carbone, Shaoping Bai:
Advances in Robotics and Mechatronics. Robotics 9(2): 36 (2020) - [j15]Jingmeng Liu, Xuerong Li, Weihai Chen, Lu Liu, Shaoping Bai:
Magnetic field modeling and validation for a spherical actuator with cylindrical permanent magnets. Simul. Model. Pract. Theory 98 (2020) - [c31]Shaoping Bai, Rui Wu, Ruiqin Li:
Exact Coupler-Curve Synthesis of Four-Bar Linkages with Fully Analytical Solutions. ARK 2020: 82-89 - [c30]Libo Zhou, Weihai Chen, Wenjie Chen, Shaoping Bai, Jianhua Wang:
A Novel Portable Lower Limb Exoskeleton for Gravity Compensation during Walking. ICRA 2020: 768-773
2010 – 2019
- 2019
- [j14]Jingmeng Liu, Xuerong Li, Shaoxiong Cai, Weihai Chen, Shaoping Bai:
Adaptive fuzzy sliding mode algorithm-based decentralised control for a permanent magnet spherical actuator. Int. J. Syst. Sci. 50(2): 403-418 (2019) - [j13]Xuerong Li, Shaoping Bai, Ole Madsen:
Dynamic modeling and trajectory tracking control of an electromagnetic direct driven spherical motion generator. Robotics Comput. Integr. Manuf. 59: 201-212 (2019) - [j12]Weihai Chen, Zhongyi Li, Xiang Cui, Jianbin Zhang, Shaoping Bai:
Mechanical Design and Kinematic Modeling of a Cable-Driven Arm Exoskeleton Incorporating Inaccurate Human Limb Anthropomorphic Parameters. Sensors 19(20): 4461 (2019) - [c29]Libo Zhou, Weihai Chen, Wenjie Chen, Shaoping Bai, Jianhua Wang, Jianbin Zhang:
Design of a Compact Rotary Series Elastic Actuator with Nonlinear Stiffness for Lower Limb Exoskeletons. AIM 2019: 68-73 - [c28]Zhongyi Li, Shaoping Bai:
Design and Modelling of a Compact Variable Stiffness Mechanism for Wearable Elbow Exoskeletons. ICCMA 2019: 342-346 - [c27]Zhongyi Li, Weihai Chen, Shaoping Bai:
A Novel Reconfigurable Revolute Joint with Adjustable Stiffness. ICRA 2019: 8388-8393 - [c26]Long Teng, Shaoping Bai:
Fuzzy Sliding Mode Control of An Upper-Limb Exoskeleton Robot. CIS/RAM 2019: 12-17 - 2018
- [j11]Xuerong Li, Jingmeng Liu, Weihai Chen, Shaoping Bai:
Integrated design, modeling and analysis of a novel spherical motion generator driven by electromagnetic principle. Robotics Auton. Syst. 106: 69-81 (2018) - [j10]Ruiqin Li, Hongwei Meng, Shaoping Bai, Yinyin Yao, Jianwei Zhang:
Stability and Gait Planning of 3-UPU Hexapod Walking Robot. Robotics 7(3): 48 (2018) - 2017
- [j9]Lelai Zhou, Yibin Li, Shaoping Bai:
A human-centered design optimization approach for robotic exoskeletons through biomechanical simulation. Robotics Auton. Syst. 91: 337-347 (2017) - [c25]Shaoping Bai, Simon Christensen, Muhammad Raza Ul Islam:
An upper-body exoskeleton with a novel shoulder mechanism for assistive applications. AIM 2017: 1041-1046 - [c24]Xuerong Li, Shaoping Bai, Weihai Chen, Jingmeng Liu:
Integrated design and modelling of an electro-magnets driven spherical parallel manipulator. AIM 2017: 1209-1214 - [c23]Muhammad Raza Ul Islam, Shaoping Bai:
Intention Detection for Dexterous Human Arm Motion with FSR Sensor Bands. HRI (Companion) 2017: 139-140 - [c22]Juan de Dios Flores Mendez, Henrik Schiøler, Ole Madsen, Shaoping Bai:
Impedance Control of a Redundant Parallel Manipulator. ICINCO (1) 2017: 104-111 - [c21]Juan de Dios Flores Mendez, Henrik Schiøler, Ole Madsen, Shaoping Bai:
Impedance Control and Force Estimation of a Redundant Parallel Kinematic Manipulator. ICINCO (Selected Papers) 2017: 174-191 - [c20]Zhongyi Li, Weihai Chen, Jianbin Zhang, Shaoping Bai:
Design and control of a 4-DOF cable-driven arm rehabilitation robot (CARR-4). CIS/RAM 2017: 581-586 - [c19]Xuerong Li, Shaoping Bai, Weihai Chen, Jingmeng Liu:
Torque modelling and current optimization of a spherical actuator built as an electro-magnets driven spherical parallel manipulator. CIS/RAM 2017: 626-631 - [c18]Libo Zhou, Weihai Chen, Jianhua Wang, Jingmeng Liu, Wenjie Chen, Shaoping Bai:
Optimization design of a bionic lower limb rehabilitation robot with dynamic analysis. ROBIO 2017: 718-723 - 2016
- [c17]Zhongyi Li, Weihai Chen, Jianbin Zhang, Shaoping Bai:
Stiffness analysis of a cable-driven wrist robotic rehabilitor. ICARCV 2016: 1-6 - [c16]Guanglei Wu, Shaoping Bai, Preben Hjornet:
On the stiffness of three/four degree-of-freedom parallel pick-and-place robots with four identical limbs. ICRA 2016: 861-866 - 2015
- [c15]Guanglei Wu, Shaoping Bai, Preben Hjornet:
Parametric optimal design of a parallel Schönflies-motion robot under pick-and-place trajectory constraints. IROS 2015: 3158-3163 - 2014
- [j8]Guanglei Wu, Stéphane Caro, Shaoping Bai, Jørgen Kepler:
Dynamic modeling and design optimization of a 3-DOF spherical parallel manipulator. Robotics Auton. Syst. 62(10): 1377-1386 (2014) - 2012
- [j7]Lelai Zhou, Shaoping Bai, Michael Rygaard Hansen:
Integrated dimensional and drive-train design optimization of a light-weight anthropomorphic arm. Robotics Auton. Syst. 60(1): 113-122 (2012) - [c14]Shaoping Bai, Chuhao Xing:
Shape modeling of a concentric-tube continuum robot. ROBIO 2012: 116-121 - 2011
- [c13]Guanglei Wu, Shaoping Bai, Jørgen Kepler:
Error modelling and experimental validation for a planar 3-PPR parallel manipulator. ICAR 2011: 259-264 - [c12]Lelai Zhou, Shaoping Bai, Michael Rygaard Hansen:
Integrated design optimization of a 5-DOF assistive light-weight anthropomorphic arm. ICAR 2011: 659-664 - 2010
- [c11]Nicolas Binaud, Stéphane Caro, Shaoping Bai, Philippe Wenger:
Comparison of 3-PP̲R parallel planar manipulators based on their sensitivity to joint clearances. IROS 2010: 2778-2783
2000 – 2009
- 2009
- [j6]Shaoping Bai, Michael Rygaard Hansen, Torben Ole Andersen:
Modellingof a special class of spherical parallel manipulators with Euler parameters. Robotica 27(2): 161-170 (2009) - [c10]Shaoping Bai, Stéphane Caro:
Design and analysis of a 3-PPR planar robot with U-shape base. ICAR 2009: 1-6 - 2006
- [c9]Shaoping Bai, Jorge Angeles:
Kinematics of Spherical Multi-Lobe-Cams for The Design of a Pitch-Roll Wrist. ICARCV 2006: 1-6 - 2005
- [c8]Shaoping Bai, Jorge Angeles:
The Design of A Gearless Pitch-Roll Wrist. ICRA 2005: 3213-3218 - 2003
- [j5]Huat Kin Low, Shaoping Bai:
Terrain-evaluation-based motion planning for legged locomotion on irregular terrain. Adv. Robotics 17(8): 761-778 (2003) - [j4]Shaoping Bai, Ming Yeong Teo:
Kinematic Calibration and Pose Measurement of a Medical Parallel Manipulator by Optical Position Sensors. J. Field Robotics 20(4): 201-209 (2003) - 2002
- [c7]Shaoping Bai, Ming Yeong Teo:
Kinematic calibration and pose measurement of a medical parallel manipulator by optical position sensors. ICARCV 2002: 419-424 - [c6]Shaoping Bai, Huat Kin Low, Ming Yeong Teo:
Path Generation of Walking Machines in 3D Terrain. ICRA 2002: 2216-2221 - 2001
- [j3]Shaoping Bai, Huat Kin Low:
Terrain evaluation and its application to path planning for walking machines. Adv. Robotics 15(7): 729-748 (2001) - [c5]Shaoping Bai, Huat Kin Low:
Body Trajectory Generation for Legged Locomotion Systems Using A Terrain Evaluation Approach. ICRA 2001: 2279-2284 - [c4]Shaoping Bai, Ming Yeong Teo, Wan Sing Ng, Charlie Sim:
Workspace analysis of a parallel manipulator with one redundant DOF for skull-base surgery. IROS 2001: 1694-1699 - [c3]Charlie Sim, Ming Yeong Teo, Wan Sing Ng, Carl Yap, Yong-Chong Loh, Tseng-Tsai Yeo, Shaoping Bai, Charles Lo:
Hexapod Intervention Planning for a Robotic Skull-Base Surgery System. MICCAI 2001: 1314-1315 - 2000
- [c2]Shaoping Bai, Huat Kin Low, Weimiao Guo:
Kinematographic Experiments on Leg Movements and Body Trajectories of Cockroach Walking on Different Terrain. ICRA 2000: 2605-2610
1990 – 1999
- 1999
- [j2]Shaoping Bai, Huat Kin Low, Teresa Zielinska:
Quadruped Free Gait Generation Based on the Primary/Secondary Gait. Robotica 17(4): 405-412 (1999) - [c1]Shaoping Bai, Huat Kin Low, Gerald Seet, Teresa Zielinska:
A New Free Gait Generation for Quadrupeds Based on Primary/Secondary Gait. ICRA 1999: 1371-1376 - 1998
- [j1]Shaoping Bai, Huat Kin Low, Teresa Zielinska:
Quadruped free gait generation for straight-line and circular trajectories. Adv. Robotics 13(5): 513-538 (1998)
Coauthor Index
manage site settings
To protect your privacy, all features that rely on external API calls from your browser are turned off by default. You need to opt-in for them to become active. All settings here will be stored as cookies with your web browser. For more information see our F.A.Q.
Unpaywalled article links
Add open access links from to the list of external document links (if available).
Privacy notice: By enabling the option above, your browser will contact the API of unpaywall.org to load hyperlinks to open access articles. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Unpaywall privacy policy.
Archived links via Wayback Machine
For web page which are no longer available, try to retrieve content from the of the Internet Archive (if available).
Privacy notice: By enabling the option above, your browser will contact the API of archive.org to check for archived content of web pages that are no longer available. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Internet Archive privacy policy.
Reference lists
Add a list of references from , , and to record detail pages.
load references from crossref.org and opencitations.net
Privacy notice: By enabling the option above, your browser will contact the APIs of crossref.org, opencitations.net, and semanticscholar.org to load article reference information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the Crossref privacy policy and the OpenCitations privacy policy, as well as the AI2 Privacy Policy covering Semantic Scholar.
Citation data
Add a list of citing articles from and to record detail pages.
load citations from opencitations.net
Privacy notice: By enabling the option above, your browser will contact the API of opencitations.net and semanticscholar.org to load citation information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the OpenCitations privacy policy as well as the AI2 Privacy Policy covering Semantic Scholar.
OpenAlex data
Load additional information about publications from .
Privacy notice: By enabling the option above, your browser will contact the API of openalex.org to load additional information. Although we do not have any reason to believe that your call will be tracked, we do not have any control over how the remote server uses your data. So please proceed with care and consider checking the information given by OpenAlex.
last updated on 2024-12-12 21:02 CET by the dblp team
all metadata released as open data under CC0 1.0 license
see also: Terms of Use | Privacy Policy | Imprint