TY - GEN
T1 - 6-DOF Parallel Robot under Partial Observation
T2 - 20th IEEE Conference on Industrial Electronics and Applications, ICIEA 2025
AU - Xiao, Junlin
AU - Tian, Xinyu
AU - Jia, Fuhua
AU - Yang, Mengshen
AU - Rushworth, Adam
AU - Kwong, Chiew Foong
AU - Ijaz, Salman
AU - Chen, Silu
AU - Chen, Chin Yin
AU - Yang, Guilin
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025/9
Y1 - 2025/9
N2 - Due to the coupling characteristics of kinematics and dynamics, six-degree-of-freedom parallel robots face challenges in achieving real-time and high-precision velocity and acceleration control. The existing methods limit their applications in scenarios such as admittance control, dynamic operational environments, and multi-robot collaboration due to the excessive computational burden brought by complex models. In this paper, a novel state estimation and control method based on partial observational data is proposed. Firstly, the on-platform state estimation is accomplished precisely in real time by employing the extended Kalman Filter to integrate data from both the inertial measurement unit and the camera. Then, a direct method maps the state of the upper platform to the actuator using estimated data, eliminating the need for traditional leg length data, reducing the system cost, and shortening the response time. The feed-forward velocity control strategy is proposed to enhance the dynamic performance and robustness of the system, enabling it to quickly adapt to external changes and maintain six degrees-of-freedom of compensation for base disturbance. Finally, quintic spline trajectory planning is adopted to plan the robot motion trajectory, which significantly improves motion efficiency and reduces energy consumption. Experiments on the Stewart platform have proved the feasibility and effectiveness of the proposed method. The source code is available as open source at https://github.com/ControlSystemLab/Stewart-Control.
AB - Due to the coupling characteristics of kinematics and dynamics, six-degree-of-freedom parallel robots face challenges in achieving real-time and high-precision velocity and acceleration control. The existing methods limit their applications in scenarios such as admittance control, dynamic operational environments, and multi-robot collaboration due to the excessive computational burden brought by complex models. In this paper, a novel state estimation and control method based on partial observational data is proposed. Firstly, the on-platform state estimation is accomplished precisely in real time by employing the extended Kalman Filter to integrate data from both the inertial measurement unit and the camera. Then, a direct method maps the state of the upper platform to the actuator using estimated data, eliminating the need for traditional leg length data, reducing the system cost, and shortening the response time. The feed-forward velocity control strategy is proposed to enhance the dynamic performance and robustness of the system, enabling it to quickly adapt to external changes and maintain six degrees-of-freedom of compensation for base disturbance. Finally, quintic spline trajectory planning is adopted to plan the robot motion trajectory, which significantly improves motion efficiency and reduces energy consumption. Experiments on the Stewart platform have proved the feasibility and effectiveness of the proposed method. The source code is available as open source at https://github.com/ControlSystemLab/Stewart-Control.
KW - 6-DOF Parallel Manipulator
KW - Sensor Fusion
KW - State Estimation
KW - Trajectory Planning
UR - https://www.scopus.com/pages/publications/105018080933
U2 - 10.1109/ICIEA65512.2025.11149155
DO - 10.1109/ICIEA65512.2025.11149155
M3 - Conference contribution
AN - SCOPUS:105018080933
T3 - 2025 IEEE 20th Conference on Industrial Electronics and Applications, ICIEA 2025
BT - 2025 IEEE 20th Conference on Industrial Electronics and Applications, ICIEA 2025
PB - Institute of Electrical and Electronics Engineers Inc.
Y2 - 3 August 2025 through 6 August 2025
ER -
