Spatial Iterative Learning Torque Control of Robotic Exoskeletons for High Accuracy and Rapid Convergence Assistance

Xing, Xueyan; Zhang, Sainan; Huang, Tzuhao; Huang, Jin Sen; Su, Hao; Li, Yanan

doi:10.1109/tmech.2024.3365045

IEEE/ASME Trans. Mechatron.

2024

DOI: 10.1109/tmech.2024.3365045

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Spatial Iterative Learning Torque Control of Robotic Exoskeletons for High Accuracy and Rapid Convergence Assistance

Xueyan Xing,

Sainan Zhang,

Tzuhao Huang

et al.

Abstract: High-performance torque tracking is crucial for accurate control of the magnitude and timing of exoskeleton assistive torque profiles. However, state-of-the-art torque control methods, e.g., iterative learning control (ILC), applied to exoskeletons cannot achieve satisfying accuracy and convergence speed. This paper aims to design a spatial iterative learning (sIL)-based torque control strategy for exoskeletons to achieve accurate and fast torque assistance, which includes a high-level controller for torque pl… Show more

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Cited by 1 publication

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Study and Experimental Verification on Anti-Disturbance Control Strategy for Electro-Mechanical Servo Systems

Zheng,

Wang,

Wei

et al. 2024

Actuators

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With technological advances and industrial upgrading, electro-mechanical actuators (EMAs) have gradually replaced traditional hydraulic actuation systems. During operation, force servo systems inevitably suffer from external force or position disturbances, thus affecting the output performance of the system. Therefore, it is of significant engineering application value to develop EMA anti-disturbance control strategies that exhibit strong robustness and are more easily applicable to engineering practice. In this study, an open-loop transfer function of the system with command signals and disturbance signals as inputs was established based on the nonlinear mathematical models built for the core components of EMAs. To overcome the impact of external position disturbances on the motion performance of the force servo system, a proportional integral derivative (PID) controller was introduced and a high-order transfer function associated with various parameters such as speed and acceleration was derived and obtained as feedforward compensation based on the mathematical model. By incorporating a three-loop PID controller, the impact of external disturbance forces on the motion performance of the position servo system was overcome and the tracking accuracy of the system was also improved. Finally, simulation models were built using AMESim software (AMESim 2020, LMS Imagine.Lab, Roanne, France) and a dual-channel EMA performance testing system was developed. Simulation and test results indicated that both anti-disturbance control methods exhibited strong robustness and excellent anti-disturbance performance, with the control accuracy and dynamic performance almost unaffected by disturbances. This verified the correctness of the single-channel EMA anti-disturbance control strategy and the usability of the simulation model.

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Study and Experimental Verification on Anti-Disturbance Control Strategy for Electro-Mechanical Servo Systems

Zheng,

Wang,

Wei

et al. 2024

Actuators

View full text Add to dashboard Cite

show abstract

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Spatial Iterative Learning Torque Control of Robotic Exoskeletons for High Accuracy and Rapid Convergence Assistance

Cited by 1 publication

References 28 publications

Study and Experimental Verification on Anti-Disturbance Control Strategy for Electro-Mechanical Servo Systems

Study and Experimental Verification on Anti-Disturbance Control Strategy for Electro-Mechanical Servo Systems

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