Chen-Yu Chan scite author profile

The main goal of this study was to study the performance of fuzzy logic controllers combined with simplified hybrid amplitude/pulse-width (AM/PW) modulation to regulate muscle force via nerve electrical stimulation. The recruitment curves with AM/PW and AM modulations were constructed for the calf muscles of rabbits. Integrated with the modulation methods, a proportional-integral-derivative (PID) and three fuzzy logic controllers were designed and applied for the electrical stimulation of tibial nerves to control the ankle torque under isometric conditions. The performance of the two modulation methods combined with the four controllers was compared when the ankle was fixed at three positions for both in vivo experiments and model simulations using a nonlinear muscle model. For the animal experiments, AM/PW modulation performed better than AM modulation alone. The fuzzy PI controller performed marginally better and was resistant to external noises, though it tended to have a larger overshoot. The performance of the controllers had a similar trend in the three different joint positions, and the simulation results with the nonlinear model matched the experimental results well. In conclusion, AM/PW modulation improved controller performance, while the contribution of fuzzy logic was only marginal.

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Spacecraft 6-DoF Localization in a GPS denied Environment

Peng

Chan

Lin

et al. 2021

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Event-triggered control for bilateral teleoperation with time delays

Chan

Liu

2016

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PA-FlowNet: Pose-Auxiliary Optical Flow Network for Spacecraft Relative Pose Estimation

Chen

et al. 2021

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Chen-Yu Chan

Towards a walking, turning, and jumping quadruped robot with compliant mechanisms

Fuzzy control with amplitude/pulse-width modulation of nerve electrical stimulation for muscle force control

Spacecraft 6-DoF Localization in a GPS denied Environment

Event-triggered control for bilateral teleoperation with time delays

PA-FlowNet: Pose-Auxiliary Optical Flow Network for Spacecraft Relative Pose Estimation

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