A Study on the Control of a Sensorless Pneumatic Joint Using Predictive Control Method

Zhang, Yanheng; Chen, Xie; Wang, Huizhi; Zhang, Lufeng

doi:10.1109/access.2019.2913950

Cited by 2 publications

(2 citation statements)

References 19 publications

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“…26 Zhang et al applied model predictive control method to control a sensorless vane-type joint for robots working under high voltage environment. 27 But the control accuracy is not satisfactory, especially for surgical applications. Although slightly similar, a turbine-based air motor is structurally different from a vane-type air motor, which consists of a cylindrical stator and an eccentric rotor with grooves for multiple vanes to slide in and out.…”

Section: Introductionmentioning

confidence: 99%

Design and stability analysis of a nonlinear controller for MRI-compatible pneumatic motors

2023

Proceedings of the Institution of Mechanical Engineers, Part C:

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Among permissible magnetic resonance imaging (MRI) compatible actuators for surgical robots, turbine-based pneumatic motors are noticeably favorited due to its compact size, simpler structure, fast additively manufacturability, and continuous bidirectional motion ability. Yet, the system dynamics of pneumatic motors, especially pneumatic nonlinearity, is often neglected and simple PID control is used, resulting in low system bandwidth (~0.5 Hz). To tackle this obstacle, this paper proposes a model-based nonlinear control method for MRI-compatible pneumatic motors. Dynamic models for a pneumatic motor previously designed by the author are developed first, followed by establishment of the nonlinear feedback controller. An error based Lyapunov candidate function is designed and mathematically proved to be globally uniformly asymptotically stable, guaranteeing desired accuracy. Experiment control tests demonstrate that the proposed control method can achieve satisfactorily better tracking accuracy than a conventional model-independent PID controller with respect to amplitude attenuation and phase delay.

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Section: Introductionmentioning

confidence: 99%

Design and stability analysis of a nonlinear controller for MRI-compatible pneumatic motors

2023

Proceedings of the Institution of Mechanical Engineers, Part C:

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“…Controlling the system's position also becomes more complicated with the need to simultaneously consider the accuracy of system and response time. Various controllers were reportedly proposed to control the position of pneumatic system; such as proportionalintegral-derivative (PID) [3], pole-placement [4], H∞ loop shaping controller [5], adaptive controller [6], fuzzy logic [7], and predictive control [8], [9]. However, most of these reported controllers were incapable to simultaneously deliver high-speed response with accuracy.…”

Section: Introductionmentioning

confidence: 99%

Enhancement in pneumatic positioning system using nonlinear gain constrained model predictive controller: experimental validation

Sulaiman

Rahmat

Faudzi

et al. 2021

IJEECS

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The issues of inaccurate positioning control have made an industrial use of pneumatic actuator remains restricted to certain applications only. Non-compliance with system limits and properly control the operating system may also degrade the performance of pneumatic positioning systems. This study proposed a new approach to enhance pneumatic positioning system while considering the constraints of system. Firstly, a mathematical model that represented the pneumatic system was determined by system identification approach. Secondly, model predictive controller (MPC) was developed as a primary controller to control the pneumatic positioning system, which took into account the constraints of the system. Next, to enhance the performance of the overall system, nonlinear gain function was incorporated within the MPC algorithm. Finally, the performances were compared with other control methods such as constrained MPC (CMPC), proportional-integral (PI), and predictive functional control with observer (PFC-O). The validation based on real-time experimental results for 100 mm positioning control revealed that the incorporation of nonlinear gain within the MPC algorithm improved 21.03% and 2.69% of the speed response given by CMPC and PFC-O, and reduced 100% of the overshoot given by CMPC and PI controller; thus, providing fast and accurate pneumatic positioning control system.

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A Study on the Control of a Sensorless Pneumatic Joint Using Predictive Control Method

Cited by 2 publications

References 19 publications

Design and stability analysis of a nonlinear controller for MRI-compatible pneumatic motors

Design and stability analysis of a nonlinear controller for MRI-compatible pneumatic motors

Enhancement in pneumatic positioning system using nonlinear gain constrained model predictive controller: experimental validation

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