GPC Controller Design for an Intelligent Pneumatic Actuator

The aim of this paper is to propose a bipedal structure able to follow high acceleration movements. The vertical jump of a human has been chosen as input (coming from experiments) to validate the controller design as it is one of the most complex motion. The study concerns the low level of the biped control that is to say the control design of one leg made of three rigid bodies, each of them moved by a pneumatic actuator. An analogy between a pneumatic actuator and a physiological muscle is first proposed. A dynamic model of the leg is then presented decoupling the dynamic effects of the skeletal (as interactions between segments) from the dynamic effects of the muscles involved. The controller is based on the nonlinear theory (taking into account the actuator and the mechanical models), it ensures a dynamic tracking of position and force. Its originality lays in the consideration of impedance behaviour at each joint during free and constrained tasks. It leads to asymptotically stable (Popov criteria) control laws which are continuous between contact and non-contact phases enabling real-time computations. The simulation results clearly show the tracking of position and forces during the whole jump cycle.

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LPV-Based Controller Design of a Floating Piston Pneumatic Actuator

Actuators ◽

10.3390/act9040098 ◽

2020 ◽

Vol 9 (4) ◽

pp. 98

Author(s):

Ádám Szabó ◽

Tamás Bécsi ◽

Szilárd Aradi ◽

Péter Gáspár

Keyword(s):

High Speed ◽

Controller Design ◽

Linear Quadratic Regulator ◽

Pneumatic Actuator ◽

Pd Controller ◽

Linear Parameter ◽

Linear Quadratic ◽

Minimum Order ◽

Linear Parameter Varying ◽

Parameter Varying

The paper presents the modeling and control design of a floating piston pneumatic gearbox actuator using a grid-based Linear Parameter Varying approach. First, the nonlinear model of the pneumatic actuator is presented, then it is transformed into a 6th order Linear Parameter Varying representation with endogenous scheduling parameters. The model is simplified based on empirical considerations to solve the controller synthesis and allow fast controller tuning. The developed Linear Parameter Varying controller is tested in simulations. Moreover, using a balanced truncation-model order reduction method, the minimum order of the controller is determined, which can provide acceptable performance. The simplified controller is implemented in an embedded environment and validated against the real target. Then, the validation results are compared with a gain-scheduled PD controller and a Linear Quadratic Regulator. The results show that by taking the time-varying nature of the scheduling parameters into account, the Linear Parameter Varying controller surpasses the Linear Quadratic Regulator, which cannot handle the high-speed transients around Neutral. Furthermore, the PD controller performs slightly better in two of the four test cases, although the Linear Parameter Varying controller has a higher level of fault tolerance.

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G1010305 A Controller Design for a Joint Motion Assist System using McKibben Pneumatic Actuator

The Proceedings of Mechanical Engineering Congress Japan ◽

10.1299/jsmemecj.2014._g1010305- ◽

2014 ◽

Vol 2014 (0) ◽

pp. _G1010305--_G1010305-

Author(s):

Hiroyoshi MURATA ◽

Takuya OKADA ◽

Fumitake FUJII

Keyword(s):

Controller Design ◽

Pneumatic Actuator ◽

Joint Motion

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Controller Design for a Pneumatic Actuator System with Proportional Valve

International Journal of Simulation Systems Science & Technology ◽

10.5013/ijssst.a.17.02.10 ◽

2016 ◽

Author(s):

Guest Editor Chengyu Zhang

Keyword(s):

Controller Design ◽

Pneumatic Actuator ◽

Proportional Valve ◽

Actuator System

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Modified nonlinear pressure estimator of pneumatic actuator for force controller design

2017 IEEE International Conference on Robotics and Automation (ICRA) ◽

10.1109/icra.2017.7989075 ◽

2017 ◽

Author(s):

Yun-Pyo Hong ◽

Soohyun Kim ◽

Kyung-Soo Kim

Keyword(s):

Controller Design ◽

Pneumatic Actuator

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Integrating Servo-Pneumatic Actuator with Ball Beam System based on Intelligent Position Control

Jurnal Teknologi ◽

10.11113/jt.v69.3146 ◽

2014 ◽

Vol 69 (3) ◽

Cited By ~ 1

Author(s):

Muhammad Asyraf Azman ◽

Ahmad ‘Athif Mohd Faudzi ◽

Nu’man Din Mustafa ◽

Khairuddin Osman ◽

Elango Natarajan

Keyword(s):

Fuzzy Logic ◽

Position Control ◽

Fuzzy Controller ◽

Controller Design ◽

Pneumatic Actuator ◽

Fuzzy Pid ◽

Fuzzy Pid Controller ◽

Beam System ◽

Position Controller ◽

Simulation Results

The purpose of this paper is to design a controller that can control the position of the cylinder pneumatic stroke. This work proposes two control approaches, Proportional-Integral-Derivative Fuzzy Logic (Fuzzy-PID) controller and Proportional-Derivative Fuzzy Logic (PD-Fuzzy) controller for a Servo-Pneumatic Actuator. The design steps of each controller implemented on MATLAB/Simulink are presented. A model based on position system identification is used for the controller design. Then, the simulation results are analyzed and compared to illustrate the performance of the proposed controllers. Finally, the controllers are tested with the real plant in real-time experiment to validate the results obtained by simulation. Results show that PD-Fuzzy controller offer better control compared to Fuzzy-PID. A Pneumatic Actuated Ball & Beam System (PABBS) is proposed as the application of the position controller. The mathematical model of the system is developed and tested simulation using Feedback controller (outer loop)-PD-Fuzzy controller (inner loop). Simulation result is presented to see the effectiveness of the obtained model and controller. Results show that the servo-pneumatic actuator can control the position of the Ball & Beam system using PD-Fuzzy controller.

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