Your search keyword '"Pneumatic muscle actuator"' showing total 165 results

1. Modeling and dynamic analysis of a robotic arm with pneumatic artificial muscle by transfer matrix method.

Author

Bamdad, Mahdi, Feyzollahzadeh, Mahdi, and Rahi Safavi, S.

Subjects

*TRANSFER matrix, *ARTIFICIAL muscles, *ARTIFICIAL arms, *DYNAMIC models, *ROBOTICS, *PNEUMATIC actuators, *ARM

Abstract

Pneumatic artificial muscle (PAM) has attracted significant attention owing to its safe and compliant physical properties in industrial manipulators, along with advanced service technologies. Since PAM is prone to large deformation problems, actuation control, and dynamic identification is required to perceive considering precise and fast computation. This article presents a methodology for accurate dynamic modeling and analysis of a planar robotic arm in the presence of large deformations caused by the artificial muscle. This novel planar robotic arm with pneumatic actuation and spring loaded in an antagonistic form is designed and fabricated. This article deals with the displacement analysis of a new type of PAM-actuated mechanism for large deformation. The aim is to find an accurate mathematical model of this robotic arm with motion nonlinearity. Since vibration can be generated in the articulating operations according to the dynamic behavior of PAM, a transfer-matrix method is proposed to explore the effect of flexibility undergoing planar flexural deformation. An explanation of the procedure through presenting its general formulation is employed to experiment. The discrete method is analyzed beside the rich datasets generated for actuator identification in the preliminary experimental study. The transfer matrices are determined considering the flexibilities whereas results are verified using MSC.ADAMS©. Experimental validation and numerical modeling confirm that the presented modeling methods help to improve the performance of the pneumatic muscle drives in high-precision manipulators. This study leaves room for further development of this algorithmic framework with a more complicated mechanism with soft pneumatic network actuators for various designs. [ABSTRACT FROM AUTHOR]

Published

2024

2. Design and Characterization of a Mckibben Pneumatic Muscle Prototype with an Embedded Capacitive Length Transducer.

Author

Antonelli, Michele Gabrio, Beomonte Zobel, Pierluigi, De Marcellis, Andrea, and Palange, Elia

Subjects

TRANSDUCERS, PRESSURE transducers, PNEUMATIC actuators, ARTIFICIAL muscles, HUMAN-robot interaction, PROTOTYPES

Abstract

The McKibben muscle types are pneumatic actuators known to be intrinsically safe for their high power-to-weight ratio. For these reasons, they are suitable for robotic, biomechanical, and medical applications. In these application fields and, above all, in collaborative robotics, where safety must be ensured for human–robot interactions, the values of pressure, force, and length are necessary and must be continuously monitored and controlled. Force and pressure transducers are commercially available to be integrated into a McKibben muscle type. On the contrary, no commercial-length transducers can be adopted. This work presents a novel McKibben muscle prototype with an embedded capacitive-length transducer. The latter is a cylindrical capacitor made of a telescopic system composed of two tubes: one of its ends is connected to the muscle. A change in the length of the muscle causes a proportional change in the transducer capacitance. The paper reports in detail on the working principle of McKibben's muscle, its fabrication, characterization, and validation of four prototype capacitive transducers. The results achieved from the experimental activities demonstrate that it is possible to control the variations of the muscle length relative to its elongation and compression for values less than 1 mm. This is the consequence of the ability to measure the transducer capacitance with a typical statistical relative indetermination better than 0.25%, which is a figure of merit for the reliability and mechanical and electrical stability of the proposed McKibben muscle prototype. Moreover, it has been demonstrated that the transducer capacitance as a function of the muscle length is linear, with maximum deviations from linearity equal to 2.44% and 5.22% during the muscle elongation and compression, respectively. [ABSTRACT FROM AUTHOR]

Published

2022

3. Feasibility of Pi Control for a Double-Acting Cylinder Actuated by Mckibben Muscles

Author

Mhd Yusoff, Mohd Akmal, Mohd Faudzi, Ahmad Athif, Hassan Basri, Mohd Shukry, Cavas-Martínez, Francisco, Series Editor, Chaari, Fakher, Series Editor, di Mare, Francesca, Series Editor, Gherardini, Francesco, Series Editor, Haddar, Mohamed, Series Editor, Ivanov, Vitalii, Series Editor, Kwon, Young W., Series Editor, Trojanowska, Justyna, Series Editor, Chew, Esyin, editor, P. P. Abdul Majeed, Anwar, editor, Liu, Pengcheng, editor, Platts, Jon, editor, Myung, Hyun, editor, Kim, Junmo, editor, and Kim, Jong-Hwan, editor

Published

2021

4. High Gain Finite-Time Trajectory Tracking Control of Pneumatic Muscle Actuator

Author

Shen, Tong, Huang, Jian, Angrisani, Leopoldo, Series Editor, Arteaga, Marco, Series Editor, Panigrahi, Bijaya Ketan, Series Editor, Chakraborty, Samarjit, Series Editor, Chen, Jiming, Series Editor, Chen, Shanben, Series Editor, Chen, Tan Kay, Series Editor, Dillmann, Rüdiger, Series Editor, Duan, Haibin, Series Editor, Ferrari, Gianluigi, Series Editor, Ferre, Manuel, Series Editor, Hirche, Sandra, Series Editor, Jabbari, Faryar, Series Editor, Jia, Limin, Series Editor, Kacprzyk, Janusz, Series Editor, Khamis, Alaa, Series Editor, Kroeger, Torsten, Series Editor, Liang, Qilian, Series Editor, Martin, Ferran, Series Editor, Ming, Tan Cher, Series Editor, Minker, Wolfgang, Series Editor, Misra, Pradeep, Series Editor, Möller, Sebastian, Series Editor, Mukhopadhyay, Subhas, Series Editor, Ning, Cun-Zheng, Series Editor, Nishida, Toyoaki, Series Editor, Pascucci, Federica, Series Editor, Qin, Yong, Series Editor, Seng, Gan Woon, Series Editor, Speidel, Joachim, Series Editor, Veiga, Germano, Series Editor, Wu, Haitao, Series Editor, Zhang, Junjie James, Series Editor, Wang, Rui, editor, Chen, Zengqiang, editor, Zhang, Weicun, editor, and Zhu, Quanmin, editor

Published

2020

5. Characterization of pneumatic muscle actuators and their implementation on an elbow exoskeleton with a novel hinge design

Author

Antonio Dylan Do Rosario Carvalho, Navin Karanth P, and Vijay Desai

Subjects

Pneumatic muscle actuator, McKibben artificial muscle, Soft actuator, Soft robotics, Exoskeleton, Instruments and machines, QA71-90

Abstract

The exoskeleton plays an essential role in the field of physical rehabilitation. Several actuators are used for the exoskeleton application, but the pneumatic muscle actuator has proved to be the best due to its high power to weight ratio, compliance, and safe operation. The objective of this paper involves the fabrication and experimental characterization of a pneumatic muscle actuator to actuate an exoskeleton for the elbow joint. This paper presents the development and testing of twelve pneumatic muscles of varying materials and sizes, to find the best combination to suit the intended application. The characterization process involved several tests, which related force, deflection, and pressure at various loading conditions. A modular test rig was developed to conduct all the tests with minor adjustments to the test setup. The study also involved designing and developing an elbow exoskeleton to test the pneumatic muscle in the real-world scenario. The exoskeleton is designed with a novel hinge to compensate for the antagonistic nature of the pneumatic muscle actuator. The tests showed the muscles with higher tensile modules bladders having a lower hysteresis and better load handling capability, but these suffered from lower contraction and force characteristics. The styrene-based muscle with a 12mm bladder (S12LB) showed the best force and deflection characteristics at various pressures and loading conditions. The styrene bladder has a modulus closer to the skeletal muscle, therefore demonstrating higher compliance and making it a preferred choice for the exoskeleton application

Published

2022

6. Improved fuzzy sliding mode control in flexible manipulator actuated by PMAs.

Author

Li, Fang, Zhang, Zheng, Wu, Yang, Chen, Yining, Liu, Kai, and Yao, Jiafeng

Subjects

*SLIDING mode control, *PNEUMATIC actuators, *MANIPULATORS (Machinery), *HUMAN mechanics

Abstract

Pneumatic muscle actuator (PMA) similar to biological muscle is a new type of pneumatic actuator. The flexible manipulator based on PMAs was constructed to simulate the actual movement of the human upper arm. Considering the model errors and external disturbances, the fuzzing sliding mode control based on the saturation function was proposed. Compared with other fuzzy control methods, fuzzy control and saturation function are used to adjust the robust terms to improve the tracking accuracy and reduce the high-frequency chattering. [ABSTRACT FROM AUTHOR]

Published

2022

7. Switching Model Predictive Control for Thin McKibben Muscle Servo Actuator.

Author

Mhd Yusoff, Mohd Akmal, Mohd Faudzi, Ahmad Athif, Hassan Basri, Mohd Shukry, Rahmat, Mohd Fuaad, Shapiai, Mohd Ibrahim, and Mohamaddan, Shahrol

Subjects

ACTUATORS, PREDICTION models, ARTIFICIAL muscles, STEADY-state responses, FOOTPRINTS

Abstract

Dynamic characteristics and control of thin McKibben muscle (TMM) have not yet been fully investigated, especially on the translational antagonistic pair system. Therefore, the objective of this study is to propose a Switching Model Predictive Control (SMPC) based on a Piecewise Affine (PWA) system model to control a translational antagonistic-pair TMM servo actuator. A novel configuration enables the servo actuator to achieve a position control of 40 mm within a small footprint. The result shows that the feedback system gives minimal steady-state errors when tracking staircase and setpoint references ranging from 0 to 3.5 cm. The controller also produces better transient and steady-state responses than our previously developed Gain-scheduled Proportional–Integral–Derivative (GSPID) controller. The evidence from this study suggests that a predictive control for a TMM servo actuator is feasible. [ABSTRACT FROM AUTHOR]

Published

2022

8. Design, Development, and Control of a Novel Upper-Limb Power-Assist Exoskeleton System Driven by Pneumatic Muscle Actuators.

Author

Chu, Hsien-Ru, Chiou, Shean-Juinn, Li, I-Hsum, and Lee, Lian-Wang

Subjects

ROBOTIC exoskeletons, PNEUMATIC actuators, PNEUMATICS, MULTI-degree of freedom, TORSION

Abstract

An innovative wearable upper-limb power-assist exoskeleton system (UPES) was designed for laborers to improve work efficiency and reduce the risk of musculoskeletal disorders. This novel wearable UPES consists of four joints, each comprising a single actuated pneumatic muscle actuator (PMA) and a torsion spring module driven via a steel cable. Unlike most single-joint applications, where dual-PMAs are driven by antagonism, this design aims to combine a torsion spring module with a single-PMA via a steel cable for a 1-degree of freedom (1-DOF) joint controlled by a proportional-pressure regulator. The proposed four driving degrees of freedom wearable UPES is suitable for power assistance in work and characterizes a simple structure, safety, and compliance with the motion of an upper limb. However, due to the hysteresis, time-varying characteristics of the PMA, and non-linear movement between joint flexion and extension, the model parameters are difficult to identify accurately, resulting in unmeasurable uncertainties and disturbances of the wearable UPES. To address this issue, we propose an improved proxy-based sliding mode controller integrated with a linear extended state observer (IPSMC-LESO) to achieve accurate power-assisted control for the upper limb and ensure safe interaction between the UPES and the wearer. This control method can slow the underdamped dynamic recovery motion to tend the target trajectory without overshoots from large tracking errors that result in actuator saturation, and without deteriorating the power assist effect during regular operation. The experimental results show that IPSMC-LESO can effectively control a 4-DOF wearable UPES, observe the unknown states and total disturbance online of the system, and adapt to the external environment and load changes to improve system control performance. The results prove that the joint torsion spring module combining the single-PMA can reduce the number of PMAs and proportional-pressure regulators by half and obtain a control response similar to that of the dual-PMA structure. [ABSTRACT FROM AUTHOR]

Published

2022

9. Adaptive proxy-based sliding mode control for a class of second-order nonlinear systems and its application to pneumatic muscle actuators.

Author

Huang, Jian, Cao, Yu, and Wang, Yan-Wu

Subjects

SLIDING mode control, PNEUMATIC actuators, PNEUMATICS, NONLINEAR systems, CLOSED loop systems

Abstract

The human-centered robotic systems demand safe and robust controllers in many applications. This paper proposes an adaptive proxy-based sliding mode control approach for a class of typical second-order nonlinear systems. A new PID-type virtual coupling is designed between a virtual proxy and the physical object. Considering the unknown bound of lumped disturbances, an adaptation law is applied to online adjust the gain of a sign function which ensures the proxy to track the reference accurately. By using the Lyapunov theorem, the closed-loop system stability is proved. Both simulations and experiments are conducted to verify the proposed method based on a real-world pneumatic muscle actuator control platform. The results show that the proposed adaptive proxy-based sliding mode control approach presents better tracking accuracy, safety, and robustness than the conventional PID control and sliding mode control. [ABSTRACT FROM AUTHOR]

Published

2022

10. A Novel Force Sensorless Reflecting Control for Bilateral Haptic Teleoperation System

Author

Cong Phat Vo, Xuan Dinh To, and Kyoung Kwan Ahn

Subjects

Bilateral teleoperation system, pneumatic muscle actuator, force observer, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This paper presents a novel force sensorless reflecting controller for a haptic-enabled device driven by a bilateral pneumatic artificial muscle system, which proposed configuration for the first time the bilateral haptic teleoperation. For details, an adaptive force observer scheme considered to be an alternative to direct force measurement is proposed to estimate the interaction force with an unknown environment for the force reflecting control design. Meanwhile, the separately fast finite time nonsingular terminal sliding mode control schemes are developed based on the force estimation in both subsystems to achieve good tracking performance and fast response. Thus, the great transparency performance with both force feedback and position tracking can be achieved simultaneously by using our proposed method. The finite-time stability of the total controlled system is demonstrated by the Lyapunov approach. Moreover, the comparative experiments are carried out on the developed testbench to validate the effectiveness and advantages of our proposed control design in the different working conditions.

Published

2020

11. Design and Characterization of a Mckibben Pneumatic Muscle Prototype with an Embedded Capacitive Length Transducer

Author

Michele Gabrio Antonelli, Pierluigi Beomonte Zobel, Andrea De Marcellis, and Elia Palange

Subjects

pneumatic muscle actuator, capacitive length transducer, collaborative and soft robotics, Mechanical engineering and machinery, TJ1-1570

Abstract

The McKibben muscle types are pneumatic actuators known to be intrinsically safe for their high power-to-weight ratio. For these reasons, they are suitable for robotic, biomechanical, and medical applications. In these application fields and, above all, in collaborative robotics, where safety must be ensured for human–robot interactions, the values of pressure, force, and length are necessary and must be continuously monitored and controlled. Force and pressure transducers are commercially available to be integrated into a McKibben muscle type. On the contrary, no commercial-length transducers can be adopted. This work presents a novel McKibben muscle prototype with an embedded capacitive-length transducer. The latter is a cylindrical capacitor made of a telescopic system composed of two tubes: one of its ends is connected to the muscle. A change in the length of the muscle causes a proportional change in the transducer capacitance. The paper reports in detail on the working principle of McKibben’s muscle, its fabrication, characterization, and validation of four prototype capacitive transducers. The results achieved from the experimental activities demonstrate that it is possible to control the variations of the muscle length relative to its elongation and compression for values less than 1 mm. This is the consequence of the ability to measure the transducer capacitance with a typical statistical relative indetermination better than 0.25%, which is a figure of merit for the reliability and mechanical and electrical stability of the proposed McKibben muscle prototype. Moreover, it has been demonstrated that the transducer capacitance as a function of the muscle length is linear, with maximum deviations from linearity equal to 2.44% and 5.22% during the muscle elongation and compression, respectively.

Published

2022

12. Precise dynamic modeling of pneumatic muscle actuators with modified Bouw–Wen hysteresis model.

Author

Sheikh Sofla, Mohammad, Sadigh, Mohammad Jafar, and Zareinejad, Mohammad

Abstract

Pneumatic muscle actuators (PMAs) are frequently used in a wide variety of biorobotic applications, such as robotic orthoses and wearable exoskeletons, due to their high power/weight ratio and significant compliance. However, the asymmetric hysteresis nonlinearity reduces their fidelity and cause difficulties in the accurate control procedure. In this paper, Bouc–Wen hysteresis model is modified to describe the asymmetric force/length hysteresis of the PMA. The effect of muscle length on hysteretic restoring force is considered in this modified model and experimental results show that the proposed model has a better performance to characterize the asymmetric hysteresis loop of pneumatic muscles. The nonlinear pressure/force model of these actuators also is modeled precisely and its performance is experimentally verified for different muscle lengths. [ABSTRACT FROM AUTHOR]

Published

2021

13. Interval Type-2 Fuzzy Control of Pneumatic Muscle Actuator

Author

Huang, Xiang, Zhang, Hai-Tao, Wu, Dongrui, Zhu, Lijun, Hutchison, David, Series Editor, Kanade, Takeo, Series Editor, Kittler, Josef, Series Editor, Kleinberg, Jon M., Series Editor, Mattern, Friedemann, Series Editor, Mitchell, John C., Series Editor, Naor, Moni, Series Editor, Pandu Rangan, C., Series Editor, Steffen, Bernhard, Series Editor, Terzopoulos, Demetri, Series Editor, Tygar, Doug, Series Editor, Weikum, Gerhard, Series Editor, Chen, Zhiyong, editor, Mendes, Alexandre, editor, Yan, Yamin, editor, and Chen, Shifeng, editor

Published

2018

14. Fuzzy Torque Control of the Bionic Flexible Manipulator Actuated by Pneumatic Muscle Actuators

Author

Kai Liu, Yining Chen, Jiaqi Xu, Yang Wu, Yonghua Lu, and Dongbiao Zhao

Subjects

Pneumatic muscle actuator, Bionic flexible manipulator, Computed torque method, Fuzzy torque control, Ocean engineering, TC1501-1800, Mechanical engineering and machinery, TJ1-1570

Abstract

Abstract A bionic flexible manipulator driven by pneumatic muscle actuator (PMA) can better reflect the flexibility of the mechanism. Current research on PMA mainly focuses on the modeling and control strategy of the pneumatic manipulator system. Compared with traditional electro-hydraulic actuators, the structure of PMA is simple but possesses strong nonlinearity and flexibility, which leads to the difficulty in improving the control accuracy. In this paper, the configuration design of a bionic flexible manipulator is performed by human physiological map, the kinematic model of the mechanism is established, and the dynamics is analyzed by Lagrange method. A fuzzy torque control algorithm is designed based on the computed torque method, where the fuzzy control theory is applied. The hardware experimental system is established. Through the co-simulation contrast test on MATLAB and ADAMS, it is found that the fuzzy torque control algorithm has better tracking performance and higher tracking accuracy than the computed torque method, and is applied to the entity control test. The experimental results show that the fuzzy torque algorithm can better control the trajectory tracking movement of the bionic flexible manipulator. This research proposes a fuzzy torque control algorithm which can compensate the error more effectively, and possesses the preferred trajectory tracking performance.

Published

2019

15. Design, Development, and Control of a Novel Upper-Limb Power-Assist Exoskeleton System Driven by Pneumatic Muscle Actuators

Author

Hsien-Ru Chu, Shean-Juinn Chiou, I-Hsum Li, and Lian-Wang Lee

Subjects

pneumatic muscle actuator, upper-limb exoskeleton system, torsion spring, proxy-based sliding mode controller, linear extended state observer, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

An innovative wearable upper-limb power-assist exoskeleton system (UPES) was designed for laborers to improve work efficiency and reduce the risk of musculoskeletal disorders. This novel wearable UPES consists of four joints, each comprising a single actuated pneumatic muscle actuator (PMA) and a torsion spring module driven via a steel cable. Unlike most single-joint applications, where dual-PMAs are driven by antagonism, this design aims to combine a torsion spring module with a single-PMA via a steel cable for a 1-degree of freedom (1-DOF) joint controlled by a proportional-pressure regulator. The proposed four driving degrees of freedom wearable UPES is suitable for power assistance in work and characterizes a simple structure, safety, and compliance with the motion of an upper limb. However, due to the hysteresis, time-varying characteristics of the PMA, and non-linear movement between joint flexion and extension, the model parameters are difficult to identify accurately, resulting in unmeasurable uncertainties and disturbances of the wearable UPES. To address this issue, we propose an improved proxy-based sliding mode controller integrated with a linear extended state observer (IPSMC-LESO) to achieve accurate power-assisted control for the upper limb and ensure safe interaction between the UPES and the wearer. This control method can slow the underdamped dynamic recovery motion to tend the target trajectory without overshoots from large tracking errors that result in actuator saturation, and without deteriorating the power assist effect during regular operation. The experimental results show that IPSMC-LESO can effectively control a 4-DOF wearable UPES, observe the unknown states and total disturbance online of the system, and adapt to the external environment and load changes to improve system control performance. The results prove that the joint torsion spring module combining the single-PMA can reduce the number of PMAs and proportional-pressure regulators by half and obtain a control response similar to that of the dual-PMA structure.

Published

2022

16. Switching Model Predictive Control for Thin McKibben Muscle Servo Actuator

Author

Mohd Akmal Mhd Yusoff, Ahmad Athif Mohd Faudzi, Mohd Shukry Hassan Basri, Mohd Fuaad Rahmat, Mohd Ibrahim Shapiai, and Shahrol Mohamaddan

Subjects

nonlinear control system, pneumatic artificial muscle, pneumatic muscle actuator, predictive control, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

Dynamic characteristics and control of thin McKibben muscle (TMM) have not yet been fully investigated, especially on the translational antagonistic pair system. Therefore, the objective of this study is to propose a Switching Model Predictive Control (SMPC) based on a Piecewise Affine (PWA) system model to control a translational antagonistic-pair TMM servo actuator. A novel configuration enables the servo actuator to achieve a position control of 40 mm within a small footprint. The result shows that the feedback system gives minimal steady-state errors when tracking staircase and setpoint references ranging from 0 to 3.5 cm. The controller also produces better transient and steady-state responses than our previously developed Gain-scheduled Proportional–Integral–Derivative (GSPID) controller. The evidence from this study suggests that a predictive control for a TMM servo actuator is feasible.

Published

2022

17. Motion Control of Pneumatic Muscle Actuator Using Fast Switching Valve

Author

Xie, Shenglong, Mei, Jiangping, Liu, Haitao, Wang, Panfeng, Zhang, Xianmin, editor, Wang, Nianfeng, editor, and Huang, Yanjiang, editor

Published

2017

18. Fuzzy PD-Type Iterative Learning Control of a Single Pneumatic Muscle Actuator

Author

Ke, Da, Ai, Qingsong, Meng, Wei, Zhang, Congsheng, Liu, Quan, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Huang, YongAn, editor, Wu, Hao, editor, Liu, Honghai, editor, and Yin, Zhouping, editor

Published

2017

19. Adaptive Proxy-Based Robust Control Integrated With Nonlinear Disturbance Observer for Pneumatic Muscle Actuators.

Author

Cao, Yu, Huang, Jian, Xiong, Cai-Hua, Wu, Dongrui, Zhang, Mengshi, Li, Zhijun, and Hasegawa, Yasuhisa

Abstract

In pneumatic muscle actuators (PMAs)-driven robotic applications, there might exist unpredictable shocks which lead to the sudden change of desired trajectories and large tracking errors. This is dangerous for physical systems. In this article, we propose a novel adaptive proxy-based robust controller (APRC) for PMAs, which is effective in realizing a damped response and regulating the behaviors of the PMA via a virtual proxy. Moreover, the integration of the APRC and the nonlinear disturbance observer further handles the system uncertainties/disturbances and improves the system robustness. According to the Lyapunov theorem, the tracking states of the closed-loop PMA control system are proven to be globally uniformly ultimately bounded through two motion phases. Extensive experiments are conducted to verify the superior performance of our approach, in multiple tracking scenarios. [ABSTRACT FROM AUTHOR]

Published

2020

20. Optimizing Control of Passive Gait Training Exoskeleton Driven by Pneumatic Muscles Using Switch-Mode Firefly Algorithm.

Author

Cao, Yu, Huang, Jian, Huang, Zhangbo, Tu, Xikai, and Mohammed, Samer

Subjects

*ROBOTIC exoskeletons, *SLIDING mode control, *STRENGTH training, *PNEUMATIC actuators, *GLOBAL optimization

Abstract

Summary: This paper presents a lower-limb exoskeleton that is actuated by pneumatic muscle actuators (PMAs). This exoskeleton system is composed of the mechanical structures, a treadmill, and a weight support system. With the cooperative work of the three parts, the system aims to assist either the elderly for muscle strengthening by conducting walking activities or the stroke patients during a rehabilitation training program. A mechanism is developed to separate the PMAs from the wearer's legs to reduce the subject's physical exertion. Furthermore, considering the difficulty in the modeling of proposed PMAs-driven exoskeleton, a safe and model-free control strategy called proxy-based sliding mode control (PSMC) is used to ensure proper control of the exoskeleton. However, the favorable performances are strongly dependent on the appropriate control parameters, which may be difficult to obtain with blind tuning. Therefore, we propose a global parameters optimization algorithm called switch-mode firefly algorithm (SMFA) to automatically calculate the pre-defined object function and attain the most applicable parameters. Experimental studies are conducted, and the results show the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2019

21. Sliding-surface dynamic control of a continuum manipulator with large workspace.

Author

Sofla, Mohammad Sheikh, Sadigh, Mohammad Jafar, Hadi Sadati, S.M., Bergeles, Christos, and Zareinejad, Mohammad

Subjects

*REAL-time control, *LYAPUNOV stability, *CONFIGURATION space, *CLOSED loop systems, *ROBOT control systems

Abstract

This paper presents the trajectory tracking control of a multi-section continuum and compliant manipulator with large workspace. Fluidic muscles are utilized as actuators in this manipulator and inertial sensors used to measure its shape in configuration space. The robot's large workspace signifies the effects of the inertial, gravitational, and applied external forces on the trajectory tracking control of the robot end-effector. In this study, a model-based sliding-surface controller is proposed by deriving a simplified Pseudo-Rigid Body (PRB) dynamic model, which utilizes modified constant curvature assumptions to describe the couplings between the robot sections and actuators. Simplification steps are proposed for a PRB dynamic model by eliminating negligible dynamic effects to achieve a computationally efficient implementation with real-time control performance. The unmodeled dynamics and the error of model simplifications are considered as system uncertainties and an integral sliding surface with a variable sliding gain is proposed to overcome these uncertain dynamics. The sliding gain considers changes in the upper bounds of uncertainties. The closed-loop system stability in trajectory tracking is mathematically proved based on the Lyapunov stability theorem. Experiments throughout the manipulator's large workspace in challenging configurations including sudden release of unknown loads at the robot tip also highlight the potential of our contributed controller. [ABSTRACT FROM AUTHOR]

Published

2023

22. A novel Treadmill Body Weight Support system using Pneumatic Artificial Muscle actuators: a comparison between active Body Weight Support system and counter weight system

Author

Van Thuc, Tran, Prattico, Flavio, Yamamoto, Shin-ichiroh, MAGJAREVIC, Ratko, Editor-in-chief, Ladyzynsk, Piotr, Series editor, Ibrahim, Fatimah, Series editor, Lacković, Igor, Series editor, Rock, Emilio Sacristan, Series editor, and Jaffray, David A., editor

Published

2015

23. Measurements for the Thermodynamic Model of a Pneumatic Muscle Actuator

Author

Kopecny, L., Zalud, L., Mukhopadhyay, Subhas Chandra, Series editor, Mason, Alex, editor, and Jayasundera, Krishanthi Padmarani, editor

Published

2015

24. A New Dynamic Modelling Algorithm for Pneumatic Muscle Actuators

Author

Cao, Jinghui, Xie, Sheng Quan, Zhang, Mingming, Das, Raj, Hutchison, David, Series editor, Kanade, Takeo, Series editor, Kittler, Josef, Series editor, Kleinberg, Jon M., Series editor, Kobsa, Alfred, Series editor, Mattern, Friedemann, Series editor, Mitchell, John C., Series editor, Naor, Moni, Series editor, Nierstrasz, Oscar, Series editor, Pandu Rangan, C., Series editor, Steffen, Bernhard, Series editor, Terzopoulos, Demetri, Series editor, Tygar, Doug, Series editor, Weikum, Gerhard, Series editor, Goebel, Randy, Series editor, Tanaka, Yuzuru, Series editor, Wahlster, Wolfgang, Series editor, Siekmann, Jörg, Series editor, Zhang, Xianmin, editor, Liu, Honghai, editor, Chen, Zhong, editor, and Wang, Nianfeng, editor

Published

2014

25. Rotation Control of a 3-DOF Parallel Mechanism Driven by Pneumatic Muscle Actuators.

Author

LIU Kai, CHEN Yining, WU Yang, XU Jiaqi, WANG Yangwei, and GE Zhishang

Subjects

PNEUMATIC actuators, ELASTIC modulus, MATHEMATICAL models, ENERGY conservation laws, DATA analysis

Abstract

The pneumatic muscle actuator (PMA) has many advantages, such as good flexibility, high power / weight ratio, but its nonlinearity makes it difficult to build a static mathematical model with high precision. A new method is proposed to establish the model of PMA. The concept of hybrid elastic modulus which is related to the static characteristic of PMA is put forward, and the energy conservation law is used to achieve the expression of the hybrid elastic modulus, which can be fitted out based on experimental data, and the model of PMA can be derived from this expression. At the same time, a 3 - DOF parallel mechanism(a new bionic shoulder joint)driven by five PMAs is designed. This bionic shoulder joint adopts the structure of two antagonistic PMAs actualizing a rotation control and three PMAs controlling another two rotations to get better rotation characteristics. The kinematic and dynamic characteristics of the mechanism are analyzed and a new static model of PMA is used to control it. Experimental results demonstrate the effectiveness of this new static model. [ABSTRACT FROM AUTHOR]

Published

2019

26. Improved RBF network torque control in flexible manipulator actuated by PMAs.

Author

Liu, Kai, Wu, Yang, Zhu, Tianming, Chen, Yining, Lu, Yonghua, and Zhao, Dongbiao

Subjects

*ACTUATORS, *RADIAL basis functions, *MANIPULATORS (Machinery), *TORQUE control, *PID controllers

Abstract

SUMMARY: A Pneumatic Muscle Actuator (PMA) is a new pneumatic component sharing similar characteristics with biological muscles, and the flexible manipulator actuated by PMAs can better reflect the flexibility of the mechanism. First and foremost, based on the study of the characteristics of human shoulder joints, the configuration design of the flexible manipulator is analyzed, and its kinematics and dynamics models are established. Furthermore, with regard to the nonlinearity, time-invariance and uncertainty of the control system, three aspects of improvement are proposed, which are based on the Radial Basis Function (RBF) network torque control algorithm. The Genetic Algorithm is used to optimize the initial values of RBF network parameters; RBF network parameters are adjusted dynamically by using the additional momentum method; the Levenberg--Marquardt (LM) algorithm, instead of the gradient descent method, is adopted to adjust Proportion Integration Differentiation (PID) parameters online in real time. At last, to test the effects that the improved algorithm exerts on the flexible manipulator control system, some physical platform experiments are carried out. It turns out that the control accuracy and robustness of the improved algorithm are well improved, and the mechanism can be controlled better to track the circular arc trajectory. It lays fundamental importance to the practical application for the working environment. [ABSTRACT FROM AUTHOR]

Published

2019

27. Adaptive proxy-based sliding mode control for a class of second-order nonlinear systems and its application to pneumatic muscle actuators

Author

Yu Cao, Jian Huang, and Yan-Wu Wang

Subjects

0209 industrial biotechnology, Adaptive control, Computer science, Muscles, Applied Mathematics, 020208 electrical & electronic engineering, Sign function, PID controller, 02 engineering and technology, Sliding mode control, Computer Science Applications, Nonlinear system, 020901 industrial engineering & automation, Control and Systems Engineering, Robustness (computer science), Control theory, 0202 electrical engineering, electronic engineering, information engineering, Humans, Electrical and Electronic Engineering, Actuator, Pneumatic muscle actuator, Instrumentation

Abstract

The human-centered robotic systems demand safe and robust controllers in many applications. This paper proposes an adaptive proxy-based sliding mode control approach for a class of typical second-order nonlinear systems. A new PID-type virtual coupling is designed between a virtual proxy and the physical object. Considering the unknown bound of lumped disturbances, an adaptation law is applied to online adjust the gain of a sign function which ensures the proxy to track the reference accurately. By using the Lyapunov theorem, the closed-loop system stability is proved. Both simulations and experiments are conducted to verify the proposed method based on a real-world pneumatic muscle actuator control platform. The results show that the proposed adaptive proxy-based sliding mode control approach presents better tracking accuracy, safety, and robustness than the conventional PID control and sliding mode control.

Published

2022

28. Extended-State-Observer-Based Super Twisting Control for Pneumatic Muscle Actuators

Author

Yu Cao, Zhongzheng Fu, Mengshi Zhang, and Jian Huang

Subjects

extended-state-observer, super twisting control, pneumatic muscle actuator, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

This paper presents a tracking control method for pneumatic muscle actuators (PMAs). Considering that the PMA platform only feedbacks position, and the velocity and disturbances cannot be observed directly, we use the extended-state-observer (ESO) for simultaneously estimating the system states and disturbances by using measurable variables. Integrated with the ESO, a super twisting controller (STC) is design based on estimated states to realize the high-precision tracking. According to the Lyapunov theorem, the stability of the closed-loop system is ensured. Simulation and experimental studies are conducted, and the results show the convergence of the ESO and the effectiveness of the proposed method.

Published

2021

29. Static modeling of braided pneumatic muscle actuator: An amended force model

Author

Deepak Kumar, Saswath Ghosh, and Sitikantha Roy

Subjects

Materials science, business.industry, Structural engineering, Pneumatic muscle actuator, business

Abstract

The present study reports an amended static force model for a pneumatic muscle actuator (PMA) used in different aerodynamic and fluid power system applications. The PMA is a fluid actuator, made of a polymeric bladder enclosed in a braided mesh sleeve. A physics-based static model is developed to predict the deformation response of the actuator for different applied pressure. The significant losses, like braid-to-braid friction, non-cylindrical ends, and bladder hyperelasticity effect, have been considered to enhance the model’s practical feasibility. However, a combined effect of all these losses in the PMA was ignored in the literature. The findings of the derived model agree well with existing experimental results.

Published

2023

30. Implementation of an Upper-Limb Exoskeleton Robot Driven by Pneumatic Muscle Actuators for Rehabilitation

Author

Chun-Ta Chen, Wei-Yuan Lien, Chun-Ting Chen, and Yu-Cheng Wu

Subjects

pneumatic muscle actuator, exoskeleton robot, rehabilitation, fuzzy sliding mode control, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

Implementation of a prototype of a 4-degree of freedom (4-DOF) upper-limb exoskeleton robot for rehabilitation was described in this paper. The proposed exoskeleton robot has three DOFs at the shoulder joint and one DOF at the elbow joint. The upper-limb exoskeleton robot is driven by pneumatic muscle actuators (PMA) via steel cables. To implement the passive rehabilitation control, the rehabilitation trajectories expressed in the Fourier series were first planned by the curve fitting. The fuzzy sliding mode controller (FSMC) was then applied to the upper-limb exoskeleton robot for rehabilitation control. Several rehabilitation scenarios were carried out to validate the designed PMA-actuated exoskeleton robot.

Published

2020

31. 3D DESIGN OF A HUMAN-LIKE HAND ACTUATED BY PNEUMATIC MUSCLE ACTUATORS IN SOLID EDGE.

Author

SÁROSI, József, BAGI, István, VIRÁG, Dávid, GOGOLÁK, László, and FURSTNER, Igor

Subjects

*PNEUMATIC actuators, *FLUIDICS

Abstract

A lesser known type of pneumatic actuators is pneumatic muscle actuator (PMA) although the first investigations related to PMAs are mentioned by a Russian researcher Garasiev in 1930s. Recently, the most often applied PMA is the Fluidic Muscle manufactured by Festo Company. Generally, PMAs differ from standard cylindrical pneumatic actuators as they have no inner moved parts and there is no sliding on the surfaces. Another difference is that the force develepod by a standard cylindrical pneumatic actuator depends only on the applied pressure and piston surface but the force produced by a PMA depends on the displacement as well. This paper focuses on PMA, especially Fluidic Muscle and a human-like hand actuated by PMAs designed in Solid Edge by academic students is presented. [ABSTRACT FROM AUTHOR]

Published

2018

32. SELECTION OF COMPUTATIONAL INTELLIGENCE METHODS DESIGNED FOR APPLICATION IN PNEUMATIC MUSCLE ACTUATOR.

Author

TOTHOVA, MARIA and TROJANOVA, MONIKA

Subjects

COMPUTATIONAL intelligence, PNEUMATIC actuators, SOFT robotics, DEGREES of freedom, DISPLACEMENT (Mechanics)

Abstract

Pneumatic muscle actuators have the highest power/weight ratio of any actuator and therefore it has a broad application prospect in soft robotics. This paper presents a two degree of freedom (2-DOF) pneumatic muscle actuator that consists of four pneumatic artificial muscles (PAMs) and two rotation joins. However, this pneumatic muscle actuator has highly nonlinear and hysteretic properties (among muscle force, muscle displacement and pressure in the muscle), which lead to difficulty in accurate position control. Pneumatic muscle actuator usually necessitate the use various nonlinear techniques for control in order to improve their performance. The paper contains selection of computational intelligence methods designed for application in pneumatic muscle actuator. There are described and compared MLP neural network and RBF neural network. [ABSTRACT FROM AUTHOR]

Published

2017

33. Precise dynamic modeling of pneumatic muscle actuators with modified Bouw–Wen hysteresis model

Author

Mohammad Jafar Sadigh, Mohammad Zareinejad, and Mohammad Sheikh Sofla

Subjects

0209 industrial biotechnology, Computer science, Quantitative Biology::Tissues and Organs, Mechanical Engineering, Wearable computer, 02 engineering and technology, 021001 nanoscience & nanotechnology, Industrial and Manufacturing Engineering, Exoskeleton, System dynamics, Computer Science::Robotics, Hysteresis, 020901 industrial engineering & automation, Control theory, Bouc–Wen model of hysteresis, 0210 nano-technology, Pneumatic muscle actuator, Actuator

Abstract

Pneumatic muscle actuators (PMAs) are frequently used in a wide variety of biorobotic applications, such as robotic orthoses and wearable exoskeletons, due to their high power/weight ratio and significant compliance. However, the asymmetric hysteresis nonlinearity reduces their fidelity and cause difficulties in the accurate control procedure. In this paper, Bouc–Wen hysteresis model is modified to describe the asymmetric force/length hysteresis of the PMA. The effect of muscle length on hysteretic restoring force is considered in this modified model and experimental results show that the proposed model has a better performance to characterize the asymmetric hysteresis loop of pneumatic muscles. The nonlinear pressure/force model of these actuators also is modeled precisely and its performance is experimentally verified for different muscle lengths.

Published

2021

34. Pneumatic bio-soft robot module: Structure, elongation and experiment.

Author

Bao Guanjun, Yao Pengfei, Xu Zonggui, Li Kun, Wang Zhiheng, Zhang Libin, and Yang Qinghua

Subjects

*PNEUMATICS, *SOFT robotics, *BIONICS, *HARVESTING, *IMAGE segmentation

Abstract

Soft robotics, often taking inspirations from biomimetics, is an exciting novel research field and has great capability to work with creatures. A new type of bio-soft robot inspired by elephant trunk and octopus was proposed, which has a promising application in robotic agricultural harvesting. The two modularized structures, basal segment and caudal segment, were elaborated in detail. They both have three side chambers and one central chamber, which are reinforced by springs for better stretch performance in axial direction without radial expansion. All the chambers can act as drivers when inflated with compressed air. More importantly, the central chamber was designed for regulating the stiffness of the robot module as needed in application. The primary static model for axial elongation was established for the fundamental analysis of the bio-soft robot module's features, such as iso-force, isobaric and isometric characteristics. Simulation and experimental results showed that the motion of the proposed bio-soft module has approximate linearity in iso-force and isobaric conditions, and strict linearity in isometric condition. [ABSTRACT FROM AUTHOR]

Published

2017

35. A Novel Force Sensorless Reflecting Control for Bilateral Haptic Teleoperation System

Author

Kyoung Kwan Ahn, Cong Phat Vo, and Xuan Dinh To

Subjects

0209 industrial biotechnology, General Computer Science, Observer (quantum physics), pneumatic muscle actuator, Computer science, 020208 electrical & electronic engineering, General Engineering, Stability (learning theory), 02 engineering and technology, Tracking (particle physics), force observer, 020901 industrial engineering & automation, Control theory, Teleoperation, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Artificial muscle, lcsh:Electrical engineering. Electronics. Nuclear engineering, Transparency (data compression), Bilateral teleoperation system, lcsh:TK1-9971, Haptic technology

Abstract

This paper presents a novel force sensorless reflecting controller for a haptic-enabled device driven by a bilateral pneumatic artificial muscle system, which proposed configuration for the first time the bilateral haptic teleoperation. For details, an adaptive force observer scheme considered to be an alternative to direct force measurement is proposed to estimate the interaction force with an unknown environment for the force reflecting control design. Meanwhile, the separately fast finite time nonsingular terminal sliding mode control schemes are developed based on the force estimation in both subsystems to achieve good tracking performance and fast response. Thus, the great transparency performance with both force feedback and position tracking can be achieved simultaneously by using our proposed method. The finite-time stability of the total controlled system is demonstrated by the Lyapunov approach. Moreover, the comparative experiments are carried out on the developed testbench to validate the effectiveness and advantages of our proposed control design in the different working conditions.

Published

2020

36. DESIGN AND CONSTRUCTION OF A HUMANOID ARM DRIVEN BY PNEUMATIC MUSCLE ACTUATOR.

Author

SÁROSI, József and GYÜRKY, Bence

Subjects

*INDUSTRIAL robots, *PNEUMATICS, *ACTUATORS

Abstract

Electrics, hydraulics and pneumatics can be the main motion power of industrial robots. Pneumatic cylinders, pneumatic motors, pneumatic stepper motors and pneumatic bellows are widely used in industrial environment due to their power/weight ratio, power/volume ratio, strength, compactness, simplicity, reliability and cost. Disadvantages of pneumatic actuators can be summarized as follows: difficult to control accurately, air compressibility, compliance and noisiness. Relatively new type of the pneumatic actuators is the pneumatic artificial muscle (PAM) or pneumatic muscle actuator (PMA). Fluidic Muscle made by Festo Company is one of the most investigated commercially available PMA. Pneumatic muscle actuators can be used in industrial environment as well as in prosthesis or rehabilitation devices. In this paper a humanoid arm actuated by Fluidic Muscle is developed and presented. [ABSTRACT FROM AUTHOR]

Published

2016

37. TORQUE CHARACTERISTICS OF ROTARY PNEUMATIC MUSCLE ACTUATOR.

Author

BALARA, MILAN and TOTHOVA, MARIA

Subjects

TORQUE, PNEUMATIC actuators, AIR pressure, ARTIFICIAL muscles, STIFFNESS (Mechanics)

Abstract

The control of the standard pneumatic muscle actuators is provided by increasing the air pressure in the one artificial muscle, while reducing the pressure in the second (antagonist) artificial muscle. The paper contains information about the control and basic properties of the rotary actuator based on pneumatic artificial muscles. It presents equations for the values of the actuator arm displacement depending on an input pressure; it shows the static characteristics of the actuator and the utilization of the muscle contraction. Pneumatic artificial muscles are connected in an antagonistic system through an oval centrally symmetric pulley. Due to the fact that with increasing rotating of actuator arm the torque decrease from the both artificial muscles; the stiffness of the actuator also decreasing in both directions. The proposed method of the present control in this paper has resulted in a small increase of torque of the rotary muscle actuator and thus adequate and symmetric stiffness of actuator. [ABSTRACT FROM AUTHOR]

Published

2016

38. Hammerstein model for hysteresis characteristics of pneumatic muscle actuators

Author

Ai, Qingsong, Peng, Yuan, Zuo, Jie, Meng, Wei, and Liu, Quan

Published

2019

39. Adaptive Backstepping Position Control of Pneumatic Anthropomorphic Robotic Hand.

Author

Farag, Mohannad and Azlan, Norsinnira Zainul

Subjects

ADAPTIVE control systems, PNEUMATIC control, ROBOT hands, COMPUTER algorithms, ARTIFICIAL muscles, EMPIRICAL research, NONLINEAR theories, ACTUATORS

Abstract

This paper presents a nonlinear adaptive backstepping algorithm for position control of an anthropomorphic robotic hand. The contraction force of the pneumatic artificial muscle (PAM) actuators has been modeled based on an empirical approach and the overall finger is represented as a nonlinear second order system, taking into account the system uncertainty caused by hysteresis phenomenon in PAM actuators. Adaptive backstepping controller has been developed by formulating the estimator of the system uncertainty. A cascade control system is developed by combining a conventional PID control, as an inner loop controller, with the adaptive backstepping position control as the outer loop of the controller. Finally, a simulation test is conducted to evaluate the performance of the proposed controller. [ABSTRACT FROM AUTHOR]

Published

2015

40. A bundled staggering patterned pneumatic muscle actuator for improved working efficiency

Author

Hyungpil Moon, Kyeong Ha Lee, Hyouk Ryeol Choi, Young Min Lee, Ja Choon Koo, and Hyuk Jin Lee

Subjects

0209 industrial biotechnology, Interference problem, Computer science, Mechanical Engineering, Soft robotics, 02 engineering and technology, Small form factor, Computer Science::Robotics, 020303 mechanical engineering & transports, 020901 industrial engineering & automation, 0203 mechanical engineering, Interference (communication), Mechanics of Materials, Control theory, Bundle, Artificial muscle, Actuator, Pneumatic muscle actuator

Abstract

Recently many new actuators have been developed in order to overcome the limitations of conventional actuators. The pneumatic artificial muscle actuator (PMA) is one of the typical examples. Although many studies have been conducted on the single PMA, there are still many limitations of the single PMA operation. The typical problems are low efficiency and limited force output. In order to overcome these limitations, the parallel band PMA (PPMA) consisting of a bundle of PMAs has been developed instead of the single PMA. However, due to the simple actuator driving principle, the parallel PMA causes another problem such as an interference between each PMAs placed side by side. In this paper, we proposed a new bundled staggering patterned pneumatic artificial muscle actuator (SPMA) to resolve the interference problem. The SPMA consists of a bundle of staggered pattern actuators that ensures the large actuation force with a small form factor. To verify the performance of the proposed SPMA, output force and operating range have been compared to those of the existing PPMA by conducting simulation and experiments.

Published

2019

41. DESIGN, FABRICATION AND TESTING OF PNEUMATIC MUSCLE ACTUATOR FOR ARTIFICIAL HUMAN ARM

Author

Adithya R Upadhya, Altamash Rayan H, and Muralidhara .

Subjects

Fabrication, Human arm, Computer science, Mechanical Engineering, Mechanical engineering, Pneumatic circuit, Pneumatic muscle actuator, Load carrying

Abstract

This paper provides detailed design and characterisation of the Pneumatic Muscle Actuator (PMA) proposed for actuating an artificial human arm. The anatomy and the load carrying capacity of the human arm are considered for designing the PMA. The PMA is fabricated using the braided sleeve and latex tubes, and a pneumatic circuit is designed for its characterisation. The proposed artificial human arm with PMA can be used as a teaching aid to simulate neurological disorders.

Published

2019

42. Using the Bioelectric Signals to Control of Wearable Orthosis of the Elbow Joint with Bi-Muscular Pneumatic Servo-Drive

Author

Ryszard Dindorf and Piotr Wos

Subjects

0209 industrial biotechnology, Computer science, General Mathematics, Elbow, Wearable computer, 02 engineering and technology, Muscular tension, Computer Science Applications, 03 medical and health sciences, 020901 industrial engineering & automation, 0302 clinical medicine, medicine.anatomical_structure, Control and Systems Engineering, Control theory, medicine, Servo drive, Distributed control system, Joint (audio engineering), Pneumatic muscle actuator, 030217 neurology & neurosurgery, Software, Simulation

Abstract

SUMMARYThis study presents a new design of a wearable orthosis of elbow joint with a bimuscular pneumatic servo-drive (PSD) with control based on the recording of bioelectric signals (BESs). The authors analyzed the impact of the induced brain activity and the muscular tension within the head of the participant on the BESs that can be used to control the PSD of the elbow joint orthosis. To control the elbow joint orthosis, a distributed control system (DCS) was developed, which contains two control layers: a master layer connected to the device for recording the BES and a direct layer contained in a wireless manner with the controller of the PSD. A kinematic-dynamic model of the elbow joint orthosis, patterned after the biological model of human biceps–triceps, was used in the programming of the PSD controller. A biomimetic dynamic model of the pneumatic muscle actuator (PMA) was used, in which the contraction force results from the adopted exponential static model of the pneumatic muscle (PM). The use of direct visual feedback (DVF) makes it possible for the participant to focus on the movement of the orthosis taking into account the motoric functions of the elbow.

Published

2019

43. A Sampled-Data Approach to Nonlinear ESO-Based Active Disturbance Rejection Control for Pneumatic Muscle Actuator Systems with Actuator Saturations

Author

Lei Guo, Yang Yu, Zidong Wang, and Yuan Yuan

Subjects

Disturbance (geology), Computer science, 020208 electrical & electronic engineering, 02 engineering and technology, Active disturbance rejection control, Compensation (engineering), Nonlinear system, Control and Systems Engineering, Control theory, 0202 electrical engineering, electronic engineering, information engineering, State observer, Electrical and Electronic Engineering, Robust control, Pneumatic muscle actuator, Actuator

Abstract

In this paper, an active disturbance rejection control scheme with a nonlinear sampled-data extended state observer (NSESO) is proposed for a pneumatic muscle actuator (PMA) system. The phenomenon of the actuator saturation is taken into account in the design procedure. The NSESO is utilized to estimate the so-called total disturbance that reflects the aggregated impacts of unmodeled nonlinearities and disturbances. Then, an NSESO-based composite control strategy is designed, where the estimates provided by the designed NSESO serve as the compensation to eliminate the total disturbance. Finally, a number of practical experiments on the PMA systems are conducted to verify the validity and applicability of the proposed design method.

Published

2019

44. A Phenomenological Model-Based Controller for Position Tracking of a Pneumatic Muscle Actuator Driven Setup

Author

Jun Zhong and Chun Zhao

Subjects

General Computer Science, Computer science, Pneumatic muscle actuators, Position tracking, position tracking, General Engineering, feed-forward compensated controller, dynamics, fitted model, Control theory, Phenomenological model, General Materials Science, lcsh:Electrical engineering. Electronics. Nuclear engineering, Pneumatic muscle actuator, lcsh:TK1-9971

Abstract

Pneumatic muscle actuators (PMAs) have been attracting attention in recent years due to characteristics of natural compliance, high power output, lightweight, and low cost. Various apparatus and robots are developed by adopting PMAs and kinds of advanced controlling strategies are proposed to improve achieving accuracy. However, many of the proposed models and strategies are very complex and not suitable for the actual application. In this paper, we devise a single PMA driven setup and build up empirical quartic polynomial models of the apparatus by fitting sampled pressure-displacement data. The novel models are compact and easily computable. An improved PID algorithm by employing the phenomenological models as feed-forward is devised to improve the dynamical response of the setup. The experiments are performed to assess the proposed controller in improving the position accuracy of the apparatus.

Published

2019

45. Positioning Control of an Antagonistic Pneumatic Muscle Actuated System using Feedforward Compensation with Cascaded Control Scheme

Author

Y. Chan, C., H. Chong, S., L. Loh, S., Alias, A., Kasdirin, H. A., Y. Chan, C., H. Chong, S., L. Loh, S., Alias, A., and Kasdirin, H. A.

Abstract

This paper presents a feedforward compensation with cascaded control scheme (FFC) for the positioning control of a vertical antagonistic based pneumatic muscle actuated (PMA) system. Owing to the inherent nonlinearities and time varying parameters exhibited by PMA, conventional fixed controllers unable to demonstrate high positioning performance. Hence, the feedforward compensation with cascaded control scheme is proposed whereby the scheme includes a PID controller coupled with nonlinear control elements. The proposed scheme has a simple control structure in addition to its straightforward design procedures. Though there are nonlinear control elements involved, these elements are derived from the open loop system responses that does not requires any accurate known parameters. Performance of the FFC scheme are then evaluated experimentally and compared to a PID controller with feedforward compensation (FF-PID) in point-to-point motion of different step heights. Overall, the experimental results show that the effectiveness of the proposed FFC scheme in reducing the steady state error to zero in comparison to FF-PID controller for all cases of step heights examined.

Published

2020

46. Extended-State-Observer-Based Super Twisting Control for Pneumatic Muscle Actuators

Author

Zhongzheng Fu, Yu Cao, Mengshi Zhang, and Jian Huang

Subjects

0209 industrial biotechnology, Control and Optimization, Computer science, pneumatic muscle actuator, 020208 electrical & electronic engineering, Control (management), 02 engineering and technology, Tracking (particle physics), Stability (probability), lcsh:Production of electric energy or power. Powerplants. Central stations, 020901 industrial engineering & automation, super twisting control, Control and Systems Engineering, Control theory, Position (vector), Convergence (routing), extended-state-observer, lcsh:TK1001-1841, 0202 electrical engineering, electronic engineering, information engineering, lcsh:TA401-492, lcsh:Materials of engineering and construction. Mechanics of materials, State observer, Actuator

Abstract

This paper presents a tracking control method for pneumatic muscle actuators (PMAs). Considering that the PMA platform only feedbacks position, and the velocity and disturbances cannot be observed directly, we use the extended-state-observer (ESO) for simultaneously estimating the system states and disturbances by using measurable variables. Integrated with the ESO, a super twisting controller (STC) is design based on estimated states to realize the high-precision tracking. According to the Lyapunov theorem, the stability of the closed-loop system is ensured. Simulation and experimental studies are conducted, and the results show the convergence of the ESO and the effectiveness of the proposed method.

Published

2021

47. Regelung von pneumatisch-muskel-aktuierten Gelenken in robotischen Anwendungen:pneumatische Muskeln und Roboter mittels einer Momentenregler-Schnittstelle verbinden

Author

Martens, Mirco, Raisch, Jörg, Boblan, Ivo, Technische Universität Berlin, and Seel, Thomas

Subjects

Pneumatischer Muskelaktor, pneumatic artificial muscle, Pneumatisch-muskelaktuierte Gelenke, pneumatic-muscle-actuator-driven joints, PMA-driven joint, pneumatic muscle actuator, PAM, K��nstlicher Pneumatischer Muskel, ddc:620, 620 Ingenieurwissenschaften und zugeordnete T��tigkeiten, PMA

Abstract

Many robotic systems can be improved by novel, lightweight, and elastic actuators. While smaller weight reduces the kinetic energy of the system, elasticity offers the potential to absorb and release potential energy. Thus, the safety of the robot can be increased only by the use of light and elastic actuators, so that there is less energy transmitted in the case of collisions and damages or injuries would therefore be milder. In addition, stored potential energy can be used to perform motion sequences with increased energy efficiency. One type of these actuators are pneumatic-muscle-actuator-driven joints ��� a combination of two pneumatic-muscle-actuators (PMAs) and a pulley ���, as they provide a high torque-to-weight ratio with an adjustable stiffness. Analogously to biological muscle pairs, PMA-driven joints also yield the opportunity to change their stiffness via co-contraction and, due to this, to adapt to the demands of varying tasks. The investigation of the properties of PMA-driven joints and their integration into robotic systems form the core of this dissertation. Since PMA-driven joints consist essentially of two pneumatic muscle actuators, there is an initial chapter devoted to force modeling of pneumatic muscles in addition to the study of PMA-driven joints. It compares existing force models based on a new quality measure and introduces a new model with higher accuracy. Although there were numerous publications on robots with PMA-driven joints prior to this work, little attention has been given to their properties in general. It remains mostly unclear why a specific robot with PMA-driven joints is able to fulfill its task and how this depends on the characteristics of the chosen PMA-driven joints. Motivated by this, the present thesis provides a general discussion on the characteristics of PMA-driven joints, like their static torque range, their joint stiffness and the bandwidth of their joint torque. All results are discussed with the goal to drive a robotic system with PMA-driven joints and all essential information will be provided within this thesis. With this information at hand it will be demonstrated how to use this information to drive three different robotic systems with PMA-driven joints, successfully. Unlike most other publications on robots with PMA-driven joints, the focus of this work is less on the issue of controlling a particular robot but rather on discussing, developing and proposing a general framework for successful control of any robot with PMA-driven joints. Depending on the robot and its task, joint torques must be provided at an adequate height and speed, and only if these specifications can be met by the actuators, the robot can fulfill its task. As an interface between the robot on the one side and the actuators on the other side, a torque controller for PMA-driven joints will be developed and employed for different applications in this thesis. With this torque controller in place, the complex PMA-driven joint dynamics can be reduced to only the static torque characteristic and the bandwidth of the controller. Since these properties of PMA-driven joints are examined in detail in this dissertation, this thesis forms the necessary basis for the successful application of PMA-driven joints in robotic systems. The simplicity of integrating PMA-driven joints under torque control into robots will be demonstrated by using three different robots. Firstly, a robot with one degree of freedom is positioned with PMA-driven joints, and secondly, the same is demonstrated for a robot with two degrees of freedom. Lastly, a rehabilitation robot with a PMA-driven joint is realized which facilitates a controlled-active-motion therapy, as used after cruciate ligament rupture., Viele Robotersysteme k��nnen durch neuartige, leichte und elastische Aktoren verbessert werden. W��hrend ein geringeres Gewicht die kinetische Energie des Systems ver�� ringert, bietet Elastizit��t die M��glichkeit, potentielle Energie aufzunehmen und wieder abzugeben. Somit erh��ht sich, allein durch den Einsatz leichter und elastischer Aktoren, die Sicherheit des Roboters, da im Falle einer Kollision weniger Energie ��bertragen wird und somit Sch��den oder Verletzungen milder ausfallen. Dar��ber hinaus kann gespeicherte potentielle Energie dazu genutzt werden, Bewegungsabl��ufe mit erh��hter Energieeffizienz auszuf��hren. Aktoren mit variabler Elastizit��t und einem besonders ho�� hen Kraft-zu-Eigengewicht-Verh��ltnis sind pneumatisch-muskel-aktuierte (PM-aktuierte) Gelenke. Analog zu biologischen Muskelpaaren haben auch PM-aktuierte Gelenke die M��glichkeit, ihre Steifigkeit durch Kokontraktion zu ��ndern und sich so an die Anspr��che variierender Aufgaben anzupassen. Die Untersuchung der Eigenschaften dieser Aktoren und deren Integration in Robotersysteme bilden den Kern der vorliegenden Arbeit. Obwohl es bereits vor dieser Arbeit zahlreiche Publikationen zu Robotern mit PM-ak�� tuierten Gelenken gab, wurden deren Eigenschaften nicht ausreichend diskutiert. In dieser Dissertation wird die Diskussion ��ber die Charakteristiken von PM-aktuierten Gelenken bereitgestellt. Im Gegensatz zu anderen Publikationen ��ber Roboter mit PM-aktuierten Gelenken steht weniger die Frage nach der Regelung eines bestimmten Roboters im Vordergrund, sondern vielmehr die Grundlage f��r eine erfolgreiche Regelung eines beliebigen Roboters mit PM-aktuierten Gelenken. Je nach Roboter und dessen Aufgabe m��ssen Gelenkmomente in ad��quater H��he und Geschwindigkeit bereitgestellt werden, und nur falls diese Vorgaben von den Aktoren eingehalten werden k��nnen, kann der Roboter seine Aufgabe erf��llen. Die Schnittstellenkommunikation zwischen dem Roboter und den Aktoren ��bernimmt ein in dieser Arbeit entwickelter Momentenregler. Mit diesem Momentenregler kann das PM-aktuierte Gelenk ausschlie��lich anhand seiner statischen Momentencharakteristik und der Bandbreite des Reglers beschrieben werden. Da die Eigenschaften PM-aktuierter Gelenke in dieser Dissertation vordergr��ndig unter�� sucht werden, bildet die vorliegende Arbeit die n��tige Grundlage f��r einen erfolgreichen Einsatz PM-aktuierter Gelenke in Robotern. Die Einfachheit, PM-aktuierte Gelenke mit Momentenregler in Roboter zu integrieren, wird anhand dreier verschiedener Roboter gezeigt. Dabei werden jeweils ein Roboter mit einem Freiheitsgrad und ein Roboter mit zwei Freiheitsgraden in der Position geregelt sowie ein Rehabilitationsroboter, der die M��glichkeit bietet, eine Widerstandsmomententrajektorie beliebig vorzugeben. Da PM-aktuierte Gelenke im Wesentlichen aus zwei pneumatischen Muskelaktoren bestehen, ist neben der Untersuchung von PM-aktuierten Gelenken ein Kapitel dieser Dissertation zun��chst der Kraftmodellierung pneumatischer Muskeln gewidmet. In diesem werden bestehende Kraftmodelle anhand eines neuen G��tema��es miteinander verglichen und ein neues Model mit h��herer Genauigkeit eingef��hrt.

Published

2021

48. Experimental Comparisons of Sliding Mode Controlled Pneumatic Muscle and Cylinder Actuators.

Author

Jouppila, Ville, Gadsden, S. Andrew, and Ellman, Asko

Subjects

*PNEUMATIC motors, *ACTUATOR testing, *SLIDING mode control, *ALGORITHMS, *ROBUST control

Abstract

Pneumatic muscle actuators offer a higher force-to-weight ratio compared to traditional cylinder actuators, and introduce stick-slip-free operation that offers an interesting option for positioning systems. Despite several advantages, pneumatic muscle actuators are commonly avoided in industrial applications, mainly due to rather different working principles. Due to the highly nonlinear characteristics of the muscle actuator and pneumatic system, a reliable control strategy is required. Although muscle actuators are widely studied, the literature lacks detailed studies where the performance for servo systems is compared with traditional pneumatic cylinders. In this paper, a pneumatic servo actuation system is compared with a traditional cylinder actuator. As the overall system dynamics are highly nonlinear and not well defined, a sliding mode control (SMC) strategy is chosen for the control action. In order to improve the tracking performance, an SMC strategy with an integral action (SMCI) is also implemented. The control algorithms are experimentally applied on the pneumatic muscle and the cylinder actuator, for the purposes of position tracking. The robustness of the systems are verified and compared by varying the applied loads. [ABSTRACT FROM AUTHOR]

Published

2014

49. Isotonic characteristics of a pneumatic muscle actuator.

Author

Kulesza, Zbigniew

Subjects

*PNEUMATIC control, *NUMERICAL calculations, *MATHEMATICAL models, *HUMAN-robot interaction, *HUMANOID robots, *ROBOTICS

Abstract

The article presents the problems of determination of the static characteristics of the pneumatic muscle actuator for an artificial hand. The procedure of experimental investigation of the constant load characteristics (the so called isotonic characteristics) of the muscle is described. A new mathematical model for the isotonic characteristics is developed based on the geometry of the muscle. The new model provides a very good agreement between the calculation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2014

50. Design and Fabrication of a Test Rig for Performance Analysis of a Pneumatic Muscle Actuator

Author

Vijay Desai, M. Yashas, Antonio Dylan Do Rosario Carvalho, and P. Navin Karanth

Subjects

Fabrication, Computer science, business.industry, Test rig, Robotics, Ranging, Artificial intelligence, Pneumatic muscle actuator, Actuator, business, Automotive engineering, Datasheet, Power (physics)

Abstract

Artificial pneumatic muscle actuator (PMA) is used to convert pneumatic power to mechanical force. These actuators are like biological muscles, hence its name. PMAs have a wide range of applications ranging from robotics, industrial to the medical applications, as a result of its high power-to-weight ratio, nonhazardous, and compliant nature. The PMA, like any other actuator, has to be tested and validated before using it in any real-world application. An experimental procedure is set up to allow the designer to predict, analyze, and optimize PMA performance before its use in sensitive applications. To achieve this, a rigid experimental test rig needs to be designed to test properties of PMA such as displacement, force, and load capacity. Result of the experiment conducted on the standard PMA by using developed test rig has 5% variation with the values of the manufacturer’s datasheet.

Published

2020