Vol: 59(73) No: 1 / June 2014 Robust Positioning Control of Pneumatic Muscle Actuator at Different Temperatures József Sárosi Technical Institute, University of Szeged, Faculty of Engineering, Moszkvai krt. 9, 6725 Szeged, Hungary, phone: (3662) 546-571, e-mail: sarosi@mk.u-szeged.hu, web: http://www.mk.u-szeged.hu/szte_profiles/9 Keywords: Pneumatic muscle actuator, robust control, sliding mode controller, LabVIEW, temperature effect, accurate positioning Abstract Pneumatic muscle actuator (PMA) or pneumatic artificial muscle (PAM) is the less well-known type of pneumatic actuators. It consists of a thin, flexible, tubular membrane with fibre reinforcement. When the membrane is pressurized the gas pushes against its inner surface and against the external fibre. Then the PAM expands radially and contracts axially with the result that the volume increases. The force and motion produced by PAM are linear and unidirectional. It differs from general pneumatic cylinder actuators as they have no inner moved parts and there is no sliding on the surfaces. Besides, they have small weight, simple construction and low cost. During action they reach high velocities, while the power/weight and the power/volume ratios reach high levels. Because of their highly nonlinear and time varying nature, PAMs are difficult to control thus robust control method is needed. In this paper a LabVIEW based sliding mode controller is developed to eliminate the effects of these drawbacks. The positioning error of a pneumatic muscle actuator at different temperatures is determined. The error of the experiments shows 0.01 mm. This paper is organized in four sections. After Introduction, Section II illustrates the steps to designing sliding mode controller. In this section the experimental rigs and LabVIEW programs are also shown. The internal and external temperatures of the PAM at different operating frequencies are compared and the effect of temperature on the accuracy of the positioning is given in Section III. Finally, conclusion and future work are summarized in Section IV. References [1] F. Daerden, “Conception and Realization of Pleated Artificial Muscles and Their Use as Compliant Actuation Elements,” Ph.D. dissertation, Wetenschappen Vakgroep Werktuigkunde, Faculteit Toegepaste, Vrije Universiteit Brussel, 1999. [2] F. Daerden and D. Lefeber, “Pneumatic Artificial Muscles: Actuator for Robotics and Automation,” European Journal of Mechanical and Environmental Engineering, vol. 47, pp. 10-21, 2002. [3] T. Kerscher, J. Albiez, J. M. Zöllner and R. Dillmann, “FLUMUT - Dynamic Modelling of Fluidic Muscles Using Quick-Release,” 3rd International Symposium on Adaptive Motion in Animals and Machines, Ilmenau, Germany, 2005, pp. 1-6. [4] L. Dragan, “Theoretical and Experimental Research about the Linear Pneumatic Actuators with Cylindrical Membrane and Braided Shell,” International Conference on Automation Quality and Testing Robotics (AQTR), Cluj-Napoca, Romania, 2010, pp. 1-6. [5] J. H. Lilly, “Adaptive Tracking for Pneumatic Muscle Actuators in Bicep and Tricep Configurations,” IEEE Transactions on Neural Systems and Rehabilitation Engineering, vol. 11, pp. 333-339, 2003. [6] K. C. Wickramatunge and T. Leephakpreeda, “Empirical Modeling of Pneumatic Artificial Muscle,” International MultiConference of Engineers and Computer Scientists 2009 (IMECS 2009), Kowloon, Hong Kong, 2009, pp. 1726-1730. [7] T. Y Choi, J. J. Kim and J. J. Lee, “An Artificial Pneumatic Muscle Control Method on the Limited Space,” International Joint Conference 2006 (SICE-ICASE), Bexco, Busan, Korea, 2006, pp. 4738-4743. [8] C. P. Chou and B. Hannaford, “Measurement and Modeling of McKibben Pneumatic Artificial Muscles,” IEEE Transactions on Robotics and Automation, vol. 12, pp. 90-102, 1996. [9] B. Tondu and P. Lopez, “Modeling and Control of McKibben Artificial Muscle Robot Actuators,” IEEE Control Systems Magazine, vol. 20, pp. 15-38, 2000. [10] D. B. Reynolds, D. W. Repperger, C. A. Phillips and G. Bandry, “Modeling the Dynamic Characteristics of Pneumatic Muscle,” Annals of Biomedical Engineering, vol. 31, pp. 310-317, 2003. [11] J. Sárosi, “New Approximation Algorithm for the Force of Fluidic Muscles,” 7th IEEE International Symposium on Applied Computational Intelligence and Informatics (SACI 2012), Timisoara, Romania, 2012, pp. 229-233. [12] M. Tothova and J. Pitel, “Dynamic Model of Pneumatic Actuator Based on Advanced Geometric Muscle Model,” 9th International Conference on Computational Cybernetics (ICCC 2013), Tihany, Hungary, 2013, pp. 83-87. [13] J. Pitel and M. Tothova, “Dynamic Modeling of PAM Based Actuator Using Modified Hill\'s Muscle Model,” 14th International Carpathian Control Conference (ICCC), Rytro, Poland, 2013, pp. 307-310. [14] M. Tothova and A. Hosovsky, “Dynamic Simulation Model of Pneumatic Actuator with Artificial Muscle,” 11th International Symposium on Applied Machine Intelligence and Informatics (SAMI), Herl\'any, Slovakia, 2013, pp. 47-51. [15] Z. Situm and S. Herceg, “Design and Control of a Manipulator Arm Driven by Pneumatic Muscle Actuators,” 16th Mediterranean Conference on Control and Automation, Ajaccio, France, 2008, pp. 926-931. [16] Festo, Fluidic Muscle DMSP, with Press-fitted Connections, Fluidic Muscle MAS, with Screwed Connections. Festo product catalog, 2005. [17] J. Sárosi, “Accurate Positioning of Pneumatic Artificial Muscle at Different Temperatures Using LabVIEW Based Sliding Mode Controller,” 9th IEEE International Symposium on Applied Computational Intelligence and Informatics (SACI 2014), Timisoara, Romania, 2014, pp. 85-89. [18] V. I. Utkin, “Sliding Mode Control Design Principles and Applications to Electric Drives,” IEEE Transactions on Industrial Electronics, vol. 40, pp. 23-36, 1993. [19] G. Monsees, “Discrete-Time Sliding Mode Control,” Ph.D. dissertation, Technische Universiteit Delft, 2002. [20] W. Perruquetti and J. P. Barbot, Sliding Mode Control in Engineering. Marcel Dekker, New York, Basel, 2002. [21] K. J. Kim, J. B. Park and Y. H. Choi, “Chattering Free Sliding Mode Control,” International Joint Conference 2006 (SICE-ICASE), Bexco, Busan, Korea, 2006, pp. 732-735. [22] C. Vecchio, Sliding Mode Control: Theoretical Developments and Applications to Uncertain Mechanical Systems. Università degli Studi di Pavia, 2008. [23] K. Lamár and G. A. Kocsis, “Implementation of Speed Measurement for Electrical Drives Equipped with Quadrature Encoder in LabVIEW FPGA,” Acta Technica Corviniensis, Bulletin of Engineering, vol. 6, pp. 123-126, 2013. [24] N. S. Bao, S. L. Fei, X. J. Huang., T. Q. Liu and J. Huang, “Labview-Based Automatic Four-Axis Positioning Control Air Temperature and Wind Speed Detection Platform for Drying Oven,” Advanced Materials Research, Advanced Measurement and Test III, vol. 718-720, pp. 1547-1553, 2013. |