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Chopper Control of a Bipolar Stepper Motor
Maher Dababneh, Walid Emar, Issam TTrad
Pages - 61 - 73     |    Revised - 15-05-2013     |    Published - 30-06-2013
Volume - 7   Issue - 2    |    Publication Date - June 2013  Table of Contents
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KEYWORDS
Stepper Motor, Unipolar Permanent Magnet, Time Constant, Chopper Converter, Chopper Control.
ABSTRACT
Low power stepper motors, such as those used in floppy disk drives, are usually powered at low dc voltages, and the value of the motor windings current is usually restricted by the internal resistance of the winding. Very low resistance windings are usually used for building high torque motors; when powered by any suitable supply voltage, these motors typically require external current limiting circuitry.
The requirements for stepper motor drive circuits have changed at a very rapid rate and hence digital integrated circuits have been developed to avoid any complexity and provide facilities to be used in association with microcontrollers. The reduction of discrete circuit components has enhanced the reliability and permitted the use of more sophisticated drive techniques at a reasonable cost [1].
The rotor of a stepper motor usually aligns itself with the stator magnetic field generated by a dc current applied to the stator coils. When the rotor is driven by an external force, a restoring torque is developed. The torque becomes maximum when the rotor is turned by one step angle on either direction. This maximum torque is called the holding torque and has the unit of ounce-inches (oz-inches). It may be good to say that the running torque or the pull-out torque should be less than the holding torque; otherwise the rotor will not turn. The pull-out torque is the true indication of the torque output capability of the motor. This torque varies with the stepping rate or rotor speed [1-2].
Thus the running torque of stepper motor may be considered as the peak load torque that can be subjected to the motor without affecting the rotor equilibrium position while the appropriate stator windings are energized.
The dynamic characteristics and efficiency of the stepper motor drive may be improved if a steady dc current switched mode power supply is used. This paper discusses two types of power electronic circuits for limiting the current through the windings of the stepper motor. These two current limiters are suitable for many other industrial applications, including limiting the current rise and decrease through the dc motor windings and other highly inductive loads. This paper also covers the basic principles of stepper motors and stepper motor control systems. It focuses on a Bipolar permanent magnet, from the elementary circuitry needed to control its speed, to the methods used for improving its time constant and stepper rate [1-5].
CITED BY (4)  
1 Virgala, I., Kelemen, M., Gmiterko, A., & Lipták, T. (2015). Control of Stepper Motor by Microcontroller. Journal of Automation and Control, 3(3), 131-134.
2 Omer, S. E., & Alzubaidi, A. J. Programmed Oxygen Delivery System.
3 Virgala, I., Kelemen, M., Lipták, T., & Prada, E. (2015). Stepper Motor Control by ATMEL AVR Microcontroller. Applied Mechanics & Materials, 816.
4 Sarhan, H. (2014). PLC-controlled stepper motor drive for NC positioning system. International Journal of Engineering & Technology, 3(3), 298-307.
B. K. Bose, “Neural network applications in power electronics and motor drives—An introduction and perspective,” IEEE Trans. Ind. Electron., vol. 54, no. 1, pp. 14–33, Feb.2007.
D. Austin: “Generate stepper-motor speed profiles in real time“. Article in Embedded Systems Programming, January 2005.http://www.embedded.com//showArticle.jhtml?articleID=56800129
D. Carrica, M. A. Funes and S. A. Gonzalea: “Novel Stepper Motor Controller Based on FPGA Hardware Implementation”. IEEE/ASME Trans. Mechatronics, vol. 8, No. 1,pp.120-124, March 2003.
D. W. Jones: “ Control of Stepper Motors“. Sections 5.2.10, 10.8, 10.9 and 10.10 of the Handbook of Small Electric Motors edited by W. H. Yeadon and A. W. Yeadon,McGraw-Hill, 2001. http:// www.cs.uiowa.edu/~jones/step
D. W. Jones: “Control of stepping motors”, University of Jowa, Dept. of Computer Science, http://www.cs.uiowa.edu/~jones/step/.
E. Karakas, S. Vardarbasi,” Speed control of SR motor by self-tuning fuzzy PI controller with artificial neural network” in S¯ adhan¯ a Academy Proceedings in Engineering Sciences, Vol. 32, No. 5, pp. 587–596, 2007.
M. Hajatipour, M. Farrokhi, ”Adaptive intelligent speed control of switched reluctance motors with torque ripple reduction”, Energy Conversion and Management, Vol. 49, No.5, pp. 1028-1038, 2008.
Morar, A,: “Sisteme electronice de comanda si alimentare a motoarelor pas cu pas implementate pe calculatoare personale (Electronic systems for stepping motor control implemented on personal computers)”. Teza de doctorat, Universitatea Tehnica din Cluj-Napoca, 2001.
P. C. Sen: “Modern Power Electronics”. Published by S. Chand & Company LTD. New Delhi, 2004.
P. Crnosija, B. Kuzmanovic, and S. Ajdukovic, “Microcomputer implementation of optimal algorithms for closed-loop control of hybrid stepper motor drives,” IEEE Trans.Ind. Electron., vol. 47, no. 6, pp. 1319–1325, Dec. 2000.
R. Krishnan, “Switched Reluctance Motor Drives: Modeling, Simulation, Analysis,Design, and Applications”, Industrial Electronic Series, CRC Press LLC, 2001.
R.W. De Doncker, D. W. Novonty. "The Universal Field Oriented Controller," IEEE Trans. Ind. Applicat., vol. IA-30, No 1, 1994, pp. 92-100.
S.-M. Yang and E.-L. Kuo, “Damping a hybrid stepping motor with estimated position and velocity,” IEEE Trans. Power Electron., vol. 18, no. 3, pp. 880–887, May 2003.
V. I. Utkin, H. C. Chang,”Sliding Mode Control on Electro-Mechanical Systems”,Mathematical Problems in Engineering, Vol. 5, No. (4-5), pp. 451-473, 2002.
W. D. Chen, K. L. Yung, and K. W. Cheng, “A learning scheme for lowspeed precision tracking control of hybrid stepping motors,” IEEE/ASME Trans. Mechatronics, vol. 11,no. 3, pp. 362–365, Jun. 2006.
W. D. Chen, K. L. Yung, and K. W. Cheng, “Profile tracking performance of a low ripple hybrid stepping motor servo drive,” Proc. Inst. Elect.Eng.—Control Theory Appl., vol.150, no. 1, pp. 69–76, Jan. 2003.
W. D. Harries and J. H. Lang: “A simple motion estimation for variable reluctance motors, IEEE Trans. Ind. Appl., pp 237-243, March 1990.
W. Theodore: “Electrical machines, drives, and power systems”, sixth edition. Published by Pearson education international, New Jersey 07458, 2006.
Associate Professor Maher Dababneh
Isra University - Jordan
mikemaher_1@hotmail.co.uk
Dr. Walid Emar
Electrical Engineering Department Isra University 11622 Amman, Jordan - Jordan
Mr. Issam TTrad
Faculty of science and information Jadara University Irbid, Jordan - Jordan


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