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International Journal of Scientific and Engineering Research
ISSN Online 2229-5518
ISSN Print: 2229-5518 7    
Website: http://www.ijser.org
scirp IJSER >> Volume 3,Issue 7,July 2012
Pulse Width Modulation Implementation using FPGA and CPLD Ic
Full Text(PDF, )  PP.323-327  
Author(s)
Jakirhusen I. Tamboli, Prof. Satyawan R. Jagtap, Amol R. Sutar
KEYWORDS
Pulse width modulation, Field programmable gate array, CPLD, counte
ABSTRACT
Pulse width modulation (PWM) has been widely used in power converter control. Most high power level converters operate at switching frequencies in excess of 1 MHz at high power levels can be achieved using the planar transformer technology. PWM control is the most powerful technique that offers a simple method for controlling of analog systems with processors digital output. The resulting PWM frequency depends on the target FPGA or CPLD device speed and duty cycle resolution requirements. The contribution of this paper is the development of high frequency PWM generator architecture for power converter control using FPGA and CPLD ICs.
References
[1] N. Mohan, T. Undeland, W. Robbins, Power Electronics: Converters, Applications and Design, second ed., Wiley, 1995.

[2] R. Miftakhutdinov, A. Nemchinov, V. Meleshin, S. Fraidlin, Modified Asymmetrical ZVS half-bridge DC– DC converter, in: Proc. Applied Power Electronics Conference and Exposition, vol. 1, 1999, pp. 567–574.

[3] J. Cheng, A. Witulski, J. Vollin, A small-signal model utilizing amplitude modulation for the Class-D converter at fixed frequency, IEEE Transactions on Power Electronics 15 (2000) 1204–1211.

[4] K. Arshak, B. Almukhtar, The design and development of anovel flyback planar transformer for high frequency switch mode DC–DC converter applications, Microelectronics Journal 31 (2000) 929–935.

[5] P. Dananjayan, V. SriRam, C. Chellamuthu, A flyback constant frequency ZCS–ZVS quasi-resonant converter,Microelectronics Journal 29 (1998) 495–504.

[6] T. Gupta, R.R. Boudreaux, R.M. Nelms, J.Y. Hung, Implementation of a fuzzy controller for DC–DC converters using an Inexpensive 8-b microcontroller, IEEE Transactions on Industrial Electronics 44 (1997) 661–669.

[7] E. Koutroulis, K. Kalaitzakis, N.C. Voulgaris, Development of a microcontroller-based photovoltaic maximum power point tracking control system, IEEE Transactions on Power Electronics 16 (2001) 46–54.

[8] C. Hua, J. Lin, C. Shen, Implementation of a DSP controlled photovoltaic system with peak power tracking, IEEE Transactions on Industrial Electronics 45 (1998) 99– 107.

[9] A. Dancy, R. Amirtharajah, A. Chandrakasan, High efficiency multiple-output DC–DC conversion for low voltage systems, IEEE Transactions on Very Large Scale Integration (VLSI) Systems 8 (2000) 252–263.

[10] A. Peterchev, J. Xiao, S. Sanders, Architecture and IC implementation of a digital VRM controller, IEEE Transactions on Power Electronics 18 (2003) 356–364.

[11] B. Patella, A. Prodic´, A. Zirger, D. Maksimovic´, High frequency digital PWM controller IC for DC–DC converters, IEEE Transactions on Power Electronics 18 (2003) 438–446.

[12] R. Ramos, X. Roset, A. Manuel, Implementation of fuzzy logic controller for DC/DC converters using field programmable gate array, in: Proc. 17th IEEE Instrumentation and Measurement Technology Conference, vol. 1, 2000, pp. 160– 163.

[13] T. Ide, T. Yokoyama, A study of deadbeat control for three phase PWM inverter using FPGA based hardware controller, in: Proc. IEEE 35th Annual Power Electronics Specialists Conference, vol. 1, 2004, pp. 50–53.

[14] R. Ruelland, G. Gateau, T. Meynard, J. Hapiot, Design of FPGA-based emulator for series multicell converters using co-simulation tools, IEEE Transactions on Power Electronics 18 (2003) 455–463.

[15] A.M. Omar, N. Rahim, S. Mekhilef, Three-phase synchronous PWM for flyback converter with powerfactor E. Koutroulis et al. / Journal of Systems Architecture 52 (2006) 332–344 343 correction using FPGA ASIC design, IEEE Transactions on Industrial Electronics 51 (2004) 96–106.

[16] R. Ramos, D. Biel, E. Fossas, F. Guinjoan, A fixed frequency quasi-sliding control algorithm: application to power inverters design by means of FPGA implementation, IEEE Transactions on Power Electronics 18 (2003) 344–355.

[17] S. Jung, M. Chang, J. Jyang, L. Yeh, Y. Tzou, Design and implementation of an FPGA-based control IC for Ac voltage regulation, IEEE Transactions on Power Electronics 14 (1999) 522–532.

[18] A. Arbit, D. Pritzker, A. Kuperman, R. Rabinovici, A DSP controlled PWM generator using field programmable gate array, in: Proc. 23rd IEEE Convention of Electrical and Electronic Engineers, vol. 1, 2004, pp. 325–328.

[19] M.M. Islam, D. Allee, S. Konasani, A. Rodriguez, A lowcost digital controller for a switching DC converter with improved voltage regulation, IEEE Power Electronics Letters 2 (2004) 121–124.

[20] O. Cadenas, G. Megson, A clocking technique for FPGA pipelined designs, Journal of Systems Architecture 50 (2004) 687–696.

[21] Brian von Herzen, Signal processing at 250 MHz using high performance FPGA_s, IEEE Transactions on VLSI Systems 6 (1998) 238–246

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