Nonlinear property of Active rectifier is caused by the use of the semiconductor switches, resulting in high harmonic distortion and high ripple output voltage on the DC side. This research develops a nonlinear controller to improve performance of the dc output voltage and line current based on feedback linearization. This controller mathematically transform nonlinear system dynamics into fully linear ones, so that linear control techniques can be applied.  It is designed with selecting energy function on DC side and quadrature-axis current on AC side as output variables, in order to avoid the internal dynamics, so that the system becomes stable and robust. The system applies switch function of time as the input of control strategy, instead of current and voltage in d-q frame. The proposal is validated through different tests. These tests include difference performance with conventional controller (PI optimized). The simulation results in that the output voltage performing without any overshoot, while the ripple and settling time is 0.006 sec, which is better result compared to PI optimized
Copyright © 2013 Praise Worthy Prize - All rights reserved.

Hong-Seok Song, In-Won Joo, and Kwanghee Nam, “Source Voltage Sensorless Estimation Scheme for PWM Rectifiers Under Unbalanced Conditions”, IEEE Transactions On Industrial Electronics, Vol. 50, No. 6, December 2003.

Ashari, M., W.W.L. Keerthipala and C.V. Nayar, “A Single Phase Parallely Connected Uninterruptible Power Supply/ Demand Side Management System”, IEEE Transactions on Energy Conversion, vol. 15, No. 1, March 2000, pp.97-102.

S. R. Hadian-Amrei and H. Iranmanesh ,“Novel Direct Power Control for Compensating Voltage Unbalance and Load Fluctuations in PWM Rectifiers”, ACSE Journal, Volume (6), Issue (4), Dec., 2006.

P. Antoniewicz¤ And M.P. Ka´Zmierkowski, “Predictive direct power control of three-phase boost Rectifier”, Bulletin Of The Polish Academy Of Sciences Technical Sciences Vol. 54, No. 3, 2006

Mariusz Malinowski and Marian P. Kazmierkowski, “Control of Three-Phase PWM Rectifier – A Comparative Review”, IEEE Industrial Electronics Society Newsletter Issn 0746-1240 Vol. 51, No. 1 2004

Masoud Hajihashemi, Ali Nazeran Motlagh, “Improved 3-phase PWM Boost Rectifiers in Unbalanced Network by Fuzzy Controller”, The International Conference on Electrical Engineering 2009.

C. Cecati, A. Dell’Aquila, A. Lecci, and M. Liserre, “Implementation issues of a fuzzy-logic-based three-phase active rectifier employing only voltage sensors,” IEEE Transactions on Industrial Electronics, vol. 52, pp. 378–385, April 2005

Wenxin Liu, Li Liu, David A. Cartes, Xin Wang, “Neural Network Based Controller Design for Three-Phase PWM AC/DC Voltage Source Converters” _2008 IEEE

R. S. Pena, R. J. Cardenas, J. C. Clare, and G. M. Asher, “Control strategies for voltage control of a boost type PWM converter,” IEEE 32nd Power Elec. Spec. Conf, PESC’01, vol. 2, pp. 730–735, June 2001.

Blasco and V. Kaura, “A new mathematical model and control of a three-phase AC-DC voltage source converter,” IEEE Transactions on Power Electronics, vol. 12, pp. 116–123, January 1997.

A. Hadri Hamida, A. Allag, M.Y. Hammoudi dll, “A Nonlinear Adaptive Backstepping Approach Applied to A Three phase PWM AC – DC Converter Feeding Induction Heating”, Elsevier : Communications in Nonlinear Science and Numerical Simulation, April 2009

M.-T. Tsai and W. I. Tsai, “Analysis and design of three-phase AC-to- DC converters with high power factor and near-optimum feedforward,” IEEE Trans. on Ind. Electr., vol. 46, pp. 535–543, June 1999

B. Yin, R. Oruganti, S. K. Panda, and A. K. S. Bhat, “Control of a threephase PWM rectifier based on a dual single-input single-output linear model,” Inter. Conf. on Power Electr. and Drives Systems, PEDS’05, vol. 1, pp. 456–461, January 2006.

Loubna Yacoubi∗, Farhat Fnaiech1, Louis-A. Dessaint, Kamal Al-Haddad, “New nonlinear control of three-phase NPC boost rectifier operating under severe disturbances”, Elsevier : Mathematics and Computers in Simulation 63 (2003).

Tzann-Shin Lee, Nat. Lien-Ho, “Input-output linearization and zero-dynamics control of three-phase AC/DC voltage-source converters”, Power Electronics, IEEE Transaction on Jan 2003.

Dong-Choon Lee, G-Myoung Lee, and Ki-Do Lee, “DC-Bus Voltage Control of Three-Phase AC/DCPWM Converters Using Feedback Linearization”, IEEE Transactions On Industry Applications, Vol. 36, No. 3, May/June 2000.

Bin Lu and Boon-Teck Ooi, Nonlinear Control of Voltage-Source Converter Systems”, IEEE Transactions ON Power Electronics, Vol. 22, No. 4, July 2007

Gensior A., Rudolph J., Guldner H.: ‘Flatness based control of three-phase boost rectifiers’. European Conf. on Power Electronics and Applications EPE’05, September 2005.

Charfeddine, M., Jouili, K., Jerbi, H., Braiek, N.B., Linearizing control with a robust relative degree based on a lyapunov function: Case of the ball and beam system, (2010) International Review on Modelling and Simulations (IREMOS), 3 (2), pp. 219-226.

R. Wu, S. B. Dewan, and G. R. Slemon, “A PWM ac to dc converter with fixed switching frequency,” in Conf. Rec. 1988 IEEE-IAS Ann.Meeting, pp. 706–711.

R. Wu, S. B. Dewan, and G. R. Slemon, “Analysis of an ac-to-dc voltage source converter using PWM with phase and amplitude control,” IEEE Trans. Ind. Applicat., vol. 27, no. 2, pp. 355–364, Mar./Apr. 1991.

J.-J. E. Slotine and W. Li, Applied Nonlinear Control. Englewood Cliffs, NJ: (Prentice-Hall, 1991, pp. 207–271).

Isastia, V., Meo, S., A new ZVS-CV bridgeless PFC dual boost converter for pure electric vehicle battery charger, (2011) International Review of Electrical Engineering (IREE), 6 (3), pp. 1060-1069.