Authors: K.Sedhuraman, S.Himavathi, A.Muthuramalingam

Abstract:

The performance of sensor-less controlled induction motor drive depends on the accuracy of the estimated speed. Conventional estimation techniques being mathematically complex require more execution time resulting in poor dynamic response. The nonlinear mapping capability and powerful learning algorithms of neural network provides a promising alternative for on-line speed estimation. The on-line speed estimator requires the NN model to be accurate, simpler in design, structurally compact and computationally less complex to ensure faster execution and effective control in real time implementation. This in turn to a large extent depends on the type of Neural Architecture. This paper investigates three types of neural architectures for on-line speed estimation and their performance is compared in terms of accuracy, structural compactness, computational complexity and execution time. The suitable neural architecture for on-line speed estimation is identified and the promising results obtained are presented.

Keywords: Sensorless IM drives, rotor speed estimators, artificial neural network, feed- forward architecture, single neuron cascaded architecture.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1080044

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References:

[1] K. Hurst, T. Habetler, G. Griva, and F. Profumo, "Speed sensorless field-oriented control of induction machines using current harmonic spectral estimation," in Conference Record of Industry Applications Society Annual Meeting, vol. 1, pp. 601-607, IEEE, Oct. 1994.
[2] A. Ferrah, P. Hogben-Laing, K. Bradley, G. Asher, and M. Woolfson, "The effect of rotor design on sensorless speed estimation using rotor slot harmonics by adaptive digital filtering using the maximum likelihood approach," in Conference Proceedings of the IEEE IAS Annual Meeting, pp. 128-135, IEEE, Oct. 1997.
[3] M. Rashed and A. F. Stronach, "A stable back-EMF MRAS-based sensorless low speed induction motor drive insensitive to tator resistance variation," Proc. Inst. Elect. Eng.ÔÇöElectr. Power Appl., vol. 151, no. 6, pp. 685-693, Nov. 2004.
[4] P. L. Jansen and R. D. Lorenz, "Transducer less field orientation concepts employing saturation-induced saliencies in induction machines," IEEE Transactions on Industry Applications, vol. 32, pp. 1380-1393, Nov/Dec 1996.
[5] M. Schroedl, "Sensorless control of ac machines at low speed and standstill based on the "inform" method," in Conference Record of the31st Annual Meeting of the IAS, vol. 1, pp. 270-277, IEEE, Oct. 1996.
[6] S. Maiti, C. Chakraborty, Y. Hori, and M. C. Ta, "Model reference adaptive controller-based rotor resistance and speed estimation techniques for vector controlled induction motor drive utilizing reactive power," IEEE Trans. Ind. Electron., vol. 55, no. 2, pp. 594-601, Feb. 2008.
[7] F. Z. Peng and T. Fukao, "Robust speed identification for speed sensorless vector control of induction machines," IEEE Transactions on Industry Applications, vol. IA-30, no. 5, pp. 1234-1230, 1994.
[8] K.Narendra and K.Part-ms arathy, "Identification and control of dynamical system using neural network" IEEE Trans. Neural Networks, vol.1, no.1, pp.4-27, Mar.1990
[9] Karanayil M. Rahman M.F. and Grantham C. "Online Stator and Rotor Resistance Estimation Scheme Using Artificial Neural Networks for Vector Controlled Speed Sensorless Induction Motor Drive" IEEE Transactions on Industrial Electronics, vol. 54, no. 1, Feb 2007.
[10] S.K.Mondal, J.O.P.Pinto and B.K. Bose, "A neural network based space vector PWM controller for a three voltage fed inviter induction motor drive," IEEE Trans.Ind.Appl. vol. 30.no.3.pp 660-669 May 2002.
[11] Maurizio Cirrincione,and Marcello Pucci, "An MRAS-Based Sensorless High-Performance Induction Motor Drive With a Predictive Adaptive Model" IEEE Transactions On Industrial Electronics, vol. 52, pp. 532- 551, Apr 2005.
[12] P.Vas, "Sensorless and Direct Torque Control", Oxford University Press, 1998.
[13] Nicholas K.Treadgold and Tramas D. Gedeon, "Exploring Constructive Cascade Networks", IEEE Transactions on Neural Networks, vol. 10, pp.1335-1349, 1999.
[14] K.S.Narendra and K.Parthasarathy, "Gradient Methods for the Optimization of Dynamical Systems Containing Neural Networks", IEEE Transactions on Neural Networks, Vol 2, No.2, pp.252-262, March 1991.
[15] Martin T. Hagan and Mohammad B. Menhaj, "Training Feedforward Networks with the Marquardt Algorithm", IEEE Transactions on Neural Networks, Vol 5,No.6, pp.989-993, November 1994.
[16] Martin T.Hagan, Howard B. Demuth and Mark Beale, "Neural Network Design", Cengage Learning, Pvt.Ltd., India 2008.
[17] Steven W. Smith, "Digital Signal Processing: a Practical Guide for Engineers and Scientists", Cengage Learning, Pvt.Ltd., India 2008.