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This paper describes a new approach to estimate rotor angle of two-phase induction machine from measured terminal voltages and currents using virtual high frequency injection method for sensorless vector control. The proposed scheme is independent from load variation since the rotor angle is derived by using only the injected d, q axis voltage component. The difference between the classical high frequency injection method and the novel virtual one is in injection voltage to the mathematical model of the machine not to the stator of the machine. The mathematical principle of the proposed technique and its implementation are presented. Computer simulations and experimental results are also included for verification
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Virtual High Frequency Injection Method; Sensorless Control; Two-Phase Induction Machine; Synchronous Filter; Angle Tracking Observer

Brandstetter, P., Sensorless control of induction motor using modified MRAS, (2012) International Review of Electrical Engineering, 7 (3), pp. 4404-4411.

M. Cirrincione, M. Pucci, G. Cirrincione, and G.-A. Capolino, A new adaptive integration methodology for estimating flux in induction machine drives, IEEE Transactions on Power Electronics, vol. 19, n. 1, January 2004, pp. 25–34.

M. Elbuluk, N. Langovsky, M.D. Kankam, Design and Implementation of a closed-loop observer and adaptive controller for induction motor drives, IEEE Transaction on Industry Applications,vol. 34, n. 3, May/June 1998, pp. 435-443.

A.R. Haron, N.R.N. Idris, Simulation of MRAS-based Speed Sensorless Estimation of Induction Motor Drives using Matlab/Simulink, The 1st International Power and Energy Conference ~PECON 2006~,Nov. 28-29, Putralaya, Malaysia.

M.N. Marvwali, A. Keyhani, A Comparative Study of Rotor Flux Based MRAS and Back EMF Based MRAS Speed Estimators for Speed Sensorless Vector Control of Induction Machines, The 32th Industry Application Conference ~IAS ’97~, Oct. 5-9, 1997, New Orleans, Louisiana.

Nandhini Gayathri, M., Himavathi, S., Sankaran, R., FPGA implementation of neural learning algorithm based MRAS rotor resistance estimator using reactive power for vector controlled induction motor drive, (2012) International Review of Electrical Engineering (IREE), 7 (6), pp. 6035-6044.

S. Maiti, C. Chakraborty, Y. Hori, 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. on Industrial Electronics, vol. 55 n. 2, February 2008, pp. 594-601.

K. Huang, Y. Zhang, S. Huang, L. Xiao, A MRAS Method for Sensorless Vector Control of Induction Motor Based on Instantaneous Reactive Power, International Conference on Electrical Machines and Systems ~ICEMS 2010~,Oct. 10-13, 2010, Incheon, South Korea

E.A. Vendrusculo, J. A. Pomilio, An Adaptive Speed Estimator for Single-Phase Induction Motors, International Symposium on Power Electronics, Electrical Drives, Automation and Motion, ~SPEEDAM 2008~, 2008, pp. 1248-1252

J.I. Ha; S.K. Sul., Physical Understanding of High Frequency Injection Method to Sensorless Drives of an Induction Machine, IEEE Industry Application Conference, Vol. 3, 2000, pp.:1802-1808.

J.I. Ha, S.K. Sul, Sensorless field-orientation control of and induction machine by high frequency signal injection, IEEE Trans. on Industrial Applications, vol. 55 n. 2, Jan./Feb. 1999, pp. 45-51.

C. Caruana, G.M. Asher, M. Sumner, Performance of High Frequency Signal Injection Techniques for Zero-Low-Frequency Vector Control of Induction Machines Under Sensorless Conditions, IEEE Trans. on Industrial Electronics, vol. 53 n. 1, February 2006, pp. 225-238.

M. Jemli, H.B. Azza, M. Gossa, Real-time implementation of IRFOC for single-phase induction motor drive using dSpace DS 1104 control board, Simulation Modelling Practice and Theory, vol. 17, n. 6, July 2009, pp. 1071 – 1080.

M.B.R Corrêa, C.B. Jacobina, E.R.C. Da Silva, A.M.N. Lima, IEEE Transaction on Industrial Electronics, vol. 51,n. 5, October 2004, pp. 1073 – 1080.

B. Dobrucky, P. Drgona, P. Spanik, V. Bobek, Using Power PC-MPC for Real-Time VHFIM Sensorless Drive Control, The 2nd International Multi-Conference on Complexity, Informatics and Cybernetics ~IMCIC 2011~, March 27-30, 2011, Orlando, Florida.

D. H. Jang, D.Y. Yoon., Space-Vector PWM Technique for Two-Phase Inverter-Fed Two-Phase Induction Motors, IEEE Transactions on Industry Applications, Vol. 39, No.2, March/April 2003, pp.542-549.

L.C. Tomaselli, T.B. Lazzarin, D.C. Martins, I. Barbi., Application of the Vector Modulation in the Symmetrical Two-Phase Induction Machine Drive, The 36th IEEE Power Electronics Specialists Conference ~PESC 2005~, June 12-18, 2005,.Recife, Brazil.

D. Dujic, D. Ostojic, Rotor Angular Position and Speed Estimation with use of Electromgnetic Resolvers for Motor Drives, GERI Annual Research Symposium, June 15, 2006, .Liverpool, England.

H. Kubota, K. Matsuse, Speed Sensorless Field-Oriented Control of Induction Motor with Rotor Resistance Adaptation, IEEE Transaction on Industry Applications, vol. 30, n. 5, Sept./Oct. 1994, pp. 1219-1224.

D.H. Choi, S.B. Cho, D.S. Hyun, Improved Torque response by Tuning of the Magnetizing Inductance under Field Weakening Operation Region, The 32th IAS Annual Meeting ~IAS ‘97~,Oct. 5-9, 1997, New Orleans, Louisiana.

J. Vonkomer, Self-tuned Speed Servodrive with Induction Motor, Institute of Control and Industrial Informatics, Slovak University of Technology, Slovakia, 2012. (In Slovak).

Dobrucky, B., Zaskalicky, P., Kascak, S., Prazenica, M., Comparison of modified sinusoidal and space vector modulation for symmetrical two-phase induction motor under field oriented control, (2012) International Review on Modelling and Simulations (IREMOS), 5 (6), pp. 2445-2451.