Fuzzy Logic Controller for Variable Boost Function in Quasi Z Source Indirect Matrix Converter during Voltage Sag Condition

This paper presents a fuzzy logic controller to vary the voltage transfer ratio of Quasi Z Source Indirect Matrix Converter (QZSIMC) for application in induction motor drive during unbalanced input voltage and variable drive speed. A fuzzy logic controller achieves the variation of the voltage trans...

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Bibliographic Details
Published in:International journal of fuzzy systems 2017-08, Vol.19 (4), p.1093-1103
Main Authors: Sri Vidhya, D., Venkatesan, T., Kanagaraj, N.
Format: Article
Language:English
Subjects:
Artificial Intelligence
Computational Intelligence
Controllers
Conversion
Engineering
Fuzzy control
Fuzzy logic
Induction motors
Management Science
Matrix converters
Operations Research
Voltage sags
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Summary:This paper presents a fuzzy logic controller to vary the voltage transfer ratio of Quasi Z Source Indirect Matrix Converter (QZSIMC) for application in induction motor drive during unbalanced input voltage and variable drive speed. A fuzzy logic controller achieves the variation of the voltage transfer ratio from 0.866 to 5 by modifying the shoot through duty ratio of the quasi z source network. Modification in the shoot through duty ratio of the rectifier results in the improvement of the voltage boost factor of the quasi network which in turn varies the voltage transfer ratio. The fuzzy controller varies the shoot through duty ratio with input voltage error and set speed error. The proposed fuzzy-based QZSIMC can attain variable boost as well as buck function with variable shoot through duty ratio. Thus, this proposed method overcomes the limitation of constant boost. The proposed fuzzy-based QZSIMC widens the operating range of the induction motor during all the input voltage sag conditions and reduces the stress on the switches. The simulation results validate the quality performance of the proposed induction motor drive.
ISSN:1562-2479
2199-3211
DOI:10.1007/s40815-016-0221-x