Dynamic model of a space vector modulated buck-boost matrix-reactance frequency converter

The determination of the converter passive elements for various load and power grid conditions is of great importance to the proper operation of matrix-reactance frequency converters. The modulation strategy of power switches is very important to the voltage gain and input power factor control. The Space Vector Modulation is the most commonly used algorithm for the control of three-phase power converters. This paper presents a novel dynamic model of a Matrix-Reactance Frequency Converter that utilizes a Space Vector Modulation (SVM) switching method. In this paper the average-state space method and the two-frequency d-q transformation are proposed as aids in the process of fast verification of the matrix-reactance frequency converter operation under specific dynamic conditions.

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