Abstract
Matrix converters convert a three-phase alternating-current power supply to a power supply of a different peak voltage and frequency, and are an emerging technology in a wide variety of applications. However, they are susceptible to an instability, whose behaviour is examined herein. The desired “steady-state” mode of operation of the matrix converter becomes unstable in a Hopf bifurcation as the output/input voltage transfer ratio, q, is increased through some threshold value, qc. Through weakly nonlinear analysis and direct numerical simulation of an averaged model, we show that this bifurcation is subcritical for typical parameter values, leading to hysteresis in the transition to the oscillatory state: there may thus be undesirable large-amplitude oscillations in the output voltages even when q is below the linear stability threshold value qc.
Highlights
The matrix converter is an important emerging technology for the conversion of one alternating-current (AC) power supply into another AC power supply, with different voltage and frequency [1]
The matrix converter works by connecting each output line to the various input lines in succession, according to some switching protocol, at high frequency, in an attempt to synthesise the desired outputs
T is a delay time constant, typically the period of the high-frequency switching in the matrix converter; for example, T = 80μs when the switching takes place at 12.5kHz
Summary
The matrix converter is an important emerging technology for the conversion of one alternating-current (AC) power supply into another AC power supply, with different voltage and frequency [1]. The matrix converter can become unstable; as a consequence the intended “steadystate” output is spoilt by large-amplitude, high-frequency ripple. This new “oscillatory state” is highly undesirable in applications; its origin and nonlinear development are analysed in this paper. The latter are calculated both by a weakly nonlinear analysis close to the onset of the oscillatory solutions, and by directly solving the governing nonlinear equations numerically.
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