Abstract
Gallium nitride (GaN) devices are becoming more popular in power semiconductor converters. Due to the absence of the freewheeling substrate diode, the reverse conduction region is used in GaN transistors to conduct the freewheeling current. However, the voltage drop across the device in the reverse conduction mode is relatively high, causing additional power losses. These losses can be optimized by adequately adjusting the dead-time issued by the microcontroller. The dead-time loss minimization strategies presented in the literature have the common disadvantage that either additional hardware or specific converter data are needed for their proper operation. Therefore, this paper’s motivation is to present a novel dead-time loss minimization method for GaN-based high-frequency switching converters for electric drives that does not impose additional requirements on the hardware design phase and converter data acquisition. The method is based on optimizing the current controllers’ output with a simple perturb-and-observe tracker. The experimental results show that the proposed approach can minimize the dead-time losses over the whole drive’s operating range at the cost of only a moderate increase in software complexity.
Highlights
Within electrical drives, especially when powered by batteries, efficiency and power density are essential aspects
The design of small and highly efficient power converters for electric motor control demands wide bandgap semiconductors such as those based on silicon carbide (SiC) and gallium nitride (GaN)
From (3), it can be seen that the dead-time losses are even more significant in the case of robust converters that apply a negative gate voltage in the off-state to prevent a false turn-on
Summary
Especially when powered by batteries, efficiency and power density are essential aspects. The design of small and highly efficient power converters for electric motor control demands wide bandgap semiconductors such as those based on silicon carbide (SiC) and gallium nitride (GaN). These materials, with a high inner electric field, improve the transistor’s parameters, such as the current density and on-state resistance. In this thispaper, paper, online method of dead-time loss minimization for a vector-controlled. In an an online method of dead-time loss minimization for a vector-controlled permanent permanent magnet synchronous motor (PMSM).
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