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The increasing slew rate of modern power switches can increase the efficiency and reduce the size of power electronic applications. This requires a fast and robust signal transmission to the gate driver of the high-side switch. This work proposes a galvanically isolated capacitive signal transmission circuit to increase common mode transient immunity (CMTI). An additional signal path is introduced to significantly improve the transmission robustness for small duty cycles to assure a safe turn-off of the power switch. To limit the input voltage range at the comparator on the secondary side during fast high-side transitions, a clamping structure is implemented. A comparison between a conventional and the proposed signal transmission is performed using transistor level simulations. A propagation delay of about 2 ns over a wide range of voltage transients of up to 300V/ns at input voltages up to 600V is achieved.
A novel gate driving approach to balance the transient current of parallel-connected GaN-HEMTs
(2018)
To enable higher current handling capability of GaN-based DC/DC converters, devices have to be used in parallel. However, their switching times differ, especially if their threshold voltages are not identical, which causes unbalanced device current. This paper focuses on the homogeneous distribution of turn-on switching losses of GaN-HEMTs connected in parallel. By applying a new gate driver concept, the transient current is distributed evenly. The effectiveness of this concept is demonstrated by double pulse measurements, for switching currents up to 45A and a voltage of 400V. A uniform current distribution is achieved, including a reduction of the turn-on losses by 50% compared to a conventional setup.