Multiple current amplifier-based gate driving for parallel operation of discrete SiC MOSFETs

The shorter switching times of silicon carbide (SiC) MOSFETs enable power converters to operate at higher frequencies than with silicon IGBTs. However, because SiC MOSFET die sizes are still relatively small, several devices have to be connected in parallel to cope with the high current ratings demanded. For the total current to be evenly distributed among all the MOSFETs, the gate circuit and power layout must meet stringent symmetry requirements. However, space limitations on the circuit surface hinders the achievement of full symmetries on both the power and gate layouts because they constrain one another. This paper proposes a solution for safely paralleling discrete SiC MOSFETs while decoupling the gate and power layout designs. It requires placing one BJT-based fast current amplifier as close as possible to each MOSFET rather than using just one to feed all the MOS gates. This reduces the noise in the received gating signals and, more importantly, reduces the sensitivity of driver-gate path geometric / electric mismatches. This makes it possible to safely relax the symmetry requirements for the gating circuitry, thereby providing designers with more freedom to achieve better symmetry in the power layout.

Automated summary

This paper proposes a solution for safely paralleling discrete SiC MOSFETs while decoupling the gate and power layout designs. By placing a BJT-based fast current amplifier as close as possible to each MOSFET, the noise in the received gating signals is reduced and the sensitivity of driver-gate path geometric/electric mismatches is decreased. This allows for safely relaxing the symmetry requirements for the gating circuitry, providing more freedom for achieving better symmetry in the power layout.