Litcius/Paper detail

CMOS Active Gate Driver for Closed-Loop d<i>v</i>/d<i>t</i> Control of GaN Transistors

Plinio Bau, Marc Cousineau, Bernardo Cougo, Frédéric Richardeau, Nicolas Rouger

2020IEEE Transactions on Power Electronics38 citationsDOIOpen Access PDF

Abstract

This article shows both theoretical and experimental analyses of a fully integrated CMOS active gate driver (AGD) developed to control the high dv/dt of GaN transistors for both 48 and 400 V applications. To mitigate negative effects in the high-frequency spectrum emission, an original technique is proposed to reduce the dv/dt with lower switching losses compared to classical solutions. The AGD technique is based on a subnanosecond delay feedback loop, which reduces the gate current only during the dv/dt sequence of the switching transients. Hence, the dv/dt and di/dt can be actively controlled separately, and the tradeoff between the dv/dt and EON switching energy is optimized. Since GaN transistors have typical voltage switching times on the order of a few nanoseconds, introducing a feedback loop from the high voltage drain to the gate terminal is quite challenging. In this article, we successfully demonstrate the active gate driving of GaN transistors for both 48 and 400 V applications, with initial open-loop voltage switching times of 3 ns, due to a full CMOS integration. Other methods for dv/dt active control are further discussed. The limits of these methods are explained based on both experimental and simulation results. The AGD showed a clear reduction in the peak dv/dt from -175 to -120 V/ns for the 400 V application.

Topics & Concepts

CMOSTransistorVoltageGate driverMOSFETElectrical engineeringOptoelectronicsMetal gateLogic gateMaterials scienceGate oxideEngineeringSilicon Carbide Semiconductor TechnologiesSemiconductor materials and devicesGaN-based semiconductor devices and materials