SiC Power Module Loss Reduction by PWM Gate Drive Patterns and Impedance-Optimized Gate Drive Voltages

Gerstner H, Heckel T, Endruschat A, Rosskopf A, Eckardt B, März M (2017)


Publication Language: English

Publication Type: Conference contribution, Conference Contribution

Publication year: 2017

Event location: Albuquerque, NM US

DOI: 10.1109/WiPDA.2017.8170564

Abstract

This paper presents a novel procedure to determine the internal gate-source voltage inside a multi-chip power module using the example of a SiC half bridge module. Based on the lumped elements of the gate circuit calculated by a quasi-static electromagnetic simulation, each field-effect transistor is represented by a single, voltage dependent capacitor. The procedure is validated by clamped inductive switching measurements of a SiC power module. Moreover, it is applied to determine the maximum permissible gate-source voltage range in compliance with the manufacturer’s voltage rating for a given driver-module combination. In this context a significant extension of the gate drive voltage range and thus an increase of efficiency using impedance specific PWM patterns is demonstrated.

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How to cite

APA:

Gerstner, H., Heckel, T., Endruschat, A., Rosskopf, A., Eckardt, B., & März, M. (2017). SiC Power Module Loss Reduction by PWM Gate Drive Patterns and Impedance-Optimized Gate Drive Voltages. In Proceedings of the 2017 WiPDA. Albuquerque, NM, US.

MLA:

Gerstner, Holger, et al. "SiC Power Module Loss Reduction by PWM Gate Drive Patterns and Impedance-Optimized Gate Drive Voltages." Proceedings of the 2017 WiPDA, Albuquerque, NM 2017.

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