一种基于米勒钳位的SiC MOSFET桥臂串扰抑制驱动电路

doi:10.19595/j.cnki.1000-6753.tces.250889

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摘要 SiC MOSFET因具有开关速度快、耐压高、热导率高等优点而得到广泛应用。然而,其高速切换特性也给驱动带来了串扰问题,严重影响了系统的可靠性。因此,该文提出一种基于米勒钳位的SiC MOSFET驱动电路,可有效抑制桥臂串扰电压。首先,分析桥臂串扰的形成原因,从寄生参数和工作模式两个方面,揭示了桥臂串扰的影响因素;其次,提出一种基于米勒钳位的新型桥臂串扰抑制驱动电路,并分析其工作原理;在此基础上,提出驱动电路的参数设计准则;最后,对所提驱动电路进行实验验证,实验结果证明了所提驱动电路对串扰抑制的有效性。

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关键词 ： SiC MOSFET, 米勒钳位, 驱动电路, 桥臂串扰

Abstract：SiC MOSFETs are widely used due to their advantages of fast switching speed, high voltage tolerance, and high thermal conductivity. However, the high-speed switching characteristics also introduce crosstalk into the drive circuit, seriously affecting the system's reliability. To mitigate the bridge-arm crosstalk, the existing methods can be categorized into three types. The first increases the gate-source impedance, which is simple but increases the power losses or slows the switching speed. The second employs a negative turn-off voltage to mitigate forward crosstalk, but, in turn, aggravates reverse crosstalk and may damage the power switch. The third applies Miller clamping, which provides a low-impedance path for Miller current during switching transients. Excellent crosstalk suppression can be achieved, yet most implementations remain complex. This paper proposes a novel SiC MOSFET bridge-arm crosstalk suppression drive circuit that combines Miller clamping with negative turn-off voltage.
Firstly, the causes of the bridge-arm crosstalk are analyzed. During the switching transients of the power switch, a displacement current is generated in the drive circuit of the complementary power switch in the same bridge arm, thus inducing the gate-source crosstalk voltage. This voltage may trigger false turn-on or reverse breakdown of the power switch. The influencing factors of crosstalk are then analyzed from the aspects of parasitic parameters and operating modes. Regarding parasitic parameters, the gate and drain inductances impact crosstalk voltage, whereas the source inductance has opposing effects on forward and reverse crosstalk. The gate resistor demands a compromise between the drive oscillations and crosstalk voltage. In terms of operating modes, crosstalk between soft-switching and hard-switching modes is compared. When the power switch operates in soft-switching mode, the forward crosstalk of the complementary power switch is significantly reduced. In contrast, the reverse crosstalk slightly increases and remains safely bounded.
Secondly, a novel bridge-arm crosstalk suppression drive circuit is proposed. The topology and operating principles of the proposed drive circuit are provided. To suppress forward crosstalk, a low-impedance path with an auxiliary switch connected across the gate-to-source of the power switch is introduced to shunt the crosstalk current and bias the gate to a negative voltage via a capacitor in parallel with a Zener diode. To suppress reverse crosstalk, the auxiliary switch's body diode diverts the crosstalk current. As a result, both forward and reverse crosstalk are mitigated effectively. Then, a step-by-step parameter design guideline for the proposed drive circuit is provided, along with an example covering passive-component sizing and active-device selection.
Finally, the proposed drive circuit is validated through simulations and experiments. Gate-voltage waveforms with and without the suppression circuit are analyzed under both soft-switching and hard-switching modes. Soft-switching reduces forward crosstalk, and the proposed drive circuit further lowers the crosstalk voltage in both modes. Experimental results verify the effectiveness of the proposed drive circuit. A comparison with other drive circuits shows that the proposed driver circuit employs only one low-impedance path to suppress both forward and reverse crosstalk, reducing the number of active devices and the drive circuit's complexity.

Key words： SiC MOSFET Miller clamping drive circuit bridge-arm crosstalk

收稿日期: 2025-05-26

PACS:

TM461

基金资助:国家自然科学基金（52407209）和江苏省科技计划专项资金（BE2022048-4）资助项目

通讯作者: 刘飞女,1992年生,讲师,硕士生导师,研究方向为宽禁带半导体器件的应用、软开关电力电子变换技术与电力电子系统集成。

作者简介: 杨旭男,2001年生,硕士研究生,研究方向为宽禁带半导体器件的应用。E-mail: yx-8468@nuaa.edu.cn

引用本文:

刘飞, 杨旭, 阮新波. 一种基于米勒钳位的SiC MOSFET桥臂串扰抑制驱动电路[J]. 电工技术学报, 2026, 41(10): 3437-3447. Liu Fei, Yang Xu, Ruan Xinbo. A Miller Clamping-Based Drive Circuit for Bridge-Arm Crosstalk Suppression in SiC MOSFETs. Transactions of China Electrotechnical Society, 2026, 41(10): 3437-3447.

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