宽温域下的SiC MOSFET开关暂态建模方法研究

doi:10.19595/j.cnki.1000-6753.tces.241603

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摘要由于碳化硅金属氧化物半导体场效应晶体管（SiC MOSFET）具有优异的电热性能, 已在电力、交通、航空航天等诸多领域得到广泛应用。准确、易用的SiC MOSFET仿真模型对SiC MOSFET电力电子装置的设计与优化, 保障系统安全稳定运行起着十分关键的作用。然而, 现有的SiC MOSFET开关暂态模型大多忽略了温度对开关特性的影响, 使得宽温域工况下器件的电流与电压开关波形与真实的实验波形存在较大差异, 模型误差显著增大。为了准确地反映SiC MOSFET在不同温度下的电气特性, 该文建立了一种宽温域下的SiC MOSFET开关暂态模型。通过分析SiC MOSFET阈值电压和跨导随温度变化的规律, 采用函数拟合的方式对阈值电压和转移特性曲线进行数学建模。并依据SiC MOSFET等效电路和开关暂态过程的物理机理, 将开关过程划分为八个阶段进行分段建模。在不同温度下, 通过Matlab仿真和双脉冲实验平台的测试对所建模型的准确性进行系统性对比验证, 测得的模型开关时间平均误差小于10%, 开关损耗误差约为12%, 均低于常规建模方法。

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	姜杰俊
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	辛振

关键词 ： SiC MOSFET, 开关暂态模型, 温度, 等效电路

Abstract：An accurate model for SiC MOSFET devices is crucial for precise circuit design and analysis. Many existing SiC MOSFET models neglect temperature effects, leadingto substantial discrepancies in voltage and current measurements across different temperatures. Although some manufacturers offer proprietary models, these are often oversimplified and may exhibit significant deviations from actual SiC MOSFET performance. To address this, this paper develops a comprehensive SiC MOSFET switching transient model covering a wide temperature range, which accurately describes the transient process of SiC MOSFET switching at different temperatures. Additionally, for some complex processes, mathematical fitting of waveforms is employed to simplify the modeling process.
During the switching process of SiC MOSFETs, internal device parameters fluctuate with temperature, directly impacting transient behavior. Accurately characterizing these parameters at various temperatures is crucial for effective device modeling. The parasitic capacitance of SiC MOSFETs is analyzed in this paper, and a target function for parasitic capacitance is derived using mathematical techniques. To mitigate significant deviations in transfer characteristics at different temperatures, the traditional transfer characteristics curve fitting function is enhanced by incorporating a temperature variable through polynomial fitting. The transconductance is the slope of the tangent line of the transfer characteristic curve. In this article, the transconductance is calculated based on the transfer characteristic curve, which also obtains the relationship between transconductance and temperature. Meanwhile, the threshold voltage of SiC MOSFET is affected by temperature, and the relationship between threshold voltage and temperature also affects the transient process of the switch. This article uses linear fitting to represent the expression between temperature and threshold voltage based on the information provided in the data sheet.
These model parameters are incorporated into the SiC MOSFET switching transient model, integrating temperature effects into the SiC model. The switching process is divided into multiple stages for piecewise modeling, based on the equivalent circuit and physical mechanisms of the transient process. Analysis focuses on drain-source voltage, drain-source current, and switching time, with corresponding expressions established. Behavioral modeling is used for complex stages of switch transients, simplifying the process of switch transient modeling. At the same time, the model parameters are related to the real circuit, ensuring accuracy. This method can balance computational efficiency and accuracy. Build a dual pulse testing platform to conduct dual pulse experiments on Infineon's silicon carbide device IMZA120R040M1H at different temperatures (25℃ to 125℃). The comparison between model predictions and experimental results shows good consistency, verifying the accuracy of the model.
In summary, the following conclusions are drawn: (1) The enhanced transfer characteristics fitting method, incorporating temperature effects, achieves a fitting goodness of 0.99, improving curve accuracy. (2) The proposed SiC MOSFET switching transient model exhibits an average error of less than 10% in switching time and approximately 12% in switching loss compared to experimental data. (3) The improved model, accounting for temperature effects, enhances both the accuracy and applicability of the SiC MOSFET model.

Key words： SiC MOSFET switching transient model temperature equivalent circuit

收稿日期: 2019-12-08

PACS:

TN386

基金资助:国家自然科学基金青年基金项目（52407201）、河北省高等学校科学研究项目（QN2023105）和河北省留学人员项目（C20220318）资助

通讯作者: 韩伟健男, 1989年生, 讲师, 研究方向为高频电力电子变换器建模与控制。E-mail: weijian.han@hebut.edu.cn

作者简介: 姜杰俊男, 1999年生, 硕士研究生, 研究方向为功率变换器实时仿真建模。E-mail: 202221401116@stu.hebut.edu.cn

引用本文:

姜杰俊, 刘青, 韩伟健, 辛振. 宽温域下的SiC MOSFET开关暂态建模方法研究[J]. 电工技术学报, 2025, 40(20): 6591-6603. Jiang Jiejun, Liu Qing, Han Weijian, Xin Zhen. Research on Switching Transient Modeling Method of SiC MOSFET in Wide Temperature Range. Transactions of China Electrotechnical Society, 2025, 40(20): 6591-6603.

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