Promising Algorithm Addressing Characteristic Curves of Insulated Gated Bipolar Transistor (IGBT) Fitted by Applying Bipolar Transistor Driven by Insulated Gate Bias

2021 7th International Conference on Applied System Innovation (ICASI) Pub Date : 2021-09-24 DOI:10.1109/ICASI52993.2021.9568443

Hsin-Chia Yang, Sung-Ching Chi, Peifeng Yang, Chia-Chun Lin, Kuan-Hung Chen, You-Sheng Lin

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Abstract

Power devices have been overwhelmingly popular for the last decades. Insulated Gate Bipolar Transistor (IGBT) is quite dominant for the capability of providing relatively high current at pretty high sustaining breakdown voltages. The underlying bipolar junction transistors (including NPN and PNP) get activated as the bias is applied to the isolated gate which is equivalent to a MOSFET transistor with high input impedance. Flowing current ignites wherever potential bipolar junction transistors locate. The current of the whole IGBT is lead by the VEC voltage while, for VMOS (vertical MOS) type, the current flows from the bottom (Emitter) straight up to the top (Collector) through N-type drift region. With the careful design of the concentration in N-type drift region, a multi-merit transistor of high power is thus available. The measured characteristic curves of current (IEC) versus voltage (VEC) are thus fitted and modeled.

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利用绝缘栅极偏置驱动的双极晶体管拟合的绝缘门控双极晶体管(IGBT)特性曲线的求解算法

在过去的几十年里，动力装置一直非常受欢迎。绝缘栅双极晶体管(IGBT)在相当高的持续击穿电压下提供相对高电流的能力相当占主导地位。底层的双极结晶体管(包括NPN和PNP)被激活，因为偏置被应用于隔离栅极，相当于一个具有高输入阻抗的MOSFET晶体管。流动电流点燃任何潜在的双极结晶体管的位置。整个IGBT的电流由VEC电压引导，而对于VMOS(垂直MOS)型，电流通过n型漂移区从底部(发射极)直接流向顶部(集电极)。通过对n型漂移区集中的精心设计，可以获得高功率的多优点晶体管。由此拟合并建立了所测电流(IEC)对电压(VEC)特性曲线。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 7th International Conference on Applied System Innovation (ICASI)

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