建立精确动态双极晶体管紧凑模型的数学基础

2019 IEEE BiCMOS and Compound semiconductor Integrated Circuits and Technology Symposium (BCICTS) Pub Date : 2019-11-01 DOI:10.1109/BCICTS45179.2019.8972737

M. Schröter, M. Krattenmacher

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引用次数: 0

摘要

对于现在和未来的毫米波和亚毫米波应用，紧凑的模型需要捕捉到高达几个谐波的大信号动态晶体管行为，这通常远远超过晶体管的截止频率。由于这些频率超出了现有的或通常负担得起的测量能力，因此需要一种物理和数学上合理的方法来开发紧凑的模型，以保证所需的精度水平。本文基于DD输运和连续性方程的封闭解，论证了本征晶体管工作的物理等效电路的构造。通过器件仿真验证了方案的正确性。

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Mathematical foundation for constructing accurate dynamic bipolar transistor compact models

For present and future mm- and sub-mm-wave applications, compact models need to capture the large-signal dynamic transistor behavior up to several harmonics, which are often far beyond the transistor cut-off frequencies. Since such such frequencies exceed the existing or usually affordable measurement capability, a physically and mathematically sound approach for developing compact models is required that guarantees a desired level of accuracy. This paper demonstrates the construction of physics-based equivalent circuits for the intrinsic transistor operation based on a closed-form solution of the DD transport and continuity equation. The solutions are verified based on device simulation.

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2019 IEEE BiCMOS and Compound semiconductor Integrated Circuits and Technology Symposium (BCICTS)

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