智能功率集成电路中衬底少数载流子注入的电路仿真流程

2017 29th International Symposium on Power Semiconductor Devices and IC's (ISPSD) Pub Date : 2017-05-01 DOI:10.23919/ISPSD.2017.7988946

Michael Kollmitzer, M. Olbrich, E. Barke

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引用次数: 0

摘要

本文提出了一种基于spice的点对点建模方案，用于模拟基于深沟槽的BCD技术基片中少量载流子注入引起的寄生耦合效应。由于少数载流子可以在公共衬底中扩散很远的距离并干扰电路的正常工作，因此有必要在设计早期采用定量方法来解决这种寄生效应。基于芯片设计提取了等效电路，并用Verilog-AMS模型表示了扰动器件与敏感节点之间的耦合效应。自动布局提取识别扰动和敏感装置，并确定模型的参数。模型的方程是基于专用测试芯片测量的校准TCAD仿真推导出来的。最后，对整个仿真流程进行了评估，并将仿真结果与芯片的测量结果进行了比较。

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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A circuit simulation flow for substrate minority carrier injection in smart power ICs

This paper proposes a point-to-point modeling scheme for Spice-based circuit simulation of parasitic coupling effects caused by minority carrier injection into the substrate of a deep-trench based BCD technology. Since minority carriers can diffuse over large distances in the common substrate and disturb circuits in their normal operation, a quantitative approach is necessary to address this parasitic effect early during design. An equivalent circuit based on the chip's design is extracted and the coupling effect between the perturbing devices and the susceptible nodes is represented by Verilog-AMS models. An automated layout extraction identifies the perturbators and the sensitive devices and determines the parameters for the models. The equations of the models are derived from calibrated TCAD simulations based on measurements of a dedicated test chip. Finally, the entire simulation flow is evaluated and the simulation results are compared to measurements of the chip.

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2017 29th International Symposium on Power Semiconductor Devices and IC's (ISPSD)

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