Study of Turns Impact on ESD-immunity of High-voltage nLDMOSs with a Constant Floating-poly

2022 IEEE 4th Eurasia Conference on IOT, Communication and Engineering (ECICE) Pub Date : 2022-10-28 DOI:10.1109/ECICE55674.2022.10042892

Xing-Chen Mai, Xiu-Yuan Yang, Shen-Li Chen, Ting-En Lin, Yu-Jie Chung

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Abstract

A TSMC $0.18- \mu \mathrm{m}50 -\mathrm{V}$ process is used to realize high-voltage nLDMOS devices. The floating-poly (poly-2) shows a spiral shape in the layout diagram. Commonly, the electric field in an nLDMOS decreases if the area is occupied by the poly-2 increases. However, the method used in this study is to increase or decrease the number of turns with the same occupied area of poly-2. Therefore, we studied whether the electric field rises or falls depending on the number of turns or the area occupied without changing the area occupied by poly-2. The reference device had the poly-2 with seven turns, and the other groups had 9 turns or 3 and 5 turns. Eventually, the highest electric field of the 9-turn device was 2.76 x 108 (V/cm), and its occupied area is the most dispersed distribution. For the 3 circles device is the most concentrated, the lowest electric field is 3.39 x 106 (v/cm). If the occupied area remains unchanged, the electric field is greatly reduced with the concentrated poly-2.

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恒浮聚高压nLDMOSs匝数对抗静电性影响的研究

采用TSMC $0.18- \mu \ mathm {m}50 -\ mathm {V}$工艺实现高压nLDMOS器件。浮动多边形(poly-2)在布局图中显示为螺旋形状。通常，如果poly-2占据的面积增加，nLDMOS中的电场就会减小。然而，本研究采用的方法是增加或减少poly-2占用相同面积的匝数。因此，我们研究了在不改变poly-2占据的面积的情况下，电场的上升或下降是否取决于匝数或占据的面积。参考装置为7圈poly-2，其他组为9圈或3圈和5圈。最终，9匝器件最高电场为2.76 × 108 (V/cm)，占据面积分布最分散。3圆器件最集中，最低电场为3.39 × 106 (v/cm)。当占据面积不变时，聚-2的集中使电场大大减小。

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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2022 IEEE 4th Eurasia Conference on IOT, Communication and Engineering (ECICE)

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