Accurate electrical simulation and design optimization for silicon interposer considering the MOS effect and eddy currents in the silicon substrate

Jing Zhou, L. Wan, Fengwei Dai, Huijuan Wang, Chongshen Song, Tianmin Du, Yanbiao Chu, M. Pan, D. Guidotti, Liqiang Cao, Daquan Yu
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引用次数: 8

Abstract

In this paper, a group of coplanar lines on a silicon dioxide insulating layer on a nominally doped silicon substrate is simulated and measured. Electrical parameters extracted from published data are used and lead to substantially improved agreement with measurements. In addition, several models of redistribution layer (RDL) with different shape-TSVs (through silicon vias) are simulated, along with two different joint structures between TSV and RDL. Simulation result suggest that because the electrical length is very short reflection losses attributed to the structural details of the TSV may be ignored in the applicable frequency band of the TSV. In addition, several optimized transmission line structures are designed and simulated. Results suggest that design criteria used to optimize lines in organic substrates are not directly transferable to a silicon substrate. This paper shows a simple but effective method with which to analyze the influences exerted by the metal oxide semiconductor (MOS) capacitance at the TSV interface and eddy currents in the substrate on a transmission line. Finally, newly de-embedded test structures are provided to extract spice model parameters for TSV modeling.
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考虑MOS效应和硅衬底涡流的硅中间体的精确电学仿真与设计优化
本文对名义掺杂硅衬底上二氧化硅绝缘层上的一组共面线进行了模拟和测量。从公布的数据中提取的电气参数被使用,并导致与测量结果的一致性大大提高。此外,还模拟了具有不同形状的TSV(通过硅孔)的重分配层(RDL)模型,以及TSV和RDL之间的两种不同连接结构。仿真结果表明,由于电长度很短,在TSV的适用频段内,由TSV结构细节引起的反射损耗可以忽略不计。此外,还对几种优化的输电线路结构进行了设计和仿真。结果表明,用于优化有机衬底线的设计标准不能直接转移到硅衬底。本文给出了一种简单而有效的方法来分析TSV接口处的金属氧化物半导体(MOS)电容和传输线衬底涡流的影响。最后,提供了新的去嵌入测试结构,用于提取TSV建模所需的spice模型参数。
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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