Efficient, physics-based via modeling: Return path, impedance, and stub effect control

Andreas Hardock; Renato Rimolo-Donadio; Sebastian Müller; Young H. Kwark; Christian Schuster

doi:10.1109/memc.2014.6798802

Efficient, physics-based via modeling: Return path, impedance, and stub effect control

Andreas Hardock
, Renato Rimolo-Donadio
, Sebastian Müller
, Young H. Kwark
, Christian Schuster

Escuela de Ingeniería Electrónica

Hamburg University of Technology
IBM

Producción científica: Contribución a una publicación especializada › Artículo

37 Citas (Scopus)

Resumen

In this third paper of the series physics-based models are used to develop insight into practical aspects of the electrical performance of via interconnects in the frequency range up to 20 GHz. It will be shown that with careful design of the via environment, the current return path can be controlled, which makes it possible to describe vias in terms of transmission line parameters in certain frequency ranges. This implies that via impedance can be controlled to match a specific target in order to minimize reflections. Furthermore, the via stub effect and alternatives to mitigate it by shifting unwanted resonances beyond the range of interest are addressed. Finally, both via impedance matching and stub length reduction methods were applied to a generic link configuration in order to assess the impact on signal integrity.

Idioma original	Inglés
Páginas	76-84
Número de páginas	9
Volumen	3
N.º	1
Publicación especializada	IEEE Electromagnetic Compatibility Magazine
DOI	https://doi.org/10.1109/memc.2014.6798802
Estado	Publicada - 1 mar 2014

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abstract = "In this third paper of the series physics-based models are used to develop insight into practical aspects of the electrical performance of via interconnects in the frequency range up to 20 GHz. It will be shown that with careful design of the via environment, the current return path can be controlled, which makes it possible to describe vias in terms of transmission line parameters in certain frequency ranges. This implies that via impedance can be controlled to match a specific target in order to minimize reflections. Furthermore, the via stub effect and alternatives to mitigate it by shifting unwanted resonances beyond the range of interest are addressed. Finally, both via impedance matching and stub length reduction methods were applied to a generic link configuration in order to assess the impact on signal integrity.",

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Efficient, physics-based via modeling: Return path, impedance, and stub effect control

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