Novel Formulations of Multireflections and Their Applications to High-Speed Channel Design

IEEE Transactions on Signal and Power Integrity Pub Date : 2022-03-23 DOI:10.1109/TSIPI.2022.3176592

Muqi Ouyang;Xiao-Ding Cai;Bo Pu;Qian Gao;Srinath Penugonda;Chaofeng Li;Bidyut Sen;Chulsoon Hwang;DongHyun Kim

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引用次数: 2

Abstract

Reflection theory has been long established for over decades targeted at microwave and radio frequency (RF) applications. With ultra-high-bandwidth applications emerging, such as 112 Gb/s and higher speed Ethernet protocols, discontinuities in high-speed channels negatively impact signal quality, where reflections become one of the most critical concerns in high-speed designs. In this article, for the first time, we analyzed the traditional reflection theory and proposed and verified a new formulation, which exhibits the reflection-related parameters explicitly, indicating where design optimization can be made for high-bandwidth applications using the backtracked propagation method. Our closed-form formulation is applied to high-speed channel examples, where effective mitigation of negative impact from reflections on signal integrity can be identified to be used as a prelayout channel design guide. Our proposed formulation of the reflection theory provides more accurate prediction of high-speed channel behavior to minimize the negative signal integrity impact from reflections.

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多重反射的新公式及其在高速通道设计中的应用

反射理论针对微波和射频（RF）应用已经建立了几十年。随着超高带宽应用的出现，如112 Gb/s和更高速的以太网协议，高速通道中的不连续性会对信号质量产生负面影响，反射成为高速设计中最关键的问题之一。在本文中，我们首次分析了传统的反射理论，并提出并验证了一个新的公式，该公式明确地展示了反射相关的参数，表明了使用回溯传播方法可以对高带宽应用进行设计优化的地方。我们的闭合形式公式应用于高速通道示例，其中可以确定有效缓解反射对信号完整性的负面影响，用作预布局通道设计指南。我们提出的反射理论公式提供了对高速信道行为的更准确预测，以最大限度地减少反射对信号完整性的负面影响。

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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IEEE Transactions on Signal and Power Integrity

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