High-speed bus signal integrity compliance using a frequency-domain model

2016 IEEE International Symposium on Electromagnetic Compatibility (EMC) Pub Date : 2016-07-25 DOI:10.1109/ISEMC.2016.7571594

Si T. Win, J. Hejase, W. Becker, Glen A. Wiedemeier, D. Dreps, J. Myers, K. Willis, John Horner, A. Varma

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引用次数: 3

Abstract

A new technique for frequency-domain compliance testing of high-speed differential interfaces is implemented in a signal integrity simulation tool that can accurately predict a channel's bit-error rate (BER) from seven frequency-domain parameters. This greatly increases the speed and efficiency of designing the number of computer systems required for custom configurations in scale-out data centers. The compliance method is tested with three example case studies in channel printed circuit board (PCB) design. These three studies are: finding maximum loss due to routable trace length as a function of wiring depth layer (which affects crosstalk), finding the maximum routable length when introducing reflections and crosstalk due to adding a connector in the channel, and finding what amount of skew introduced by asymmetry in a differential pair for reasons such as the glass weave or different copper lengths under which a channel can still operate. The pass/fail frequency compliance results are discussed and compared with the time-domain simulation results of the channels tested.

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高速总线信号完整性符合性使用频域模型

在信号完整性仿真工具中实现了高速差分接口频域符合性测试的新技术，该技术可以从7个频域参数准确预测信道的误码率(BER)。这大大提高了在向外扩展的数据中心中设计自定义配置所需的计算机系统数量的速度和效率。通过对通道印刷电路板(PCB)设计中的三个实例进行了验证。这三项研究分别是:寻找可路由走线长度作为布线深度层的函数(影响串扰)所导致的最大损耗，在引入反射和由于在通道中添加连接器而导致的串扰时，寻找最大可路由长度，以及寻找由于玻璃编织或不同铜长度等原因导致的差分对中不对称所引入的歪斜量，在这种情况下通道仍然可以运行。讨论了通/不合格频率顺应性结果，并与测试信道的时域仿真结果进行了比较。

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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2016 IEEE International Symposium on Electromagnetic Compatibility (EMC)

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