在IEEE 1588中使用硬件支持的同步精度限制

2008 IEEE International Symposium on Precision Clock Synchronization for Measurement, Control and Communication Pub Date : 2008-10-24 DOI:10.1109/ISPCS.2008.4659205

P. Loschmidt, R. Exel, A. Nagy, G. Gaderer

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引用次数: 61

摘要

面向包的网络的时钟同步协议，如IEEE 1588，依赖于从本地时钟在不同时间点绘制的时间戳。由于软件生成的时间戳会受到执行时间不确定造成的抖动的影响，许多高精度时钟同步的实现依赖于硬件支持。这允许在物理层附近读取具有非常低抖动的数据包的时间。然而，当涉及到纳秒范围时，使用硬件支持的方法必须仔细考虑对同步精度的影响。其中，限制来自更新间隔、振荡器稳定性或硬件时钟频率。本文在分析影响抖动的主要因素的基础上，提出了这种实现的限制。结论为有效优化当前实现提供了提示。

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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Limits of synchronization accuracy using hardware support in IEEE 1588

Clock synchronization protocols for packet-oriented networks, like IEEE 1588, depend on time stamps drawn from a local clock at distinct points in time. Due to the fact that software-generated time stamps suffer from jitter caused by non-deterministic execution times, many implementations for high precision clock synchronization rely on hardware support. This allows time readings for packets with very low jitter close to the physical layer. Nevertheless, approaches using hardware support have to carefully consider influences on synchronization accuracy when it comes to the range of nanoseconds. Among others, limits come from the update interval, oscillator stability, or hardware clock frequency. This paper enlightens the limits for such implementations based on an analysis of the influences of the main factors for jitter. The conclusions give hints for efficiently optimizing current implementations.

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2008 IEEE International Symposium on Precision Clock Synchronization for Measurement, Control and Communication

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