基于FPGA的时钟同步技术

2015 IEEE International Conference on Communication Software and Networks (ICCSN) Pub Date : 2015-06-06 DOI:10.1109/ICCSN.2015.7296124

Chen Yong, Wu Hao, Tan Xiaofeng, Wu Wenbo

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引用次数: 1

摘要

为了解决分布式系统中的时钟同步问题，介绍了两种硬件方法。采用外部1PPS时钟在本频域产生同步时钟(S时钟)。其中一种方法是通过硬件逻辑直接跟踪和锁定1PPS时钟，然后立即刺激S时钟。解决了现场1PPS故障和时钟丢失问题。另一种方法是建立多时钟数学模型来校正1PPS时钟的自抖动。所有程序均在一个FPGA芯片上实现，采用NiosII软CPU，采用纯物理层同步方式。与传统的上位机软件解决方案相比，硬件时钟同步可以达到微秒级精度，并且更加稳定。

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Clock synchronization technology based on FPGA

To solve clock synchronization problem in distributed system, two hardware methods were introduced. External 1PPS clock was used to generate synchronized clock (S clock) in local frequency domain. In one method, 1PPS clock was directly tracked and locked by hardware logic, and then stimulates S clock immediately. 1PPS glitch and clock-lost problems in field were solved. In the other method, the multi-clocks mathematical models were built to correct 1PPS clock self-jitter. All the program were realized in one FPGA chip with NiosII soft CPU, which were pure physical layer synchronization style. Compared to traditional software solutions in the host computer, hardware clock synchronization can reach microseconds precision, and is more stable.

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来源期刊

2015 IEEE International Conference on Communication Software and Networks (ICCSN)

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