High Performance Time Synchronisation for Industrial Logic Control Utilising a Low Cost Single Board Computer with EMC Compliance

2018 IEEE International Frequency Control Symposium (IFCS) Pub Date : 2018-05-21 DOI:10.1109/FCS.2018.8597533

G. Adams, R. Siebrits, E. Bauermeister, L. Boyana, S. Malan, M. Welz, R. Vanwyk, R. Gamatham, J. Burger, F. Kapp, N. Mnyandu, S. Tshongweni, A. Otto, C. Vander Merwe

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引用次数: 2

Abstract

The integration of time transfer and control on a low cost single board computer (SBC) system is presented. The solution allows sub-microsecond level timestamping of logic control events and analogue to digital (ADC) measurements. The system is based on low cost, miniature commercially off the shelf (COTS) hardware. External time referencing can be supplied via network timing protocol (NTP), precision timing protocol (PTP) and/or a discrete pulse per second (PPS) signal. The operating distance is extendable to tens of kilometers using a simplified PPS transmission system over fibre, based on the Karoo array timing system (KATS) developed at South African Radio Astronomy Observatory (SARAO). Integration into the MeerKAT Radio Telescope's time and frequency modules shows CISPR 22 compliance and cross coupling effects for sensitive phase transfer systems are below the stringent EMC limits acceptable for radio astronomy. Real-time control is of great importance for industrial and scientific applications. After evaluating existing market-based solutions., these were found to be either cost prohibitive, non-EMC compliant or requiring proprietary network protocols. This implementation serves to offer a time synchronisation solution which is low in cost., has a small footprint and easily integrated into timing applications.

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高性能时间同步工业逻辑控制利用低成本的单板计算机与EMC合规性

提出了一种低成本的单板计算机(SBC)系统，将时间传递与控制集成在一起。该解决方案允许亚微秒级的时间戳逻辑控制事件和模拟到数字(ADC)测量。该系统基于低成本、小型商用现货(COTS)硬件。外部时间参考可以通过网络定时协议(NTP)，精确定时协议(PTP)和/或离散脉冲每秒(PPS)信号提供。使用基于南非射电天文台(SARAO)开发的Karoo阵列授时系统(KATS)的光纤上的简化PPS传输系统，操作距离可扩展到数十公里。集成到MeerKAT射电望远镜的时间和频率模块显示CISPR 22合规性和敏感相位转移系统的交叉耦合效应低于射电天文学可接受的严格EMC限制。实时控制在工业和科学应用中具有重要意义。在评估现有的基于市场的解决方案之后。发现这些方法要么成本过高，要么不符合emc标准，要么需要专有网络协议。这个实现提供了一个低成本的时间同步解决方案。，占地面积小，易于集成到定时应用中。

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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2018 IEEE International Frequency Control Symposium (IFCS)

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