A Novel High Resolution Optical Time Delay Cable Measurement System Utilized in Fiber Verification in Radio Interferometry

2018 IEEE International Frequency Control Symposium (IFCS) Pub Date : 2018-05-01 DOI:10.1109/FCS.2018.8597450

R. Julie, T. Abbott, J. Burger, R. Siebrits

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引用次数: 5

Abstract

A long distance optical fiber cable measurement is described that delivers ~0.2 picosecond (ps) delay resolution with capability for high accuracy relative distance extraction over 10's of microseconds of delay. This is necessary in radio interferometry, for verification, but has general applicability to many situations found in optical fiber transport. For radio interferometry one can use direct RF over fiber to transport the hydrogen maser clock source, and measurement of fiber to certain points in the cable system is very important. The long distance measurements are used to show that the thermal stability of the buried optical fiber cable keeps the propagation delay changes on the optical fiber link stable to less than 9.5 ps over 20 minutes, meeting a key requirement for phase margins for interferometry. The measurement method shows great promise in general optical fiber measurement for optical cables over long distances, with high resolution and dynamic range, enabling capabilities better than those offered by normal OTDR (Optical Time Domain Reflectometer) or OFDR (Optical Frequency Domain Reflectometer) methods.

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一种用于无线电干涉测量中光纤验证的新型高分辨率光延时电缆测量系统

描述了一种长距离光纤电缆测量，它提供了~0.2皮秒(ps)的延迟分辨率，能够在10微秒的延迟内高精度地提取相对距离。这在无线电干涉测量中是必要的，用于验证，但在光纤传输中的许多情况下都具有普遍的适用性。对于无线电干涉测量，可以使用光纤直接射频传输氢脉泽时钟源，测量光纤到电缆系统中的某些点是非常重要的。长距离测量表明，埋地光缆的热稳定性使光纤链路上的传播延迟变化在20分钟内稳定在9.5 ps以下，满足干涉测量相位裕度的关键要求。该测量方法具有高分辨率和动态范围，比普通的OTDR(光时域反射计)或OFDR(光频域反射计)方法提供的性能更好，在长距离光缆的一般光纤测量中显示出很大的前景。

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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