SP Technical Research Institute of Sweden and STUPI have performed a time transfer experiment over a 500-km-long baseline between Boras and Stockholm. The time transfer technique passively utilizes the data bit stream generated in an optical fiber computer network based on the packet over SONET/SDH technique. A small fraction of the optical signal is monitored both at the transmitter and at the receiver. When an occurrence of a unique bit sequence of the SDH frames is detected, an electrical pulse is generated and compared with a resolution of 100 ps to a local clock. With data from all four positions of an optical bidirectional link, two-way time transfer can be achieved and any symmetrical variations in delay can potentially be cancelled. The results presented here have been obtained over OptoSUNET, the new Swedish University Network. In the experiment, 10 Gbit/s traffic from SP over OptoSUNET is extended in Stockholm to STUPI, a clock laboratory which is the second node in this setup. This reconnection enables that a communication channel is established between two nodes, with no intermediate jump. The time-transfer experiment includes more than 500 km of fiber transmission, of which several km is via air-lines. By comparing the results from a GPS carrier-phase link, a precision better than ± 1 ns is achieved over several months of measurements between two hydrogen-masers.
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机译:SP技术研究所瑞典和佛寺在鲍拉斯和斯德哥尔摩之间的500公里长的基线上进行了时间转移实验。时间传输技术通过SONET / SDH技术的分组被动地利用光纤计算机网络中生成的数据比特流。在发射器和接收器处监测一小部分光信号。当检测到SDH帧的唯一位序列时,产生电脉冲并将电脉冲与100ps的分辨率进行比较。利用来自光学双向链路的所有四个位置的数据,可以实现双向时间转移,并且可能会潜在地取消延迟的任何对称变化。这里呈现的结果已在新瑞典大学网络上获得Optosunet。在实验中,来自SP OVER OPTOSUNET的10 Gbit / S流量在斯德哥尔摩延伸到Stupi,一个时钟实验室,即该设置中的第二个节点。该重新连接使得能够在两个节点之间建立通信信道,没有中间跳转。时转实验包括超过500公里的纤维传输,其中几kM通过空线。通过比较GPS载波相位链路的结果,在两个氢气配合物之间的几个月内测量超过±1ns的精度。
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