IEEE 1588 based time synchronization system for a seafloor observatory network 被引量：4

IEEE 1588 based time synchronization system for a seafloor observatory network

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摘要 An IEEE 1588 based application scheme was proposed to achieve accurate time synchronization for a deep seafloor observatory network based on the communication topological structure of the Zhejiang University Experimental and Research Observatory.The principles of the network time protocol(NTP)and precision time protocol(PTP)were analyzed.The framework for time synchronization of the shore station,undersea junction box layer,and submarine science instrument layer was designed.NTP and PTP network signals were decoded by a PTP master clock on a shore station that receives signals from the Global Positioning System and the BeiDou Navigation Satellite System as reference time sources.These signals were remotely transmitted by a subsea optical–electrical composite cable through an Ethernet passive optical network.Accurate time was determined by time synchronization devices in each layer.Synchronization monitoring experiments performed within a laboratory environment indicated that the proposed system is valid and has the potential to realize microsecond accuracy to satisfy the time synchronization requirements of a high-precision seafloor observatory network. An IEEE 1588 based application scheme was proposed to achieve accurate time synchronization for a deep seafloor observatory network based on the communication topological structure of the Zhejiang University Experimental and Research Observatory. The principles of the network time protocol （NTP） and precision time protocol （PTP） were analyzed. The framework for time synchronization of the shore station, undersea junction box layer, and submarine science instrument layer was designed. NTP and PTP network signals were decoded by a PTP master clock on a shore station that receives signals from the Global Posi- tioning System and the BeiDou Navigation Satellite System as reference time sources. These signals were remotely transmitted by a subsea optical-electrical composite cable through an Ethernet passive optical network. Accurate time was determined by time synchronization devices in each layer. Synchronization monitoring experiments performed within a laboratory environment indicated that the proposed system is valid and has the potential to realize microsecond accuracy to satisfy the time synchronization requirements of a high-precision seafloor observatory network.

作者 De-jun LI Gang WANG Can-jun YANG Bo JIN Yan-hu CHEN

机构地区 State Key Laboratory of Fluid Power Transmission and Control

出处《Journal of Zhejiang University-Science C(Computers and Electronics)》 SCIE EI 2013年第10期766-776,共11页 浙江大学学报C辑（计算机与电子（英文版）

基金 Project supported by the National High-Tech R&D(863)Program ofChina(No.2012AA09A408) the National Natural ScienceFoundation of China(No.51221004)

关键词 Seafloor observatory network Junction box IEEE 1588 Time synchronization Seafloor observatory network, Junction box, IEEE 1588, Time synchronization

分类号 TN915.0 [电子电信—通信与信息系统]

作者简介 E-mail： li dejun@zju.cdu.cn; E-mail： wgscu@126.com

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Journal of Zhejiang University-Science C(Computers and Electronics)

2013年第10期

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