Precise Receiver Clock Offset Estimations According to Each Global Navigation Satellite Systems (GNSS) Timescales

IF 0.7 Q4 ASTRONOMY & ASTROPHYSICS Artificial Satellites-Journal of Planetary Geodesy Pub Date : 2017-12-01 DOI:10.1515/arsa-2017-0009
Thayathip Thongtan, Pawit Tirawanichakul, C. Satirapod
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引用次数: 9

Abstract

Abstract Each GNSS constellation operates its own system times; namely, GPS system time (GPST), GLONASS system time (GLONASST), BeiDou system time (BDT) and Galileo system time (GST). They could be traced back to Coordinated Universal Time (UTC) scale and are aligned to GPST. This paper estimates the receiver clock offsets to three timescales: GPST, GLONASST and BDT. The two measurement scenarios use two identical multi-GNSS geodetic receivers connected to the same geodetic antenna through a splitter. One receiver is driven by its internal oscillators and another receiver is connected to the external frequency oscillators, caesium frequency standard, kept as the Thailand standard time scale at the National Institute of Metrology (Thailand) called UTC(NIMT). The three weeks data are observed at 30 seconds sample rate. The receiver clock offsets with respected to the three system time are estimated and analysed through the geodetic technique of static Precise Point Positioning (PPP) using a data processing software developed by Wuhan University - Positioning And Navigation Data Analyst (PANDA) software. The estimated receiver clock offsets are around 32, 33 and 18 nanoseconds from GPST, GLONASST and BDT respectively. This experiment is initially stated that each timescale is inter-operated with GPST and further measurements on receiver internal delay has to be determined for clock comparisons especially the high accuracy clock at timing laboratories.
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根据每个全球导航卫星系统(GNSS)时标的精确接收机时钟偏移估计
摘要每个GNSS星座都运行自己的系统时间;即GPS系统时间(GPST)、GLONASS系统时间(GLONASST)、北斗系统时间(BDT)和伽利略系统时间(GST)。它们可以追溯到协调世界时(UTC)刻度,并与GPST对齐。本文估计了接收器时钟偏移到三个时间尺度:GPST、GLONASST和BDT。这两种测量场景使用两个相同的多GNSS大地测量接收器,通过分离器连接到同一大地测量天线。一个接收器由其内部振荡器驱动,另一个接收器连接到外部频率振荡器,铯频率标准,在泰国国家计量研究所被称为UTC(NIMT),保持为泰国标准时标。以30秒的采样率观察三周的数据。利用武汉大学开发的数据处理软件——定位导航数据分析软件(PANDA),通过静态精密点定位(PPP)大地测量技术,估计并分析了接收机时钟相对于三个系统时间的偏移。估计的接收机时钟偏移分别为GPST、GLONASST和BDT的32、33和18纳秒左右。该实验最初指出,每个时间尺度都与GPST相互操作,必须确定接收器内部延迟的进一步测量值,以进行时钟比较,尤其是定时实验室的高精度时钟。
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