时序信号设计的一种新方法

文章结合高速时序工作的特点,从实现的角度提出了一种利用软件调整时序的新方法。在可编程逻辑器件中,利用数字时钟管理器(DCM),通过模块化和增量式设计思想达到对高速时序信号的精确调节。最终实现了一个20MHz速率的时序控制,调节精度达到100ps。     

原子钟时域频率稳定性计算方法

首先给出时域频率稳定性分析中各种方差的实用计算公式，并在此基础上分析各种方差特性，总结归纳其适用范围。分析表明：①阿仑方差是时域频率稳定性分析中最常用的方法，但不能区分调相白噪声和调相闪变噪声；②改进阿仑方差通过相位平滑运算能识别这2种噪声；③时间方差和时间总方差主要用于描述频率源的时间波动，主要用于分析调相噪声；④当频率漂移项较大或受甚低频噪声影响时，哈达玛系列方差能给出很好的测量特性。     

基于BDS-2/BDS-3联合处理的北斗超快速钟差预报优化策略

针对北斗卫星导航系统(BDS)钟差预报产品无法满足高精度快速服务需求的现状，提出了一种基于BDS-2/BDS-3联合估计的超快速卫星钟差预报优化策略。区别于传统两步法预报模型，利用稀疏建模方法一步求解所有模型项，并通过BDS-2/BDS-3星间相关性实现了模型系数解的增强；为进一步降低模型残差的影响，基于残差序列时空相关性，利用半变异函数重构了模型估计的权阵。为验证提出的钟差预报模型，设计了12套对比方案，实验结果表明：基于稀疏建模的钟差模型参数一步估计可略微提高钟差预报精度；通过引入星间相关性对随机模型进行精化，钟差序列一步建模可分别将BDS-2与BDS-3卫星钟差18h预报精度提升28.6%与27.2%；基于半变异函数建模的模型残差相关性提取，可实现BDS-2与BDS-3预报钟差精度8.0%与11.1%的提升。因此，提出的优化策略对当前北斗超快速卫星钟差预报产品精化具有重要意义。     

iGMAS分析中心产品一致性分析及其应用研究

通过比较不同分析中心提供的精密轨道与钟差产品发现，不同分析中心的轨道和钟差表现出明显差异，并且轨道径向和钟差的相对偏差存在很强的相关性和周期特性。经过数据分析，BDS、GPS、GLONASS的轨道径向和钟差相对偏差具有12h和24h周期项，而Galileo具有12h周期项。因此，提出了一种新的钟差拟合及加权综合方法，通过建立多项式+不同周期项模型对钟差进行拟合求得残差序列，利用残差序列对不同分析中心产品的钟差值进行定权，并将加权均值作为钟差综合值。通过与ISC钟差对比发现，提出的钟差综合模型可以明显提高部分分析中心产品的钟差精度，并优化iGMAS分析中心钟差产品的一致性。     

Real-time clock comparison and monitoring with multi-GNSS precise point positioning: GPS,GLONASS and Galileo

The precise point positioning (PPP) technique is widely used in time and frequency applications. Because of the real-time service (RTS) project of the International GNSS Service, we can use the PPP technique for real-time clock comparison and monitoring. As a participant in the RTS, the Centre National d’Etudes Spatiales (CNES) implements the PPPWIZARD (Precise Point Positioning with Integer and Zero-difference Ambiguity Resolution Demonstrator) project to validate carrier phase ambiguity resolution. Unlike the Integer-PPP (IPPP) of the CNES, fixing ambiguities in the post-processing mode, the PPPWIZARD operates in the real-time mode, which is also called real-time IPPP (RT-IPPP). This paper focuses on applying the RT-IPPP for real-time clock comparison and monitoring. We review the principle of real-time clock comparison and monitoring, and introduce the methodology of the RT-IPPP technique. The observations of GPS, GLONASS and Galileo were processed for the experiments. Five processing modes were provided in the experiment to analyze the benefits of ambiguity resolution and multi-GNSS. In the clock comparison experiment, the average reduction ratios of standard deviations with respect to the G PPP mode range from 9.7% to 35.0%. In the clock monitoring experiment, G PPP mode can detect clock jumps whose magnitudes are larger than 0.9 ns. The RT-IPPP technique with GRE PPP AR (G) mode allows for the detection of any clock jumps larger than 0.6 ns. For frequency monitoring, G PPP mode allows detection of frequency changes larger than 1.1 × 10⁻¹⁴. When the RT-IPPP technique is applied, monitoring with GRE PPP AR (G) mode can detect frequency changes larger than 6.1 × 10⁻¹⁵.     

Statistical characteristics of low latitude Pc4s: Influence of solar wind and IMF parameters

Pc4 signatures for the year 2013, extracted from geomagnetic north–south and east–west components of induction coil magnetometer (LEMI 30) from low latitude station Desalpar (DSP), operated by Institute of Seismological Research (ISR), India have been investigated vis-à-vis the prevalent interplanetary parameters (IMF) as well as the geomagnetic activity indices. A clear dominance of Pc4-5 (467 events) over Pc3 (17 events) is observed. Local time variation of Pc4 shows a peak in the noon sector in both X and Y components. Our investigations show that the dominant peak frequency is 10 mHz at low latitude region. Correlations with solar wind and IMF parameters illustrate highest occurrence of Pc4 for a solar wind speed of 300–400 km/s and average IMF B field of 3–6 nT. The amplitude of Pc4s at DSP shows an increase with increasing solar wind speed, plasma density, solar wind dynamic pressure and average B field which is also reflected in the trend of frequency variation of these pulsations. We report that IMF clock angle at low latitude does not have influence on Pc4 occurrence. Based on the characteristics of these events, detected in latitudinally distributed stations from low and mid-latitudes from northern and southern hemisphere, we infer that modes were compressional, which could be driven by K-H instability or solar wind dynamic pressure, as compressional modes can propagate to low latitude with little attenuation.     

GNSS驯服芯片级原子钟方法研究CSCD

芯片级原子钟是一种体积小且功耗低的高精度时钟源,具有广泛的用途。针对这一特点,设计了基于GNSS的芯片级原子钟驾驭算法。以GNSS系统时作为参考,测量芯片级原子钟与GNSS系统时间的钟差,并对芯片级原子钟进行钟差建模,获取其特征参数。通过乒乓法计算出钟驾驭调整量,对芯片级原子钟进行控制,最终将芯片级原子钟驾驭到GNSS系统时间上。经过实验验证,在驾驭时间常数为100s的情况下,芯片级原子钟与GNSS系统时间的时钟同步误差在-7.5~7.5ns之间;1h频率准确度为5.8×10-13;平均时间为10000s时的频率稳定度为3×10-13。     

原子钟调相白噪声降噪方法

原子钟的五种噪声反映了它在一定时间间隔内的性能。当取样间隔小于1h,原子钟主要表现为调相白噪声。在地方协调时UTC(NTSC)的实时监控中,不仅要求参考原子时(RTA,用于地方协调时控制的参考)具有很高的长期稳定度,而且要求其短期稳定度亦很高。影响RTA短期稳定度的主要是个台原子钟的调相白噪声。首先讨论了确定原子钟短期噪声的方法,进而利用小波分析方法研究了原子钟调相白噪声分离与降噪的方法。     

The impact of orbital errors on the estimation of satellite clock errors and PPP

Precise satellite orbit and clocks are essential for providing high accuracy real-time PPP (Precise Point Positioning) service. However, by treating the predicted orbits as fixed, the orbital errors may be partially assimilated by the estimated satellite clock and hence impact the positioning solutions. This paper presents the impact analysis of errors in radial and tangential orbital components on the estimation of satellite clocks and PPP through theoretical study and experimental evaluation. The relationship between the compensation of the orbital errors by the satellite clocks and the satellite-station geometry is discussed in details. Based on the satellite clocks estimated with regional station networks of different sizes (∼100, ∼300, ∼500 and ∼700 km in radius), results indicated that the orbital errors compensated by the satellite clock estimates reduce as the size of the network increases. An interesting regional PPP mode based on the broadcast ephemeris and the corresponding estimated satellite clocks is proposed and evaluated through the numerical study. The impact of orbital errors in the broadcast ephemeris has shown to be negligible for PPP users in a regional network of a radius of ∼300 km, with positioning RMS of about 1.4, 1.4 and 3.7 cm for east, north and up component in the post-mission kinematic mode, comparable with 1.3, 1.3 and 3.6 cm using the precise orbits and the corresponding estimated clocks. Compared with the DGPS and RTK positioning, only the estimated satellite clocks are needed to be disseminated to PPP users for this approach. It can significantly alleviate the communication burdens and therefore can be beneficial to the real time applications.     

GNSS超快速产品在全球标准时间复现中的应用

为满足大跨度空间范围内的时间同步需求,对基于共视时间比对原理的标准时间复现系统进行改进,采用全视时间比对方法解决原系统应用基线受限的问题.考虑实时性的要求,使用全球卫星导航系统(GNSS)超快速产品(预测部分)提供卫星位置和卫星钟差,以尽可能消除广播星历和钟差对复现结果的影响.分析了常用的几家机构发布的GNSS超快速产...