Satellite-Clock Modeling in Single-Frequency PPP-RTK Processing

Kan Wang, A. Khodabandeh, P. Teunissen, N. Nadarajah
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引用次数: 11

Abstract

The real-time kinematic precise point positioning (PPP-RTK) technique enables integer ambiguity resolution by providing singlereceiver users with information on the satellite phase biases next to the standard PPP corrections. Using undifferenced and uncombined observations, rank deficiencies existing in the design matrix need to be eliminated to formestimable parameters. In this contribution, the estimability of the parameters was studied in single-frequency ionosphere-weighted scenario, given a dynamic satellite-clock model in the network Kalman filter. In case of latency of the network corrections, the estimable satellite clocks, satellite phase biases, and ionospheric delays need to be predicted over short time spans. With and without satellite-clock models incorporated in the network Kalman filter, different approaches were used to predict the network corrections. This contribution shows how the predicted network corrections responded to the presence and absence of satellite-clock models. These differences in the predicted network corrections were also reflected in the user positioning results. Using three different 1-Hz global positioning system (GPS) single-frequency data sets, two user stations in one small-scale network were used to compute the positioning results, applying predicted network corrections. The latency of the network products ranges from 3 to 10 s. It was observed that applying strong satellite-clock constraints in the network Kalman filter (i.e., with the process noise of 1 or 0.5mm per square root of second) reduced the root-mean squares (RMS) of the user positioning results to centimeters in the horizontal directions and decimeters in the vertical direction for latencies larger than 6 s, compared to the cases without a satellite-clock model.
单频PPP-RTK处理中的卫星时钟建模
实时运动精确点定位(PPP- rtk)技术通过向单个接收机用户提供卫星相位偏差的信息,从而实现整数模糊度的解决。利用未差分和未组合的观测值,需要消除设计矩阵中存在的秩缺陷,以形成可估计的参数。在此贡献中,研究了单频电离层加权情景下参数的可估计性,给出了网络卡尔曼滤波器中的动态卫星时钟模型。在网络修正延迟的情况下,需要在短时间跨度内预测可估计的卫星时钟、卫星相位偏差和电离层延迟。在网络卡尔曼滤波器中加入卫星时钟模型和不加入卫星时钟模型时,使用了不同的方法来预测网络改正。这一贡献显示了预测的网络修正如何响应卫星时钟模型的存在和不存在。这些预测网络修正量的差异也反映在用户定位结果中。利用3个不同的1 hz全球定位系统(GPS)单频数据集,利用一个小尺度网络中的2个用户站,应用预测网络改正量计算定位结果。网络产品的时延范围为3 ~ 10秒。研究发现,与不使用卫星时钟模型的情况相比,在网络卡尔曼滤波器中应用强卫星时钟约束(即过程噪声为1或0.5mm /平方根秒)将用户定位结果的均方根(RMS)在水平方向上降低到厘米,在垂直方向上降低到分米,延迟大于6 s。
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