共查询到18条相似文献,搜索用时 78 毫秒
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伪距单点定位的精度分析及改进 总被引:1,自引:0,他引:1
GPS伪距单点定位速度快、不存在整周模糊度,因此具有很大的应用价值。分析了电离层延迟、对流层延迟、相对论效应、地球自转改正对伪距单点定位结果的影响,介绍了两种多历元求解时处理接收机钟差的方法,最后讨论了如何以大地坐标和高斯坐标为参数进行定位求解。 相似文献
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合理的随机模型对提高GNSS定位精度具有重要的现实意义。针对高度角定权等常规随机模型无法较准确评估伪距观测值质量,提出一种基于伪距观测噪声的分区定权方法。首先,基于载波、伪距双差观测量构建几何无关组合,并利用滑动窗口取平均法进一步分离出伪距观测噪声;在此基础上,以观测噪声越小对定位解算贡献率越大为原则,建立了观测噪声分区定权的随机模型;最后,设计伪距差分静、动定位实验分析其性能。结果表明,在不同距离条件下,基于观测噪声的分区定权模型无论是在静态还是动态伪距差分定位中,定位精度都要优于等权及高度角定位模型。该随机模型有效提高了伪距定位精度,且易于实现,具有一定的实际应用价值。 相似文献
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The Indian Regional Navigation Satellite System (IRNSS) has recently (as of May 2016) become operational. The system has been developed with the objective of offering positioning, navigation, and timing (PNT) to users in its two service areas, covering the Indian landmass and the Indian Ocean, respectively. It is the goal of this contribution to provide further insight into the full-constellation L5 pseudorange single-point positioning (SPP) capabilities of the system. A detailed dilution of precision (DOP) analysis of its two service areas, including the identification, in location and time, of poor receiver-satellite geometries is provided. It is hereby demonstrated how the impact of some of these poor receiver-satellite geometries can be mitigated by means of height-constraining. An overview and analysis of the SPP precision is also provided including easy-to-use representative day-averaged values for a grid of locations covering the two service areas. 相似文献
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Comparing to single BeiDou Navigation Satellite System (BDS) Precise Point Positioning (PPP), a method which can more quicklydetermine the ambiguity parameters of BDS through applying the contribution of GPS observations is proposed and analyzed in this article. The numerical examples and analysis show that the ionosphere-free ambiguities of BDS satellites can be determined and converged more quickly because of the contribution of GPS observations. The average improvement of the convergent speed of positioning is 18.5% and its positioning accuracy in N, E, and U components are improved by 29.4, 30.3, and 34.4%, respectively, with the contribution of the a priori coordinates obtained from GPS observations. This method is useful for single BDS system positioning when there is a priori information provided by GPS or other sensors which be replaced by and can be applied at the beginning of the computation. 相似文献