GNSS signal phase, TEC, and phase unwrapping errors

Annual of Navigation Pub Date : 2020-12-01 DOI:10.1002/navi.396

C. Rino, Brian Breitsch, Y. Morton, Dongyang Xu, C. Carrano

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引用次数: 1

Abstract

Precise measurements of signal phase are essential for Global Navigation Satellite System (GNSS) position estimates. However, propagation through the earth's ionosphere imposes frequency-dependent phase errors. The frequency dependence is exploited to correct phase errors proportional to total electron content (TEC) divided by frequency. Scintillation causes additional stochastic errors, which can become the largest phase error contribution. Both geometry-free (GFCs) and ionosphere-free (IFCs) frequency combinations are subject to such uncorrectable but generally small phase scintillation errors. A recent published study compared GPS TEC estimates derived from nominally identical L1-L2 and L1-L5 GFCs. The TEC errors establish an upper bound on uncorrelated single-frequency scintillation error contributions. The measured TEC errors were verified with phase-screen simulations. However, a known but largely overlooked phase unwrapping error affects the extraction of signal phase from phase-screen complex signal realizations. This paper demonstrates a procedure for detecting and correcting phase-unwrapping errors and discusses their ramifications.

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GNSS信号相位、TEC和相位展开误差

信号相位的精确测量对于全球导航卫星系统（GNSS）的位置估计至关重要。然而，通过地球电离层的传播会产生频率相关的相位误差。利用频率相关性来校正与总电子含量（TEC）除以频率成比例的相位误差。闪烁会导致额外的随机误差，这可能成为最大的相位误差贡献。无几何体（GFCs）和无电离层（IFC）频率组合都会受到这种不可校正但通常较小的相位闪烁误差的影响。最近发表的一项研究比较了名义上相同的L1-L2和L1-L5 GFC得出的GPS TEC估计值。TEC误差建立了不相关单频闪烁误差贡献的上限。通过相位屏模拟验证了测量的TEC误差。然而，一个已知但在很大程度上被忽视的相位展开误差影响了从相位屏复信号实现中提取信号相位。本文演示了一种检测和校正相位展开误差的程序，并讨论了其后果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Annual of Navigation

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审稿时长

20 weeks