Abstract
Fast high precision relative Global Navigation Satellite System (GNSS positioning is very important to various applications and ambiguity resolution is a key requirement. It has been a continuing challenge to determine and fix GNSS carrier-phase ambiguity, especially for medium-And long-distance baselines. In past research, with dual-frequency band Global Positioning System (GPS, it is almost impossible for fast ambiguity resolution of medium-And long-distance baselines mainly due to the ionospheric and tropospheric effects. With the launch of the BeiDou system, triple-frequency band GNSS observations are available for the first time. This research aims to test the ambiguity resolution performance with BeiDou triple-frequency band observations. In this research, two mathematical models are compared: zenith tropospheric delay as an unknown parameter versus corrected tropospheric delay. The ambiguity resolution performance is investigated in detail with BeiDou observations. Different distance baselines are tested: 45 km, 70 km and 100 km and the performances are investigated with different elevation cut-off angles. Also the performance with BeiDou alone and combined BeiDou and GPS are compared. Experimental results clearly show that with practical observations of triple-frequency bands, ambiguity of medium-or long-distance baselines can be fixed. The results also show that: the performance of ambiguity resolution with an elevation cutoff angle of 20° is much better than that of 15°; The performance with tropospheric effect corrected is slightly better than that with tropospheric effect as an estimated parameter; Dual-frequency band GPS observations will benefit ambiguity resolution of integrated BeiDou and GPS.
Original language | English |
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Pages (from-to) | 1109-1119 |
Number of pages | 11 |
Journal | Journal of Navigation |
Volume | 67 |
Issue number | 6 |
DOIs | |
Publication status | Published - 1 Jan 2014 |
Keywords
- Ambiguity resolution
- BeiDou
- Ionosphere
- Medium-And long-distance baselines
- Troposphere
ASJC Scopus subject areas
- Oceanography
- Ocean Engineering