Abstract
The current cycle slip detection methods of Global Navigation Satellite System (GNSS) were mostly proposed on the basis of assuming the ionospheric delay varying smoothly over time. However, these methods can be invalid during active ionospheric periods, e.g., high Kp index value and scintillations, due to the significant increase of the ionospheric delay. In order to detect cycle slips during high ionospheric activities successfully, this paper proposes a method based on two modified Hatch–Melbourne–Wübbena combinations. The measurement noise in the Hatch–Melbourne–Wübbena combination is minimized by employing the optimally selected combined signals, while the ionospheric delay is detrended using a smoothing technique. The difference between the time-differenced ambiguity of the combined signal and this estimated ionospheric trend is adopted as the detection value, which can be free from ionospheric effect and hold the high precision of the combined signal. Five threshold determination methods are proposed and compared to decide the cycle slip from the magnitude aspect. This proposed method is tested with triple-frequency Global Navigation Satellite System observations collected under high ionospheric activities. Results show that the proposed method can correctly detect and fix cycle slips under disturbed ionosphere.
Highlights
High precision Global Navigation Satellite System (GNSS) positioning requires the availability of high quality carrier phase observations
The method proposed by Zhao et al [13] cannot provide a robust detection performance during high ionospheric activities, one of the proposed combined signals (4, 0, −5) in the modified Hatch–Melbourne–Wubbena (HMW) combinations can maintain a high precise detection value even when it is biased by the ionosphere, revealing the potential to expand the application of the modified HMW combination in the scenario of high ionospheric activities
Since the cycle slip detection method proposed in Zhao et al [13] was invalidated under the condition of strong scintillation, this paper expanded the application of the method to the scenario of high ionospheric activities by reselecting the combined signals and modifying the detection process
Summary
High precision Global Navigation Satellite System (GNSS) positioning requires the availability of high quality carrier phase observations. The performance of this proposed method is extensively evaluated and tested with the data collected with different ionospheric conditions on account of its ability to detect existing and artificially added cycle slips in Sections 5 and 6, respectively.
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