Abstract
Because of the special design of BeiDou navigation satellite system (BDS) constellation, the effects of ionospheric scintillation on operational BDS generally are more serious than on the global positioning system (GPS). As BDS is currently providing global services, it is increasingly important to seek strategies to mitigate the scintillation effects on BDS navigation and positioning services. In this study, an improved cycle-slip threshold model is proposed to decrease the high false-alarm rate of cycle-slips under scintillation conditions, thus avoiding the frequent unnecessary ambiguity resets in BDS precise point positioning (PPP) solution. We use one-year (from 23 March 2015 to 23 March 2016) BDS dataset from Hong Kong Sha Tin (HKST) station (22.4°N, 114.2°E; geomagnetic latitude: 15.4°N) to model the cycle-slip threshold and try to make it suitable for three types of BDS satellites and multiple scintillation levels. The availability of our mitigation strategy is validated by using three months (from 1 September 2015 to 30 November 2015) BDS dataset collected at 10 global navigation satellite system (GNSS) stations in Hong Kong. Positioning results demonstrate that our mitigated BDS PPP can prevent the sudden fluctuations of positioning errors induced by the ionospheric scintillation. Statistical results of BDS PPP experiments show that the mitigated solution can maintain an accuracy of about 0.08 m and 0.10 m in the horizontal and vertical components, respectively. Compared with standard BDS PPP, the accuracy of mitigated PPP can be improved by approximately 24.1%, 38.2%, and 47.9% in the east, north, and up directions, respectively. Our study demonstrates that considering different scintillation levels to establish appropriate cycle-slip threshold model in PPP processing can efficiently mitigate the ionospheric scintillation effects on BDS PPP.
Highlights
The Chinese BeiDou navigation satellite system (BDS) was declared to provide global positioning services on 27 December 2018
Using six months of data collected at Hong Kong Sha Tin (HKST) station during spring (March–May) and autumn (September–November) in the year 2015, we show that the BDS scintillation events account for 35.5% and 24.2% in spring and autumn equinoxes respectively, while the percentages of global positioning system (GPS) scintillation events are only 28.7% and 18.6%
This study presents an improved cycle-slip threshold model to decrease the false-alarm rate of cycle-slips detection under ionospheric scintillation conditions, avoiding the frequent unnecessary ambiguity resets in precise point positioning (PPP) solution
Summary
The Chinese BeiDou navigation satellite system (BDS) was declared to provide global positioning services on 27 December 2018. Benefiting from the special constellation design, it is expected that BDS at low-latitudes of Asia-Pacific has the advantage of providing better positioning services compared with other global navigation satellite system (GNSS) [3,4]. Due to the high electron densities and Rayleigh–Taylor instability mechanism, ionospheric irregularities at low-latitudes are initiated at the bottom side of ionosphere F layer after sunset especially during solar maximum periods. They are called plasma plumes and their spatial scales can vary from a few meters to several hundred kilometers [7,8,9,10]. Under scintillation activity, degraded positioning results arose in other GPS techniques such as single point positioning (SPP) [17] and differential GPS (DGPS) [18]
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