Abstract
Nowadays one can use four global navigation satellite systems (GNSS). Two of them are complete constellations (GPS, Glonass) and two (Beidou, Galileo) are already usable and will be finish in the near future. Additionally satellite based augmentation systems (SBAS) like WAAS, EGNOS, GAGAN or QZSS complement the GNSS service. However, within all systems one can observe changes, modifications, and updates every year. This can be related to satellite renewables leading to signal property changes. Especially, for safety critical applications using GNSS, like advanced receiver autonomous integrity monitoring (ARAIM) or ground-based augmentation systems (GBAS) the new or changed signal properties are of high interest. With the help of detailed information about the signal deformation and the received signal power it is possible to calculate realistic error bounds and consequently realistic protection level for these kinds of safety critical applications. This paper presents an overview of the findings according new signals or signal configurations of GPS, Beidou and QZSS of the last two years. After a brief introduction of the measurement facility the paper will introduce basic analysis about the quality of the signal shape in spectral and modulation domain. Using our precise calibrated measurement facility, we will also present an analysis of the transmitted satellite signal power including estimates about the power sharing among individual signal components within each band. Considering the measured power in relation to the boresight angle of the satellite one can derive a cut through the antenna pattern of the satellite and can assess the antenna symmetry properties. Examples for different satellites will be presented. Finally, we will end with a conclusion regarding the considered signal developments and its impact on GNSS users.
Highlights
Global navigation satellite systems (GNSS) are used in thousands of applications all over the globe
L1/L2 signal spectra of GPS satellites have been obtained to highlight the presence or amplitude variation of different modulations in the course of flex power tests. These are complemented by in-phase and quadrature (IQ) measurements, which are the basis for the evaluation of the relative power distribution among individual signal components
Based on their analysis they confirmed the presence of a time multiplexed binary offset carrier (TMBOC) signal and its power sharing between its individual components and an additional BOC(14,2) and a legacy B1I signal (Beidou phase 2) at L1-14 Mhz
Summary
Global navigation satellite systems (GNSS) are used in thousands of applications all over the globe. At the same time, since January 2017, a geographically driven flex power mode is enabled on ten Block IIF satellites [7] This is visible in carrier-to-noise density ratio observations of groundbased GPS receivers as well as differential code bias estimates between the L1 C/A- and P(Y)-code signals [6]. L1/L2 signal spectra of GPS satellites have been obtained to highlight the presence or amplitude variation of different modulations in the course of flex power tests These are complemented by in-phase and quadrature (IQ) measurements, which are the basis for the evaluation of the relative power distribution among individual signal components. In contrast to the permanent installation of the geographically driven flex power mode described above, the configuration of the transmit power between the GPS components changed in L1 and in L2 frequency band. While the power of the P(Y)-code have been increased by approximately 6 dB in L1 and 5 dB in L2 the C/A-code respectively L2C-code remain nearly constant
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