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| Implementation of the carrier phased-based tightly coupled GPS/BDS/INS integration. |
ABSTRACT
The integration of Global Navigation Satellite Systems (GNSS) carrier
phases with Inertial Navigation System (INS) measurements is essential
to provide accurate and continuous position, velocity and attitude
information, however it is necessary to fix ambiguities rapidly and
reliably to obtain high accuracy navigation solutions. In this paper, we
present the notion of combining the Global Positioning System (GPS),
the BeiDou Navigation Satellite System (BDS) and low-cost
micro-electro-mechanical sensors (MEMS) inertial systems for reliable
navigation. An adaptive multipath factor-based tightly-coupled (TC)
GPS/BDS/INS integration algorithm is presented and the overall
performance of the integrated system is illustrated. A twenty seven
states TC GPS/BDS/INS model is adopted with an extended Kalman filter
(EKF), which is carried out by directly fusing ambiguity fixed
double-difference (DD) carrier phase measurements with the INS predicted
pseudoranges to estimate the error states. The INS-aided integer
ambiguity resolution (AR) strategy is developed by using a dynamic
model, a two-step estimation procedure is applied with adaptively
estimated covariance matrix to further improve the AR performance. A
field vehicular test was carried out to demonstrate the positioning
performance of the combined system. The results show the TC GPS/BDS/INS
system significantly improves the single-epoch AR reliability as
compared to that of GPS/BDS-only or single satellite navigation system
integrated strategy, especially for high cut-off elevations. The AR
performance is also significantly improved for the combined system with
adaptive covariance matrix in the presence of low elevation multipath
related to the GNSS-only case. A total of fifteen simulated outage tests
also show that the time to relock of the GPS/BDS signals is shortened,
which improves the system availability. The results also indicate that
TC integration system achieves a few centimeters accuracy in positioning
based on the comparison analysis and covariance analysis, even in harsh
environments (e.g., in urban canyons), thus we can see the advantage of
positioning at high cut-off elevations that the combined GPS/BDS
brings.
Overcoming the Challenges of BeiDou Receiver Implementation
Global Navigation Satellite System (GNSS)-based positioning is experiencing rapid changes. The existing GPS and the GLONASS systems are being modernized to better serve the current challenging applications under harsh signal conditions. These modernizations include increasing the number of transmission frequencies and changes to the signal components. In addition, the Chinese BeiDou Navigation Satellite system (BDS) and the European Galileo are currently under development for global operation. Therefore, in view of these new upcoming systems the research and development of GNSS receivers has been experiencing a new upsurge. In this article, the authors discuss the main functionalities of a GNSS receiver in view of BDS. While describing the main functionalities of a software-defined BeiDou receiver, the authors also highlight the similarities and differences between the signal characteristics of the BeiDou B1 open service signal and the legacy GPS L1 C/A signal, as in general they both exhibit similar characteristics. In addition, the authors implement a novel acquisition technique for long coherent integration in the presence of NH code modulation in BeiDou D1 signal. Furthermore, a simple phase-preserved coherent integration based acquisition scheme is implemented for BeiDou GEO satellite acquisition. Apart from the above BeiDou-specific implementations, a novel Carrier-to-Noise-density ratio estimation technique is also implemented in the software receiver, which does not necessarily require bit synchronization prior to estimation. Finally, the authors present a BeiDou-only position fix with the implemented software-defined BeiDou receiver considering all three satellite constellations from BDS. In addition, a true multi-GNSS position fix with GPS and BDS systems is also presented while comparing their performances for a static stand-alone code phase-based positioning.
Overcoming the Challenges of BeiDou Receiver Implementation
Global Navigation Satellite System (GNSS)-based positioning is experiencing rapid changes. The existing GPS and the GLONASS systems are being modernized to better serve the current challenging applications under harsh signal conditions. These modernizations include increasing the number of transmission frequencies and changes to the signal components. In addition, the Chinese BeiDou Navigation Satellite system (BDS) and the European Galileo are currently under development for global operation. Therefore, in view of these new upcoming systems the research and development of GNSS receivers has been experiencing a new upsurge. In this article, the authors discuss the main functionalities of a GNSS receiver in view of BDS. While describing the main functionalities of a software-defined BeiDou receiver, the authors also highlight the similarities and differences between the signal characteristics of the BeiDou B1 open service signal and the legacy GPS L1 C/A signal, as in general they both exhibit similar characteristics. In addition, the authors implement a novel acquisition technique for long coherent integration in the presence of NH code modulation in BeiDou D1 signal. Furthermore, a simple phase-preserved coherent integration based acquisition scheme is implemented for BeiDou GEO satellite acquisition. Apart from the above BeiDou-specific implementations, a novel Carrier-to-Noise-density ratio estimation technique is also implemented in the software receiver, which does not necessarily require bit synchronization prior to estimation. Finally, the authors present a BeiDou-only position fix with the implemented software-defined BeiDou receiver considering all three satellite constellations from BDS. In addition, a true multi-GNSS position fix with GPS and BDS systems is also presented while comparing their performances for a static stand-alone code phase-based positioning.
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