Abstract
Integrity monitoring is an essential task for ensuring the safety of positioning services. Under a selected probability of hazardous misleading information, the protection levels (PLs) are computed according to a considered threat model to bound the positioning errors. A warning message is sent to users when the PL exceeds a pre-set alert limit (AL). In the short-baseline real-time relative kinematic positioning, the spatially correlated errors, such as the the orbital errors and the atmospheric delays are significantly reduced. However, the remaining atmospheric residuals and the multipath that are not considered in the observation model could directly bias the positioning results. In this contribution, these biases are analysed with the focus put on the multipath effects in different measurement environments. A new observation weighting model considering both the elevation angle and the signal-to-noise ratios is developed and their impacts on the positional results are investigated. The coefficients of the proposed weighting model are determined for the open-sky and the suburban scenarios with the positional benefits maximised. Next, the overbounding excess-mass cumulative distribution functions (EMCs) are searched on the between-receiver level for the weighted phase and code observations in these two scenarios. Based on the mean and standard deviations of these EMCs, horizontal protection levels (HPLs) are computed for the ambiguity-fixed solutions of real experiments. The HPLs are compared with the horizontal positioning errors (HPEs) and the horizontal ALs (HALs). Using the sequential exclusion algorithm developed for the ambiguity resolution in this contribution, the full ambiguity resolution can be achieved in around 100% and 95% of the time for the open-sky and the suburban scenarios, respectively. The corresponding HPLs of the ambiguity-fixed solutions are at the sub-dm to dm-level for both scenarios, and all the valid ambiguity-fixed HPLs are below a HAL of 0.5 m. For the suburban scenario with more complicated multipath environments, the HPLs increase by considering extra biases to account for multipath under a certain elevation threshold. In complicated multipath environments, when this elevation threshold is set to 30 degrees, the availability of the ambiguity-fixed solutions could decrease to below 50% for applications requiring HAL as low as 0.1 m.
Highlights
The real-time kinematic (RTK) positioning technique is a popular Global Navigation Satellite System (GNSS) based positioning technique
The rover receiver in the test of the suburban scenario is surrounded by metal infrastructure and trees as shown in the middle and right panels of Figure 1, integrity monitoring of the RTK positioning in more challenging environments, e.g., urban areas, and in kinematic mode are of interest for road transport users
Applying these weighting models, the overbounding mean and standard deviations are determined for the weighted between-receiver observations under the open-sky and suburban scenarios based on the overbounding cumulative distribution function (CDF)
Summary
The real-time kinematic (RTK) positioning technique is a popular Global Navigation Satellite System (GNSS) based positioning technique It is substantially different from the precise point positioning (PPP) technique that typically requires a long convergence time of tens of minutes [1,2,3], because the RTK positioning technique removes or mitigates observation errors such as clocks, hardware biases, and a large part of the spatially correlated errors such as the atmospheric delays. This enables ambiguity resolution within a short time. They could vary strongly with the measurement environments, for instance in urban areas, and may hamper successful ambiguity resolution and bias the positioning results
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.