Abstract
High-precision positioning with low-cost global navigation satellite systems (GNSS) in urban environments remains a significant challenge due to the significant multipath effects, non-line-of-sight (NLOS) errors, as well as poor satellite visibility and geometry. A GNSS system is typically implemented with a least-square (LS) or a Kalman-filter (KF) estimator, and a proper weight scheme is vital for achieving reliable navigation solutions. The traditional weight schemes are based on the signal-in-space ranging errors (SISRE), elevation and C/N0 values, which would be less effective in urban environments since the observation quality cannot be fully manifested by those values. In this paper, we propose a new multi-feature support vector machine (SVM) signal classifier-based weight scheme for GNSS measurements to improve the kinematic GNSS positioning accuracy in urban environments. The proposed new weight scheme is based on the identification of important features in GNSS data in urban environments and intelligent classification of line-of-sight (LOS) and NLOS signals. To validate the performance of the newly proposed weight scheme, we have implemented it into a real-time single-frequency precise point positioning (SFPPP) system. The dynamic vehicle-based tests with a low-cost single-frequency u-blox M8T GNSS receiver demonstrate that the positioning accuracy using the new weight scheme outperforms the traditional C/N0 based weight model by 65.4% and 85.0% in the horizontal and up direction, and most position error spikes at overcrossing and short tunnels can be eliminated by the new weight scheme compared to the traditional method. It also surpasses the built-in satellite-based augmentation systems (SBAS) solutions of the u-blox M8T and is even better than the built-in real-time-kinematic (RTK) solutions of multi-frequency receivers like the u-blox F9P and Trimble BD982.
Highlights
High-precision positioning with low-cost global navigation satellite systems (GNSS) in urban environments remains a significant challenge
The dynamic vehicle-based tests with a low-cost single-frequency u-blox M8T GNSS receiver demonstrate that the positioning accuracy using the new weight scheme outperforms the traditional
The new weight scheme is based on the identification of important features in GNSS data in urban environments and intelligent classification of LOS/NLOS signals using the support vector machine (SVM) algorithm
Summary
High-precision positioning with low-cost global navigation satellite systems (GNSS) in urban environments remains a significant challenge. The industry demand, is high for many emerging applications, such as autonomous vehicles and intelligent transportation systems. Accurate and reliable solutions have been demonstrated in open sky environments with low-cost GNSS receivers, the positioning accuracy will be greatly degraded in urban environments due to significant multipath effects, non-line-of-sight (NLOS) errors, as well as poor satellite visibility and geometry caused by severe signal blockages [1]. The NLOS signal errors for instance, could be unbounded to become as large as hundreds of meters in some severe circumstances. The effective detection of NLOS signals and subsequent elimination and compensation of NLOS signal effects can significantly improve positioning accuracy in urban environments.
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