TY - JOUR
T1 - Resilient Pseudorange Error Prediction and Correction for GNSS Positioning in Urban Areas
AU - Chen, Wu
AU - Sun, Rui
AU - Fu, Linxia
AU - Cheng, Qi
AU - Chiang, Kai Wei
N1 - Funding Information:
This work was supported in part by the National Natural Science Foundation of China under Grant 42222401, Grant 41974033, and Grant 42174025; in part by the Natural Science Foundation of Jiangsu Province under Grant BK20211596; in part by the University Grants Committee of Hong Kong under the Scheme Research Impact Fund under Grant R5009-21; and in part by the Research Institute of Land and System, Hong Kong Polytechnic University.
Publisher Copyright:
© 2014 IEEE.
PY - 2023/6/1
Y1 - 2023/6/1
N2 - Positioning, navigation, and timing (PNT) is essential for Internet of Things (IoT) communications and location-based services. Although global navigation satellite system (GNSS) can provide accurate PNT in open areas, obtaining reliable PNT is still a considerable technical challenge in complex urban environments. This is because the GNSS signals are more likely to be affected by multipath interference and nonline of sight (NLOS) reception issues arising from the obstructions and reflections in built environments. These introduce range measurement errors that degrade the GNSS positioning accuracy. This article proposes two resilient pseudorange error prediction and correction strategies to improve the GNSS positioning accuracy in urban environments. In particular, considering the carrier-to-noise density ( C/N textsubscript 0), satellite elevation angle, and local positional information, the random forest-based pseudorange error prediction and correction models are constructed in two variations, including: 1) the point-based correction (PBC) and 2) the grid-based correction (GBC). The final improved positioning solution is then calculated by using the least square method (LSM) of the corrected pseudoranges. Kinematic test results in urban environments show that both variations of the proposed model can improve the positioning accuracy by 42.9% and 40.8% in horizontal, and by 60.1% and 63.3% in 3-D, respectively, compared to the positioning results obtained by the traditional method without pseudorange error corrections. The improvements are 41.1% and 38.9% in horizontal, and 45.7% and 50.0% in 3-D, respectively, compared with traditional elevation angle weighting method.
AB - Positioning, navigation, and timing (PNT) is essential for Internet of Things (IoT) communications and location-based services. Although global navigation satellite system (GNSS) can provide accurate PNT in open areas, obtaining reliable PNT is still a considerable technical challenge in complex urban environments. This is because the GNSS signals are more likely to be affected by multipath interference and nonline of sight (NLOS) reception issues arising from the obstructions and reflections in built environments. These introduce range measurement errors that degrade the GNSS positioning accuracy. This article proposes two resilient pseudorange error prediction and correction strategies to improve the GNSS positioning accuracy in urban environments. In particular, considering the carrier-to-noise density ( C/N textsubscript 0), satellite elevation angle, and local positional information, the random forest-based pseudorange error prediction and correction models are constructed in two variations, including: 1) the point-based correction (PBC) and 2) the grid-based correction (GBC). The final improved positioning solution is then calculated by using the least square method (LSM) of the corrected pseudoranges. Kinematic test results in urban environments show that both variations of the proposed model can improve the positioning accuracy by 42.9% and 40.8% in horizontal, and by 60.1% and 63.3% in 3-D, respectively, compared to the positioning results obtained by the traditional method without pseudorange error corrections. The improvements are 41.1% and 38.9% in horizontal, and 45.7% and 50.0% in 3-D, respectively, compared with traditional elevation angle weighting method.
KW - Global navigation satellite system (GNSS)
KW - multipath interference (MI)
KW - nonline of sight (NLOS)
KW - pseudo-range error correction
KW - urban navigation
UR - http://www.scopus.com/inward/record.url?scp=85147294468&partnerID=8YFLogxK
U2 - 10.1109/JIOT.2023.3235483
DO - 10.1109/JIOT.2023.3235483
M3 - Journal article
SN - 2327-4662
VL - 10
SP - 9979
EP - 9988
JO - IEEE Internet of Things Journal
JF - IEEE Internet of Things Journal
IS - 11
M1 - 23122814
ER -