Performance Evaluation of CentiSpace Navigation Augmentation Experiment Satellites
Abstract
:1. Introduction
2. Performance Evaluation Methods
2.1. GNSS Receiver Evaluation Methods
2.1.1. Integrity of Raw Measurements
2.1.2. Variation of C/N0 with Co-Frequency Self-Interference
2.1.3. Multipath Error
2.1.4. Observation Noise Error
2.1.5. Orbit Determination
2.2. Augmentation Signal Evaluation Methods
2.2.1. Quality Analysis in Modulation Domain
2.2.2. Quality Analysis in Correlation Domain
- (1)
- Correlation loss
- (2)
- Zero-Crossing Bias of S-Curve
3. Performance of Experiment Satellite
3.1. Performance of GNSS Receiver
3.1.1. Integrity of Raw Measurements
3.1.2. Variation of C/N0 with Co-Frequency Self-Interference
3.1.3. Multipath Error
3.1.4. Observation Noise Error
3.1.5. Orbit Determination
3.2. Performance of Navigation Augmentation Signal
3.2.1. Quality analysis in Modulation Domain
3.2.2. Quality Analysis in Correlation Domain
- (1)
- Correlation loss
- (2)
- Zero-Crossing Bias of S-Curve
4. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Conflicts of Interest
References
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Signal | Frequency | Modulation | Code Rate |
---|---|---|---|
FA | 157X.XX | BPSK | 2.046 MHz |
FB | 117X.XX | BPSK | 2.046 MHz |
Normal | Self-Interference | ||||
---|---|---|---|---|---|
Signal | PRNoise (mm) | CPNoise (mm) | PRNoise (mm) | CPNoise (mm) | |
BDS | B1C | 64.73 | 1.54 | 65.02 | 1.49 |
B2a | 43.48 | 1.83 | 46.91 | 1.92 |
Scheme | Model |
---|---|
Raw measurement | Dual-frequency combination |
Elevation | >10° |
Ephemeris | Precise ephemeris (IGS) |
Parameter estimation | Extended Kalman filter |
LEO dynamics model | Reduced-dynamic approach |
R (cm) | T (cm) | N (cm) | 3D (cm) | |
---|---|---|---|---|
BDS | 1.05 | 2.60 | 1.84 | 3.35 |
GNSS | 0.89 | 2.35 | 1.26 | 2.82 |
Signal | I/Q Phase Relation | Correlation Loss | S-Curve Bias (1 Chip) |
---|---|---|---|
FA/FB | 90° | 0.3 dB | 0.3 ns |
Signal | High Elevation | Medium Elevation | Low Elevation |
---|---|---|---|
FA | 0.38° | 0.37° | 1.69° |
FB | 0.32° | 0.35° | 1.45° |
Signal | High Elevation | Medium Elevation | Low Elevation | |
---|---|---|---|---|
FA | In-phase | 0.25 dB | 0.26 dB | 0.34 dB |
Quadrature | 0.23 dB | 0.29 dB | 0.31 dB | |
FB | In-phase | 0.17 dB | 0.19 dB | 0.29 dB |
Quadrature | 0.20 dB | 0.22 dB | 0.25 dB |
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Chen, L.; Lv, F.; Yang, Q.; Xiong, T.; Liu, Y.; Yang, Y.; Pan, H.; Wang, S.; Liu, M.; He, R.; et al. Performance Evaluation of CentiSpace Navigation Augmentation Experiment Satellites. Sensors 2023, 23, 5704. https://doi.org/10.3390/s23125704
Chen L, Lv F, Yang Q, Xiong T, Liu Y, Yang Y, Pan H, Wang S, Liu M, He R, et al. Performance Evaluation of CentiSpace Navigation Augmentation Experiment Satellites. Sensors. 2023; 23(12):5704. https://doi.org/10.3390/s23125704
Chicago/Turabian StyleChen, Lin, Feiren Lv, Qiangwen Yang, Tulin Xiong, Yuqi Liu, Yi Yang, Hongchen Pan, Suisheng Wang, Min Liu, Renlun He, and et al. 2023. "Performance Evaluation of CentiSpace Navigation Augmentation Experiment Satellites" Sensors 23, no. 12: 5704. https://doi.org/10.3390/s23125704
APA StyleChen, L., Lv, F., Yang, Q., Xiong, T., Liu, Y., Yang, Y., Pan, H., Wang, S., Liu, M., He, R., Zheng, D., Zhang, L., & Jin, Y. (2023). Performance Evaluation of CentiSpace Navigation Augmentation Experiment Satellites. Sensors, 23(12), 5704. https://doi.org/10.3390/s23125704