Decimeter-Level Geolocation Accuracy Updated by a Parametric Tropospheric Model with GF-3
Abstract
:1. Introduction
2. Atmospheric Path Delay
2.1. Simplified Static Zenith Model
2.2. Analytic Approximation Zenith Model
2.3. Integral Zenith Model
2.4. Ionospheric Model
3. Experiments and Results
3.1. Analysis of Accuracy of Different Tropospheric Models
- (1)
- Among the three tropospheric models, the integral model has the highest accuracy, which can reach the millimeter level (Table 1), and its RMSE is the smallest corresponding to the highest stability; the SAAS model has the second highest accuracy and can achieve an accuracy on the centimeter level in practice. The DIFF of the simplified static model is similar to that of the SAAS model in the BJFS IGS station, even though the fitting accuracy is better than the SAAS model in December. However, the experiment in the URUM IGS station proved (shown in Figure 6) that due to the lack of actual meteorological data, the universality of the simplified static model is very poor, and the actual fitting accuracy is far worse than the other two models, which are based on the real meteorological data.
- (2)
- In terms of time, the DIFF and RMSE obviously have seasonal variation characteristics. Due to the high atmospheric water vapor, frequent precipitation, and changeable weather conditions in the summer, the DIFF and RMSE are obviously higher than that in the winter. As illustrated in Figure 3b, the highest RMSE of the integral model is no longer than 20 mm during the 12 months, which is much better than the other two models, verifying its excellent seasonal adaptability.
- (3)
- In the area with less rainfall and less changeable weather, the simplified static model deployed in GF-3 can meet basic requirements; while in other area with complex terrain and changeable weather, there will be a large deviation in fitting path delay, and this model is unsuitable. Replacing the simplified static model with the integral model will increase the positioning accuracy in GF-3.
3.2. Assessment of GF-3’s Absolute Positioning Accuracy Using Different Tropospheric Models
4. Summary and Outlook
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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DIFF_INT | RMSE_INT | DIFF_STATIC | RMSE_STATIC | DIFF_SAAS | RMSE_SAAS | |
---|---|---|---|---|---|---|
Mean | −4.3807 | 10.908 | 67.6934 | 38.4067 | 45.1184 | 26.8379 |
Imaging Mode | Resolution | Date of Imaging | Imaging Region | Incidence Angle | Number of GCPs |
---|---|---|---|---|---|
SL | 1 | 2017.9.6 | Sanhe, China | 29.67 | 6 |
FS2_1 | 10 | 2017.9.6 | Dalian, China | 30.62 | 6 |
FS2_2 | 10 | 2017.7.3 | Songshan, China | 42.3 | 4 |
SS | 25 | 2017.3.19 | Amazonas, Brazil | 24.1 | 4 |
QPS2 | 25 | 2017.1.28 | Songshan, China | 37.31 | 5 |
Mode | No Atmospheric Models (m) | Static Model (m) | SAAS Model (m) | Integral Model (m) | Updated (m) (Integral-Static) |
---|---|---|---|---|---|
FS2_1 | 10.378 | 8.024 | 7.589 | 7.475 | 0.549 |
7.089 | 4.735 | 4.299 | 4.187 | 0.548 | |
5.436 | 3.086 | 2.646 | 2.544 | 0.542 | |
5.672 | 3.317 | 2.882 | 2.758 | 0.559 | |
8.244 | 5.89 | 5.454 | 5.348 | 0.542 | |
6.424 | 4.07 | 3.634 | 3.521 | 0.549 | |
SL | 7.844 | 5.172 | 5.026 | 4.968 | 0.204 |
5.128 | 2.456 | 2.31 | 2.252 | 0.204 | |
4.726 | 2.054 | 1.909 | 1.835 | 0.219 | |
10.805 | 8.132 | 7.987 | 7.924 | 0.208 | |
8.757 | 6.084 | 5.939 | 5.86 | 0.224 | |
5.124 | 2.451 | 2.306 | 2.256 | 0.195 | |
SS0 | 8.738 | 6.237 | 6.076 | 5.776 | 0.462 |
8.564 | 6.063 | 5.903 | 5.612 | 0.451 | |
7.775 | 5.274 | 5.113 | 4.812 | 0.462 | |
3.95 | 1.449 | 1.289 | 0.984 | 0.465 | |
FS2_2 | 5.296 | 2.089 | 1.866 | 1.761 | 0.328 |
8.017 | 4.81 | 4.588 | 4.493 | 0.317 | |
10.644 | 7.437 | 7.213 | 7.139 | 0.298 | |
10.098 | 6.89 | 6.667 | 6.55 | 0.34 | |
QPS2 | 4.243 | 1.347 | 1.086 | 1.068 | 0.279 |
5.771 | 2.877 | 2.613 | 2.603 | 0.274 | |
8.146 | 5.25 | 4.986 | 4.962 | 0.288 | |
7.814 | 4.922 | 4.658 | 4.637 | 0.285 | |
7.003 | 4.108 | 3.844 | 3.824 | 0.284 |
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Wang, W.; Liu, J.; Qiu, X. Decimeter-Level Geolocation Accuracy Updated by a Parametric Tropospheric Model with GF-3. Sensors 2018, 18, 2197. https://doi.org/10.3390/s18072197
Wang W, Liu J, Qiu X. Decimeter-Level Geolocation Accuracy Updated by a Parametric Tropospheric Model with GF-3. Sensors. 2018; 18(7):2197. https://doi.org/10.3390/s18072197
Chicago/Turabian StyleWang, Wentao, Jiayin Liu, and Xiaolan Qiu. 2018. "Decimeter-Level Geolocation Accuracy Updated by a Parametric Tropospheric Model with GF-3" Sensors 18, no. 7: 2197. https://doi.org/10.3390/s18072197
APA StyleWang, W., Liu, J., & Qiu, X. (2018). Decimeter-Level Geolocation Accuracy Updated by a Parametric Tropospheric Model with GF-3. Sensors, 18(7), 2197. https://doi.org/10.3390/s18072197