TY - GEN
T1 - On the Determination of the Specular Reflection Point in GNSS Reflectometry
AU - Juang, Jyh Ching
N1 - Funding Information:
The research is supported by the Ministry of Science and Technology, Taiwan under grant MOST 110-2119-M-008-003-.
Publisher Copyright:
© 2021 IEEE.
PY - 2021
Y1 - 2021
N2 - The use of GNSS (Global Navigation Satellite System) for remote sensing and environmental monitoring has been an important research topic in recent years due to the omnipresence and performance of GNSS signals. In particular, the use of GNSS reflectometry (GNSS-R) in probing sea surface height, wind velocity, salinity, soil moisture, roughness, and snow depth has been realized in several space mission. The TRITON mission from Taiwan is one GNSS-R mission under planning. A key step in onboard GNSS-R signal processing is the determination of the specular reflection point. With the information of the specular reflection point, the GNSS-R processing unit can estimate the propagation delay between the direct line-of-sight signal and the reflected signal so that the correlation processing within the GNSS-R processing unit can be appropriately adjusted. In prior work, the specular reflection point on the spherical Earth is computed by solving a quartic polynomial equation. To deal with ellipsoidal Earth model, an iterative algorithm is often used. To our knowledge, an explicit characterization of the specular reflection point on the ellipsoidal Earth has not been developed. In this paper, an analytic approach is developed to determine the specular reflection point on the ellipsoidal Earth. By exploiting the Snells law and minimal distance property, a sextic polynomial equation is obtained that characterizes the specular reflection point. This leads to an analytic approach in solving the specular reflection point that is not subject to initial condition uncertainty and iteration complexity. To account for the error in the determination of the specular reflection point, two metrics are proposed to depict the dilution of precision with respect to errors of the positions of the transmitter and receiver. Moreover, error ellipse on the surface can be established for the assessment of the accuracy in the determination of the specular reflection point. The results can be used on-board a spaceborne mission with bounded computational load and assured quality.
AB - The use of GNSS (Global Navigation Satellite System) for remote sensing and environmental monitoring has been an important research topic in recent years due to the omnipresence and performance of GNSS signals. In particular, the use of GNSS reflectometry (GNSS-R) in probing sea surface height, wind velocity, salinity, soil moisture, roughness, and snow depth has been realized in several space mission. The TRITON mission from Taiwan is one GNSS-R mission under planning. A key step in onboard GNSS-R signal processing is the determination of the specular reflection point. With the information of the specular reflection point, the GNSS-R processing unit can estimate the propagation delay between the direct line-of-sight signal and the reflected signal so that the correlation processing within the GNSS-R processing unit can be appropriately adjusted. In prior work, the specular reflection point on the spherical Earth is computed by solving a quartic polynomial equation. To deal with ellipsoidal Earth model, an iterative algorithm is often used. To our knowledge, an explicit characterization of the specular reflection point on the ellipsoidal Earth has not been developed. In this paper, an analytic approach is developed to determine the specular reflection point on the ellipsoidal Earth. By exploiting the Snells law and minimal distance property, a sextic polynomial equation is obtained that characterizes the specular reflection point. This leads to an analytic approach in solving the specular reflection point that is not subject to initial condition uncertainty and iteration complexity. To account for the error in the determination of the specular reflection point, two metrics are proposed to depict the dilution of precision with respect to errors of the positions of the transmitter and receiver. Moreover, error ellipse on the surface can be established for the assessment of the accuracy in the determination of the specular reflection point. The results can be used on-board a spaceborne mission with bounded computational load and assured quality.
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U2 - 10.1109/GNSSR53802.2021.9617670
DO - 10.1109/GNSSR53802.2021.9617670
M3 - Conference contribution
AN - SCOPUS:85123621116
T3 - IEEE Specialist Meeting on Reflectometry using GNSS and other Signals of Opportunity 2021, GNSS+R 2021 - Proceedings
SP - 86
EP - 89
BT - IEEE Specialist Meeting on Reflectometry using GNSS and other Signals of Opportunity 2021, GNSS+R 2021 - Proceedings
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2021 IEEE Specialist Meeting on Reflectometry using GNSS and other Signals of Opportunity, GNSS+R 2021
Y2 - 14 September 2021 through 17 September 2021
ER -