TY - GEN
T1 - Remote sensing coastal sea level and ocean tide by using reflected GPS Li and L2 observation for integrated GPS receiver
AU - Shen, L. C.
AU - Juang, J. C.
AU - Tsai, C. L.
PY - 2008
Y1 - 2008
N2 - In the paper, a new application and development of a highly integrated GPS receiver with reflected GPS signals for ocean state and sea tide will be described. First, both Right Hand Circular Polarization (RHCP) and Left Hand Circular Polarization (LHCP) antennas are employed so that direct and reflected signals can be acquired simultaneously. The direction of arrival of the signals may be along the reflected signal path or even along the line-of-sight of a particular satellite. The goal of the study is to exploit the carrier phase, Doppler shift, reflectivity of L1/L2 S/No signal-to-noise density ratio components of the reflected signals and direct signals for ocean water and coastal ground object detection with surface. The Sea states are predicted by using Doppler shifts due to surface reflection as a moving surface. During the development and test stage, the digital terrain elevation data and satellite's images has been used and mapped with the integrated software. An integer ambiguity algorithm has also been implemented. The precise point positions for RHCP and LHCP antennas are enhanced and processed by repeating instantaneous ionosphere delay correct model with deriving from L1 and L2 carrier phase and troposphere estimated parameter model. During the development and test stage, the DTED and visual elements of satellite's images has been used and mapped with the integrated software. According to A GPS radio occultations with CHAMP's technology of remote sensing for ocean two-dimensional tide and flow. The three dimensional ocean tide model is predicted by using Doppler shifts due to surface reflection as a moving surface. The each instantaneous moving surface should be exploited by each reflected GPS carrier phase and reflected point. For remote sensing of ocean, landscape, and stream, the accuracies of each reflected altitude are among 10 cm and 30 cm. The accuracies of each reflected area are converged among 2 cm and 10 cm.
AB - In the paper, a new application and development of a highly integrated GPS receiver with reflected GPS signals for ocean state and sea tide will be described. First, both Right Hand Circular Polarization (RHCP) and Left Hand Circular Polarization (LHCP) antennas are employed so that direct and reflected signals can be acquired simultaneously. The direction of arrival of the signals may be along the reflected signal path or even along the line-of-sight of a particular satellite. The goal of the study is to exploit the carrier phase, Doppler shift, reflectivity of L1/L2 S/No signal-to-noise density ratio components of the reflected signals and direct signals for ocean water and coastal ground object detection with surface. The Sea states are predicted by using Doppler shifts due to surface reflection as a moving surface. During the development and test stage, the digital terrain elevation data and satellite's images has been used and mapped with the integrated software. An integer ambiguity algorithm has also been implemented. The precise point positions for RHCP and LHCP antennas are enhanced and processed by repeating instantaneous ionosphere delay correct model with deriving from L1 and L2 carrier phase and troposphere estimated parameter model. During the development and test stage, the DTED and visual elements of satellite's images has been used and mapped with the integrated software. According to A GPS radio occultations with CHAMP's technology of remote sensing for ocean two-dimensional tide and flow. The three dimensional ocean tide model is predicted by using Doppler shifts due to surface reflection as a moving surface. The each instantaneous moving surface should be exploited by each reflected GPS carrier phase and reflected point. For remote sensing of ocean, landscape, and stream, the accuracies of each reflected altitude are among 10 cm and 30 cm. The accuracies of each reflected area are converged among 2 cm and 10 cm.
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U2 - 10.1109/OCEANSKOBE.2008.4530901
DO - 10.1109/OCEANSKOBE.2008.4530901
M3 - Conference contribution
AN - SCOPUS:51449105867
SN - 9781424421268
T3 - OCEANS'08 MTS/IEEE Kobe-Techno-Ocean'08 - Voyage toward the Future, OTO'08
BT - OCEANS'08 MTS/IEEE Kobe-Techno-Ocean'08 - Voyage toward the Future, OTO'08
T2 - OCEANS'08 MTS/IEEE Kobe-Techno-Ocean'08 - Voyage toward the Future, OTO'08
Y2 - 9 April 2008 through 11 April 2008
ER -