Add to ORKGOne of the main goals of the LAGEOS satellite mission is the detection of regional geotectonic movements. A parametric study with the intention to obtain the optimal baseline precision from dynamic solutions of laser ranging to LAGEOS is presented. The varied parameters are: length of reduced arc, number of tracking stations, data noise and rate, biases, refraction errors, system efficiency, gravity model errors in the value of GM. The baseline precisions are 1-10 cm depending upon the set of parameters adopted. General principles obtained are also presented
Numerous active Low Earth Orbiters (LEOs) are equipped with laser retroreflectors used for the Satel...
Satellite laser ranging provided for decades the most precise measurement of positions and velocitie...
Laser ranging is expected to help unlock the mysteries of the earthquake phenomenon by producing uni...
Satellite laser ranging has matured over the last decade into one of the essential space geodesy tec...
As part of the Crustal Dynamics Project, an experiment was performed to verify the ability of Satell...
Laser systems deployed in satellite tracking were upgraded to accuracy levels where biases from syst...
Recent improvements in the accuracy of modern satellite laser ranging (SLR) systems are strengthened...
Non-Bayesian statistics were used in simulation studies centered around laser range observations to ...
The stations of the Global Laser Tracking Network have significantly contributed to the measurement ...
A network of satellite laser ranging (SLR) tracking systems with continuously improving accuracies i...
Simultaneous Range Differences (SRDs) to Lageos are obtained by dividing the observing stations into...
Near real-time Lageos laser ranging data are analyzed in terms of range bias, time bias, and interna...
The possibility of improving the accuracy of geodetic results by use of simultaneously observed rang...
Measurement of crustal motion in the western United States and other tectonically active regions mak...
The technique of range differencing with Lageos ranges to obtain more accurate estimates of baseline...
Numerous active Low Earth Orbiters (LEOs) are equipped with laser retroreflectors used for the Satel...
Satellite laser ranging provided for decades the most precise measurement of positions and velocitie...
Laser ranging is expected to help unlock the mysteries of the earthquake phenomenon by producing uni...
Satellite laser ranging has matured over the last decade into one of the essential space geodesy tec...
As part of the Crustal Dynamics Project, an experiment was performed to verify the ability of Satell...
Laser systems deployed in satellite tracking were upgraded to accuracy levels where biases from syst...
Recent improvements in the accuracy of modern satellite laser ranging (SLR) systems are strengthened...
Non-Bayesian statistics were used in simulation studies centered around laser range observations to ...
The stations of the Global Laser Tracking Network have significantly contributed to the measurement ...
A network of satellite laser ranging (SLR) tracking systems with continuously improving accuracies i...
Simultaneous Range Differences (SRDs) to Lageos are obtained by dividing the observing stations into...
Near real-time Lageos laser ranging data are analyzed in terms of range bias, time bias, and interna...
The possibility of improving the accuracy of geodetic results by use of simultaneously observed rang...
Measurement of crustal motion in the western United States and other tectonically active regions mak...
The technique of range differencing with Lageos ranges to obtain more accurate estimates of baseline...
Numerous active Low Earth Orbiters (LEOs) are equipped with laser retroreflectors used for the Satel...
Satellite laser ranging provided for decades the most precise measurement of positions and velocitie...
Laser ranging is expected to help unlock the mysteries of the earthquake phenomenon by producing uni...