Title :
Navigation and timing accuracy at the 30 centimeter and subnanosecond level
Author :
Ashby, Neil ; Allan, David W.
Author_Institution :
Dept. of Phys., Colorado Univ., Boulder, CO, USA
Abstract :
Clocks with accuracies exceeding 1×10-13 can now be placed in orbit. Here we carry out a worst case systematic error analysis of ground-based Doppler observations of signals from such a satellite to ascertain how well all the SV orbital parameters can be determined. The classical Keplerian relationship, T2=4π 2a3/GM, provides a way for accurate determination of the semi-major axis, a, through measurement of the orbital period, T, of a SV-borne clock. Simple calculations show that an accuracy of 1×10-13 translates to an uncertainty in the length of the radius vector of 7.2 cm. To achieve such accuracy, a drag-free system is needed in the satellite to satisfy the free-fall orbital conditions. Because of the potential importance of such accuracy, the purpose of this paper to consider all relevant relativistic effects, and other important error terms
Keywords :
clocks; error analysis; measurement errors; satellite navigation; time measurement; timing; SV orbital parameters; SV-borne clock; drag-free system; error terms; free-fall orbital conditions; ground-based Doppler observations; navigation accuracy; relativistic effects; satellite clock; timing accuracy; worst case error analysis; Accuracy; Clocks; Earth; Error analysis; Extraterrestrial measurements; Global Positioning System; Navigation; Physics; Satellite ground stations; Timing;
Conference_Titel :
Frequency Control Symposium, 1996. 50th., Proceedings of the 1996 IEEE International.
Conference_Location :
Honolulu, HI
Print_ISBN :
0-7803-3309-8
DOI :
10.1109/FREQ.1996.560311
