TY - JOUR
T1 - Systematic effects in LOD from SLR observations
AU - Bloßfeld, Mathis
AU - Gerstl, Michael
AU - Hugentobler, Urs
AU - Angermann, Detlef
AU - Müller, Horst
N1 - Funding Information:
This work was funded as part of the research group ‘ Earth rotation and global dynamic processes ’ ( FOR584 ) by the German Research Foundation DFG . The authors want to thank the ILRS ( Pearlman et al., 2002 ) for providing the observational data. The authors also want to thank the three anonymous reviewers and the editor P. Willis for their helpful and very constructive comments.
PY - 2014/9/15
Y1 - 2014/9/15
N2 - Beside the estimation of station coordinates and the Earth's gravity field, laser ranging observations to near-Earth satellites can be used to determine the rotation of the Earth. One parameter of this rotation is ΔLOD (excess Length Of Day) which describes the excess revolution time of the Earth w.r.t. 86,400 s. Due to correlations among the different parameter groups, it is difficult to obtain reliable estimates for all parameters. In the official ΔLOD products of the International Earth Rotation and Reference Systems Service (IERS), the ΔLOD information determined from laser ranging observations is excluded from the processing. In this paper, we study the existing correlations between ΔLOD, the orbital node Ω, the even zonal gravity field coefficients, cross-track empirical accelerations and relativistic accelerations caused by the Lense-Thirring and deSitter effect in detail using first order Gaussian perturbation equations. We found discrepancies due to different a priories by using different gravity field models of up to 1.0ms for polar orbits at an altitude of 500 km and up to 40.0ms, if the gravity field coefficients are estimated using only observations to LAGEOS 1. If observations to LAGEOS 2 are included, reliable ΔLOD estimates can be achieved. Nevertheless, an impact of the a priori gravity field even on the multi-satellite ΔLOD estimates can be clearly identified. Furthermore, we investigate the effect of empirical cross-track accelerations and the effect of relativistic accelerations of near-Earth satellites on ΔLOD. A total effect of 0.0088 ms is caused by not modeled Lense-Thirring and deSitter terms. The partial derivatives of these accelerations w.r.t. the position and velocity of the satellite cause very small variations (0.1μs) on ΔLOD.
AB - Beside the estimation of station coordinates and the Earth's gravity field, laser ranging observations to near-Earth satellites can be used to determine the rotation of the Earth. One parameter of this rotation is ΔLOD (excess Length Of Day) which describes the excess revolution time of the Earth w.r.t. 86,400 s. Due to correlations among the different parameter groups, it is difficult to obtain reliable estimates for all parameters. In the official ΔLOD products of the International Earth Rotation and Reference Systems Service (IERS), the ΔLOD information determined from laser ranging observations is excluded from the processing. In this paper, we study the existing correlations between ΔLOD, the orbital node Ω, the even zonal gravity field coefficients, cross-track empirical accelerations and relativistic accelerations caused by the Lense-Thirring and deSitter effect in detail using first order Gaussian perturbation equations. We found discrepancies due to different a priories by using different gravity field models of up to 1.0ms for polar orbits at an altitude of 500 km and up to 40.0ms, if the gravity field coefficients are estimated using only observations to LAGEOS 1. If observations to LAGEOS 2 are included, reliable ΔLOD estimates can be achieved. Nevertheless, an impact of the a priori gravity field even on the multi-satellite ΔLOD estimates can be clearly identified. Furthermore, we investigate the effect of empirical cross-track accelerations and the effect of relativistic accelerations of near-Earth satellites on ΔLOD. A total effect of 0.0088 ms is caused by not modeled Lense-Thirring and deSitter terms. The partial derivatives of these accelerations w.r.t. the position and velocity of the satellite cause very small variations (0.1μs) on ΔLOD.
KW - General Relativity
KW - LAGEOS
KW - LOD
KW - Lense-Thirring
KW - SLR
UR - http://www.scopus.com/inward/record.url?scp=84905442080&partnerID=8YFLogxK
U2 - 10.1016/j.asr.2014.06.009
DO - 10.1016/j.asr.2014.06.009
M3 - Article
AN - SCOPUS:84905442080
SN - 0273-1177
VL - 54
SP - 1049
EP - 1063
JO - Advances in Space Research
JF - Advances in Space Research
IS - 6
ER -