Relativistic Positioning Systems: Numerical Simulations
Abstract
The motion of satellite constellations similar to GPS and Galileo is numerically simulated and, then, the region where bifurcation (double positioning) occurs is appropriately represented. In the cases of double positioning, the true location may be found using additional information (angles or times). The zone where the Jacobian, J, of the transformation from inertial to emission coordinates vanishes is also represented and interpreted. It is shown that the uncertainties in the satellite world lines produce positioning errors, which depend on the value of |J|. The smaller this quantity the greater the expected positioning errors. Among all the available 4-tuples of satellites, the most appropriate one -for a given location- should minimize positioning errors (large enough |J| values) avoiding bifurcation. Our study is particularly important to locate objects which are far away from Earth, e.g., satellites.
Cite
@article{arxiv.1404.1000,
title = {Relativistic Positioning Systems: Numerical Simulations},
author = {Neus Puchades and Diego Sáez},
journal= {arXiv preprint arXiv:1404.1000},
year = {2014}
}
Comments
10 pages, 4 figures, published in ACTA FUTURA/ACT/ESA