Resolving VLBI correlator ambiguity in the time delay model improves precision of geodetic measurements

TL;DR

This paper addresses the correction of VLBI delay models due to epoch transition, improving the precision of geodetic measurements by resolving correlator ambiguities and modeling uncertainties.

Contribution

It introduces a detailed correction method for VLBI delay models based on Lorentz transformation, enhancing consistency and accuracy in geodetic VLBI data analysis.

Findings

Correction reduces model inconsistency up to 6 ps.

Modeling the signal arrival time uncertainty improves delay accuracy.

Essential for future broadband VLBI geodetic observations.

Abstract

The modern Very Long Baseline Interferometry (VLBI) relativistic delay model, as documented in the IERS Conventions refers to the time epoch when the signal passes one of two stations of an interferometer baseline (selected arbitrarily from the pair of stations and called the 'reference station', or 'station 1'). This model consists of the previous correlation procedure used before the year 2002. However, since 2002 a new correlation procedure that produces the VLBI group delays referring to the time epoch of signal passage at the geocenter has been used. A corresponding correction to the conventional VLBI model delay has to be introduced. However, this correction has not been thoroughly presented in peer reviewed journals, and different approaches are used at the correlators to calculate the final group delays officially published in the IVS database. This may cause an inconsistency up to 6 ps for ground-based VLBI experiments between the group delay obtained by the correlator and the geometrical model delay from the IERS Conventions used in data analysis software. Moreover, a miscalculation of the signal arrival moment to the 'reference station' could result a larger modelling error (up to 50 ps). The paper presents the justification of the correction due to transition between two epochs elaborated from the Lorentz transformation, and the approach to model the uncertainty of the calculation of the signal arrival moment. The both changes are particularly essential for upcoming broadband technology geodetic VLBI observations.