Water vapour radiometry in geodetic very long baseline interferometry telescopes: assessed through simulations
Journal article, 2021

The accuracy of geodetic Very Long Baseline Interferometry (VLBI) is affected by water vapour in the atmosphere in terms of variations in the signal propagation delay at the different stations. This “wet” delay may be estimated directly from the VLBI data, as well as from independent instruments, such as collocated microwave radiometers. Rather than having stand-alone microwave radiometers we have, through simulations, evaluated the possibility to use radiometric data from the VLBI receiver in the VGOS telescopes at the Onsala Space Observatory. The advantage is that the emission from water vapour, as sensed by the radiometer, originates from the same atmospheric volume that delays the VLBI signal from the extra-galactic object. We use simulations of the sky brightness temperature and the wet delay together with an assumption of a root-mean-square (rms) noise of the receiver of 1 K, and observations evenly spread between elevation angles of 10∘–90∘. This results in an rms error of the estimated equivalent zenith wet delay of the order of 3 mm for a one frequency algorithm, used under cloud free conditions, and 4 mm for a two frequency algorithm, used during conditions with liquid water clouds. The results exclude rainy conditions when the method does not work. These errors are reduced by a factor of 3 if the receiver error is 0.1 K meaning that the receivers’ measurements of the sky brightness temperature is the main error source. We study the impact of ground-noise pickup by using a model of an existing wideband feed. Taking the algorithm uncertainty and the ground noise pickup into account we conclude that the method presented will be useful as an independent estimate of the wet delay to assess the quality of the wet delays and linear horizontal gradients estimated from the VLBI data themselves.

Geodetic VLBI

Microwave radiometry

VGOS

Author

Peter Forkman

Chalmers, Space, Earth and Environment, Microwave and Optical Remote Sensing

Jonas Flygare

Chalmers, Space, Earth and Environment, Onsala Space Observatory

Gunnar Elgered

Chalmers, Space, Earth and Environment, Microwave and Optical Remote Sensing

Journal of Geodesy

0949-7714 (ISSN) 1432-1394 (eISSN)

Vol. 95 11 117

Subject Categories

Probability Theory and Statistics

Control Engineering

Signal Processing

DOI

10.1007/s00190-021-01571-z

Related datasets

Simulated microwave propagation delays and atmospheric sky brightness temperatures in the frequency range 14–40 GHz at the Onsala Space Observatory [dataset]

DOI: 10.5878/31bx-v871 ID: 2021-243

More information

Latest update

12/5/2022