Relativistic modeling of atmospheric occultations with time transfer functions

TL;DR

This paper introduces a covariant relativistic method using optical spacetime metrics and time transfer functions to accurately model atmospheric occultation data, accounting for refractivity and medium motion.

Contribution

It develops an analytical framework for time/frequency transfer modeling during atmospheric occultations using relativistic tools, extending previous non-covariant approaches.

Findings

Provides integral form of time transfer function up to any post-Minkowskian order.

Derives explicit analytical expressions at first post-Minkowskian order.

Assesses accuracy by comparing analytical results with numerical integration.

Abstract

Context: Occultation experiments represent unique opportunities for probing remotely physical properties of atmospheres. The data processing requires one to properly account for refractivity while modeling the time/frequency transfers of an electromagnetic signal. On theoretical grounds, little work have been done concerning the elaboration of a covariant approach for modeling occultation data. Aims: We present an original method allowing one to derive up to the appropriate order fully analytical expressions for the covariant description of time/frequency transfers during an atmospheric occultation experiment. Methods: We make use of two independent powerful relativistic theoretical tools, namely the optical spacetime metric, and the time transfer functions formalism. The first one allows us to consider refractivity as spacetime curvature while the second one is used to determine the time/frequency transfers occurring in a curved spacetime. Results: We provide the integral form of the time transfer function up to any post-Minkowskian order. We specify the discussion to a stationary optical spacetime describing an occultation by a steady rotating and spherically symmetric atmosphere. Explicit analytical expressions for the time/frequency transfers are provided at the first post-Minkowskian order and their accuracy is assessed by comparing them to results of a numerical integration of the equations for optical rays. Conclusions: The method accurately describes vertical temperature gradients and properly accounts for light-dragging effect due to the motion of the optical medium. It can be pushed further in order to derive the explicit form of the time transfer function at higher order and beyond the spherical symmetry assumption.