Observable-based reformulation of time-delay interferometry

TL;DR

This paper introduces an observable-based reformulation of time-delay interferometry (TDI) for spaceborne gravitational-wave detectors, integrating onboard delay measurements directly into the TDI process, eliminating the need for prior calibration and clock synchronization.

Contribution

It presents a novel TDI processing scheme that incorporates onboard delay measurements directly, simplifying calibration and synchronization requirements.

Findings

Eliminates the need for prior interspacecraft clock synchronization.

Automatically corrects for relative clock drifts in postprocessing.

Integrates onboard delay measurements into TDI, enhancing conceptual clarity.

Abstract

Spaceborne gravitational-wave observatories utilize a postprocessing technique known as time-delay interferometry (TDI) to reduce the otherwise overwhelming laser frequency noise by around 8 orders of magnitude. While, in its traditional form, TDI considers the spacecraft as point masses, recent studies have enhanced this simplified scenario by incorporating more realistic metrology chain models, which include onboard optical, electronic, and digital delays. These studies have updated the TDI algorithm to include onboard delays obtained from prelaunch and in-flight calibrations. Conversely, the processing scheme presented in this article treats onboard delays as an integral part of the TDI combinations: instead of having separate calibration stages, it directly expresses all delays appearing in the algorithm in terms of onboard measurements, especially pseudo-random-noise ranging (PRNR) measurements. The only onboard delays that need to be corrected in our processing scheme are PRNR delays in the digital domain, which are determined by commandable digital-signal-processing parameters; hence, they can be easily managed in postprocessing. Furthermore, our processing scheme does not require a prior interspacecraft clock synchronization, and it automatically corrects for potential relative drifts between the clocks driving local phase measurement systems. The proposed observable-based formulation closely relates TDI to the actual metrology system, and it clearly outlines how to manage onboard measurements in postprocessing. Hence, it is expected to lead to fundamental advancements in TDI, providing both conceptual completeness and unique practical benefits.