VLBI for Gravity Probe B. V. Proper Motion and Parallax of the Guide Star, IM Pegasi

TL;DR

This paper reports precise VLBI measurements of IM Pegasi's proper motion and parallax, providing essential astrometric data to support the Gravity Probe B relativity experiment with minimal systematic errors.

Contribution

The study offers highly accurate VLBI astrometry of IM Pegasi, including proper motion and parallax, with detailed error analysis, supporting the GP-B mission's precision requirements.

Findings

Proper motion measured with ~30% smaller error than goal

Parallax determined with negligible systematic error

Results confirm minimal impact on GP-B relativity tests

Abstract

We present the principal astrometric results of the very-long-baseline interferometry (VLBI) program undertaken in support of the Gravity Probe B (GP-B) relativity mission. VLBI observations of the GP-B guide star, the RS CVn binary IM Pegasi (HR 8703), yielded positions at 35 epochs between 1997 and 2005. We discuss the statistical assumptions behind these results and our methods for estimating the systematic errors. We find the proper motion of IM Peg in an extragalactic reference frame closely related to the International Celestial Reference Frame 2 (ICRF2) to be -20.83 +- 0.03 +- 0.09 mas/yr in right ascension and -27.27 +- 0.03 +- 0.09 mas/yr in declination. For each component the first uncertainty is the statistical standard error and the second is the total standard error (SE) including plausible systematic errors. We also obtain a parallax of 10.37 +- 0.07 mas (distance: 96.4 +- 0.7 pc), for which there is no evidence of any significant contribution of systematic error. Our parameter estimates for the ~25-day-period orbital motion of the stellar radio emission have SEs corresponding to ~0.10 mas on the sky in each coordinate. The total SE of our estimate of IM Peg's proper motion is ~30% smaller than the accuracy goal set by the GP-B project before launch: 0.14 mas/yr for each coordinate of IM Peg's proper motion. Our results ensure that the uncertainty in IM Peg's proper motion makes only a very small contribution to the uncertainty of the GP-B relativity tests.