Numerical Data-Processing Simulation of Microarcsecond Classical and Relativistic Effects in Space Astrometry

Abstract

The accuracy of astrometric observations conducted via a space-borne optical interferometer orbiting the Earth is expected to approach a few microarcseconds. Data processing of such extremely high-precision measurements requires access to a rigorous relativistic model of light ray propagation developed in the framework of General Relativity. The data processing of the space interferometric observations must rely upon the theory of general-relativistic transformations among the spacecraft, geocentric, and solar barycentric reference systems, allowing unique and unambiguous interpretation of the stellar aberration and parallax effects. The algorithm used also must include physically adequate treatment of the relativistic effect of light deflection caused by the spherically symmetric (monopole-dependent) part of the gravitational field of the Sun and planets as well as the quadrupole- and spin-dependent counterparts of it. In some cases the gravitomagnetic field induced by the translational motion of the Sun and planets also should be taken into account for unambiguous prediction of the light ray deflection angle. In this paper, the authors describe the corresponding software program that takes into account all classical (proper motion, parallax, etc.) and relativistic (aberration, deflection of light) effects up to the microarcsecond threshold. They demonstrate using numerical simulations how observations of stars and/or quasars conducted on board a space optical interferometer orbiting the Earth can be processed and disentangled. For simulation purposes, the spacecraft orbital parameters and the telescope optical system characteristics are similar to those in the Hipparcos mission. Numerical data analysis verifies that the relativistic algorithm chosen for data processing is convergent and can be used to determine astronomical coordinates and proper motions of stars with the required microarcsecond precision.

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Document Details

Document Type
Technical Report
Publication Date
Mar 01, 2000
Accession Number
ADA435889

Entities

People

  • E. I. Yagudina
  • L. I. Yagudin
  • M. V. Vasilyev
  • N. V. Shuygina
  • Sergei M. Kopeikin

Tags

DTIC Thesaurus Topics

  • Accuracy
  • Artificial Satellites
  • Astronomy
  • Catalogs
  • Computational Science
  • Coordinate Systems
  • Data Processing
  • Data Reduction
  • Geosynchronous Satellites
  • Information Processing
  • Observation
  • Observatories
  • Observers
  • Optical Interferometers
  • Radial Velocity
  • Simulations
  • Star Position

Fields of Study

  • Physics

Readers

  • Astronomy and Astrophysics.
  • Astronomy/Astrophysics
  • Calculus or Mathematical Analysis

Technology Areas

  • Space
  • Space - Orbital Debris