INTERNATIONAL COOPERATION AND TECHNOLOGY TRANSFER 
GAIA: global astrometry from space at 10 pas level 
D. Cardio, B. Bucciarelli, M. Gai, M. G. Lattanzi and S. Cesare* 
Astronomical Observatory of Torino 
Strada Osservatorio, 20 - 10025 Pino T.se (To) - Italy 
'Alenia Spazio, C.so Marche, 31 - 10100 Torino - Italy 
Keywords: space instrumentation - astrometry - interferometry - data analysis 
ABSTRACT 
Based on the success of its previous astrometric space mission HIPPARCOS, the European Space Agency 
recommended the study of a cornestone mission named GAIA dedicated to astrometry, with the goal of 10 pas 
astrometric accuracy at magnitude V = 15. GAIA’s direct output will be an extensive network of stellar distances, proper 
motions and positions throughout a significant fraction of the Galaxy, which would lead to important scientific results in 
major astronomy and astrophysics fields. In this paper the mission concept and feasibility study are outlined. Critical 
issues concerning instrumental calibrations versus scientific mission requirements are also addressed. 
1. INTRODUCTION 
GAIA is a preliminary concept for an astrometric mission 
of the European Space Agency (ESA) which should 
provide positions, proper motions, and parallaxes of some 
5 10 7 objects, down to about V=15 mag, with an accuracy 
of better than 10 pas, along with multi-color multi-epoch 
photometry of each object (Lindegren & Perrymann, 1996) 
GAIA performs global astrometry, i.e. the entire celestial 
sphere is observed, and the results refer to a unique and 
well-defined reference system. This implies the 
determination of absolute parallaxes and of a dense and 
undistorted optical reference frame for positions and 
proper motions. 
From a technical viewpoint, the main characteristics of the 
GAIA mission concept can be summarized as follow: 
■ geostationary orbit or libration orbit around the 
Lagrangian point L2 in the Sun-Earth system; 
■ continuous scanning of the celestial sphere along 
instantaneous great circles, with simultaneous 
observations of two sky regions separated by a wide 
basic angle (54°); 
■ wide field of view (FOV ~1 deg 2 ) and high angular 
resolution in the scanning direction; 
■ the spacecraft rotation and precession, along with the 
orbit of Earth around the Sun, combine to give 
complete sky coverage; 
■ each star is observed several times during the 
mission allowing a complete determinations of the 
astrometric stellar parameters. All the parameters are 
in principle determined in a single, global adjustment 
procedure; 
The satellite could be launched in 2009, with vectors 
Arianne 5 in a dual launch, and the expected nominal 
mission lifetime is 5 years. 
1.2 General scientific objectives 
GAIA will provide an enormous quantity of data of 
extremely accurate astrometry and photometry from which 
all branches of astrophysics will benefit, in particular in the 
field of the physics and evolution of individual stars and of 
the whole Galaxy. This process has began already with 
the results of the ESA astrometry mission HIPPARCOS 
launched in June ’89. However, while HIPPARCOS could 
probe less than 0.1 % of the volume of the Galaxy by 
direct distance measurement, GAIA will encompass a 
large fraction of the Milky Way system within its parallax 
horizon, including much of the Galactic halo, and even 
touching on the nearest companion galaxies such us the 
Magellanic Clouds. 
We can summarize the scientific objectives as follow: 
■ establishment of an optical reference system by 
means of an accurate set of reference directions for 
dynamical interpretations of the motion of the Earth 
and other planets and of the Milky Way; 
■ physics and evolution of individual stars; 
■ dynamics of stellar systems; 
■ formation and evolution of the Galaxy; 
■ distance determination of the nearby Cepheydes and 
RR-Lyrae stars, fundamental to define the distance 
scale to nearby galaxies and cluster of galaxies; 
■ detection of extra-solar planets and brown dwarfs: in 
a volume of 200 pc of radius the number of stellar 
candidates is about 2-3 hundred thousand; up to this 
distance GAIA will be able to detect perturbations of 
Jupiter like planets (p=11.2 years, a= 5 AU), with 
probability larger then 50%; 
■ general relativity: possible detection of gravitational 
waves, and accurate ( 10 -6 ) measure of the 
parameter y due to the Sun.