galaxy, showing two prominent spiral arms attached to the ends of a thick central bar.
Hipparcos mapped many stars in the solar neighbourhood with great accuracy, though this represents only a small fraction of stars in the galaxy. The
Hipparcos results have affected a very broad range of astronomical research, which can be classified into three major themes: • the provision of an accurate reference frame: this has allowed the consistent and rigorous re-reduction of historical astrometric measurements, including those from Schmidt plates, meridian circles, the 100-year-old
Astrographic Catalogue, and 150 years of Earth-orientation measurements. These, in turn, have yielded a dense reference framework with high-accuracy, long-term proper motions (the
Tycho-2 Catalogue). Reduction of current state-of-the-art survey data has yielded the dense UCAC2 Catalogue of the
U.S. Naval Observatory on the same reference system, and improved astrometric data from recent surveys such as the
Sloan Digital Sky Survey and
2MASS. Implicit in the high-accuracy reference frame is the measurement of
gravitational lensing and the detection and characterisation of double and multiple stars; • constraints on
stellar structure and
stellar evolution: the accurate distances and luminosities of 100,000 stars has provided the most comprehensive and accurate data set of fundamental stellar parameters to date, placing constraints on internal rotation, element diffusion, convective motions, and
asteroseismology. Combined with theoretical models and other data it yields evolutionary masses, radii, and ages for large numbers of stars covering a wide range of evolutionary states; • Galactic kinematics and dynamics: the uniform and accurate distances and proper motions have provided a substantial advance in understanding of
stellar kinematics and the dynamical structure of the solar neighbourhood, ranging from the presence and evolution of clusters, associations and moving groups, the presence of resonance motions due to the Galaxy's central bar and
spiral arms, determination of the parameters describing
galactic rotation, discrimination of the disk and halo populations, evidence for halo accretion, and the measurement of space motions of
runaway stars,
globular clusters, and many other types of star. Associated with these major themes,
Hipparcos has provided results in topics as diverse as Solar System science, including mass determinations of asteroids,
Earth's rotation and
Chandler wobble; the internal structure of
white dwarfs; the masses of
brown dwarfs; the characterisation of
extra-solar planets and their host stars; the height of the Sun above the Galactic mid-plane; the
age of the Universe; the stellar
initial mass function and
star formation rates; and strategies for the
search for extraterrestrial intelligence. The high-precision multi-epoch photometry has been used to measure variability and stellar pulsations in many classes of objects. The
Hipparcos and
Tycho catalogues are now routinely used to point ground-based telescopes, navigate space missions, and drive public planetaria. Since 1997, several thousand scientific papers have been published making use of the
Hipparcos and
Tycho catalogues. A detailed review of the
Hipparcos scientific literature between 1997 and 2007 was published in 2009, • the nature of
Delta Scuti variables • testing the
white dwarf mass–radius relation • the structure and dynamics of the
Hyades cluster • fine structure of the
red giant clump and associated distance determinations • unexpected stellar velocity distribution in the warped Galactic disk • refining the
Oort and Galactic constants • Galactic disk dark matter, terrestrial impact cratering and the law of large numbers • vertical motion and expansion of the
Gould Belt • evidence of a galaxy merger in the early formation history of the Milky Way • study of nearby
OB associations • close approaches of stars to the
Solar System • studies of
binary star orbits and masses • formation of the stellar
Galactic halo and thick disk •
ice age epochs and the Sun's path through the Galaxy • local kinematics of K and M giants and the concept of superclusters • the local stellar velocity field in the Galaxy • Identification of two possible "siblings" of the Sun (HIP 87382 and HIP 47399), to be studied for evidence of exoplanets
The Pleiades distance controversy One controversial result has been the derived proximity, at about 120 parsecs, of the
Pleiades cluster, established both from the original catalogue as well as from the revised analysis. According to a 2012 paper, the anomaly was due to the use of a weighted mean when there is a correlation between distances and distance errors for stars in clusters. It is resolved by using an unweighted mean. There is no systematic bias in the Hipparcos data when it comes to star clusters. In August 2014, the discrepancy between the cluster distance of as measured by
Hipparcos and the distance of derived with other techniques was confirmed by parallax measurements made using
VLBI, which gave , the most accurate and precise distance yet presented for the cluster.
Polaris Another distance debate set-off by Hipparcos is for the distance to the star Polaris.
Hipparcos-Gaia Hipparcos data is recently being used together with
Gaia data. Especially the comparison of the
proper motion of stars from both spacecraft is being used to search for hidden binary companions. Hipparcos-Gaia data is also used to measure the dynamical mass of known binaries, such as
substellar companions. Hipparcos-Gaia data was used to measure the mass of the exoplanet
Beta Pictoris b and is sometimes used to study other long-period
exoplanets, such as
HR 5183 b. == People ==