International Celestial Reference System and its realizations

Last updated

The International Celestial Reference System (ICRS) is the current standard celestial reference system adopted by the International Astronomical Union (IAU). Its origin is at the barycenter of the Solar System, with axes that are intended to "show no global rotation with respect to a set of distant extragalactic objects". [1] [2] This fixed reference system differs from previous reference systems, which had been based on Catalogues of Fundamental Stars that had published the positions of stars based on direct "observations of [their] equatorial coordinates, right ascension and declination" [3] and had adopted as "privileged axes ... the mean equator and the dynamical equinox" at a particular date and time. [4]

Contents

The International Celestial Reference Frame (ICRF) is a realization of the International Celestial Reference System using reference celestial sources observed at radio wavelengths. In the context of the ICRS, a reference frame (RF) is the physical realization of a reference system, i.e., the reference frame is the set of numerical coordinates of the reference sources, derived using the procedures spelled out by the ICRS. [5]

More specifically, the ICRF is an inertial barycentric reference frame whose axes are defined by the measured positions of extragalactic sources (mainly quasars) observed using very-long-baseline interferometry while the Gaia-CRF is an inertial barycentric reference frame defined by optically measured positions of extragalactic sources by the Gaia satellite and whose axes are rotated to conform to the ICRF. Although general relativity implies that there are no true inertial frames around gravitating bodies, these reference frames are important because they do not exhibit any measurable angular rotation since the extragalactic sources used to define the ICRF and the Gaia-CRF are so far away. The ICRF and the Gaia-CRF are now the standard reference frames used to define the positions of astronomical objects. [6]

Reference systems and frames

It is useful to distinguish reference systems and reference frames. A reference frame has been defined as "a catalogue of the adopted coordinates of a set of reference objects that serves to define, or realize, a particular coordinate frame". [7] A reference system is a broader concept, encompassing "the totality of procedures, models and constants that are required for the use of one or more reference frames". [7] [8]

Realizations

The ICRF is based on hundreds of extra-galactic radio sources, mostly quasars, distributed around the entire sky. Because they are so distant, they are apparently stationary to our current technology, yet their positions can be measured very accurately by Very Long Baseline Interferometry (VLBI). The positions of most are known to 1 milliarcsecond (mas) or better. [9]

In August 1997, the International Astronomical Union resolved in Resolution B2 of its XXIIIrd General Assembly "that the Hipparcos Catalogue shall be the primary realization of the ICRS at optical wavelengths." [6] The Hipparcos Celestial Reference Frame (HCRF) is based on a subset of about 100,000 stars in the Hipparcos Catalogue. [10] In August 2021 the International Astronomical Union decided in Resolution B3 of its XXXIst General Assembly "that as from 1 January 2022, the fundamental realization of the International Celestial Reference System (ICRS) shall comprise the Third Realization of the International Celestial Reference Frame (ICRF3) for the radio domain and the Gaia-CRF3 for the optical domain." [6]

Radio wavelengths (ICRF)

ICRF1

The ICRF, now called ICRF1, was adopted by the International Astronomical Union (IAU) as of 1 January 1998. [2] ICRF1 was oriented to the axes of the ICRS, which reflected the prior astronomical reference frame The Fifth Fundamental Catalog (FK5). It had an angular noise floor of approximately 250 microarcseconds (μas) and a reference axis stability of approximately 20 μas; this was an order-of-magnitude improvement over the previous reference frame derived from (FK5). [11] [12] The ICRF1 contains 212 defining sources and also contains positions of 396 additional non-defining sources for reference. The positions of these sources have been adjusted in later extensions to the catalogue. ICRF1 agrees with the orientation of the Fifth Fundamental Catalog (FK5) "J2000.0" frame to within the (lower) precision of the latter. [2]

ICRF2

An updated reference frame ICRF2 was created in 2009. [12] [13] The update was a joint collaboration of the International Astronomical Union, the International Earth Rotation and Reference Systems Service, and the International VLBI Service for Geodesy and Astrometry. [14] ICRF2 is defined by the position of 295 compact radio sources (97 of which also define ICRF1). Alignment of ICRF2 with ICRF1-Ext2, the second extension of ICRF1, was made with 138 sources common to both reference frames. Including non-defining sources, it comprises 3414 sources measured using very-long-baseline interferometry. The ICRF2 has a noise floor of approximately 40 μas and an axis stability of approximately 10 μas. Maintenance of the ICRF2 will be accomplished by a set of 295 sources that have especially good positional stability and unambiguous spatial structure. [15]

The data used to derive the reference frame come from approximately 30 years of VLBI observations, from 1979 to 2009. [12] Radio observations in both the S-band (2.3 GHz) and X-band (8.4 GHz) were recorded simultaneously to allow correction for ionospheric effects. The observations resulted in about 6.5 million group-delay measurements among pairs of telescopes. The group delays were processed with software that takes into account atmospheric and geophysical processes. The positions of the reference sources were treated as unknowns to be solved for by minimizing the mean squared error across group-delay measurements. The solution was constrained to be consistent with the International Terrestrial Reference Frame (ITRF2008) and earth orientation parameters (EOP) systems. [16]

ICRF3

Sky distribution of the 303 "defining sources" in the ICRF3 ICRF3 Figure 13 Defining Sources Only.png
Sky distribution of the 303 "defining sources" in the ICRF3

ICRF3 is the third major revision of the ICRF, and was adopted by the IAU in August 2018 and became effective 1 January 2019. The modeling incorporates the effect of the galactocentric acceleration of the solar system, a new feature over and above ICRF2. ICRF3 also includes measurements at three frequency bands, providing three independent, and slightly different, realizations of the ICRS: dual frequency measurements at 8.4 GHz (X band) and 2.3 GHz (S band) for 4536 sources; measurements of 824 sources at 24 GHz (K band), and dual frequency measurements at 32 GHz (Ka band) and 8.4 GHz (X band) for 678 sources. Of these, 303 sources, uniformly distributed on the sky, are identified as "defining sources" which fix the axes of the frame. ICRF3 also increases the number of defining sources in the southern sky. [17] [18] [19]

Optical wavelengths

Hipparcos Celestial Reference Frame (HCRF)

In 1991 the International Astronomical Union recommended "that observing programmes be undertaken or continued in order to ... determine the relationship between catalogues of extragalactic source positions and ... the [stars of the] FK5 and Hipparcos catalogues." [1] Using a variety of linking techniques, the coordinate axes defined by the Hipparcos catalogue were aligned with the extragalactic radio frame. [20] In August 1997, the International Astronomical Union recognized in Resolution B2 of its XXIIIrd General Assembly "That the Hipparcos Catalogue was finalized in 1996 and that its coordinate frame is aligned to that of the frame of the extragalactic sources [ICRF1] with one sigma uncertainties of ±0.6 milliarcseconds (mas)" and resolved "that the Hipparcos Catalogue shall be the primary realization of the ICRS at optical wavelengths." [2]

Second Gaia celestial reference frame (Gaia–CRF2)

The second Gaia celestial reference frame (Gaia–CRF2), based on 22 months of observations of over half a million extragalactic sources by the Gaia spacecraft, appeared in 2018 and has been described as "the first full-fledged optical realisation of the ICRS, that is to say, an optical reference frame built only on extragalactic sources." The axes of Gaia-CRF2 were aligned to a prototype version of the forthcoming ICRF3 using 2820 objects common to Gaia-CRF2 and to the ICRF3 prototype. [21] [22]

Third Gaia celestial reference frame (Gaia–CRF3)

The third Gaia celestial reference frame (Gaia–CRF3) is based on 33 months of observations of 1,614,173 extragalactic sources. As with the earlier Hipparcos and Gaia reference frames, the axes of Gaia-CRF3 were aligned to 3142 optical counterparts of ICRF-3 in the S/X frequency bands. [23] [24] In August 2021 the International Astronomical Union noted that the Gaia-CRF3 had "largely superseded the Hipparcos Catalogue" and was "de facto the optical realization of the Celestial Reference Frame within the astronomical community." Consequently, the IAU decided that Gaia-CRF3 shall be "the fundamental realization of the International Celestial Reference System (ICRS) ... for the optical domain." [6]

See also

Related Research Articles

<span class="mw-page-title-main">Astrometry</span> Branch of astronomy involving positioning and movements of celestial bodies

Astrometry is a branch of astronomy that involves precise measurements of the positions and movements of stars and other celestial bodies. It provides the kinematics and physical origin of the Solar System and this galaxy, the Milky Way.

<span class="mw-page-title-main">Polaris</span> Brightest star in the constellation Ursa Minor

Polaris is a star in the northern circumpolar constellation of Ursa Minor. It is designated α Ursae Minoris and is commonly called the North Star or Pole Star. With an apparent magnitude that fluctuates around 1.98, it is the brightest star in the constellation and is readily visible to the naked eye at night. The position of the star lies less than 1° away from the north celestial pole, making it the current northern pole star. The stable position of the star in the Northern Sky makes it useful for navigation.

<span class="mw-page-title-main">Sidereal time</span> Timekeeping system on Earth relative to the celestial sphere

Sidereal time is a system of timekeeping used especially by astronomers. Using sidereal time and the celestial coordinate system, it is easy to locate the positions of celestial objects in the night sky. Sidereal time is a "time scale that is based on Earth's rate of rotation measured relative to the fixed stars".

<span class="mw-page-title-main">International Earth Rotation and Reference Systems Service</span> Body responsible for maintaining global time and reference frame standards

The International Earth Rotation and Reference Systems Service (IERS), formerly the International Earth Rotation Service, is the body responsible for maintaining global time and reference frame standards, notably through its Earth Orientation Parameter (EOP) and International Celestial Reference System (ICRS) groups.

<i>Hipparcos</i> European Space Agency scientific satellite

Hipparcos was a scientific satellite of the European Space Agency (ESA), launched in 1989 and operated until 1993. It was the first space experiment devoted to precision astrometry, the accurate measurement of the positions of celestial objects on the sky. This permitted the first high-precision measurements of the intrinsic brightnesses, proper motions, and parallaxes of stars, enabling better calculations of their distance and tangential velocity. When combined with radial velocity measurements from spectroscopy, astrophysicists were able to finally measure all six quantities needed to determine the motion of stars. The resulting Hipparcos Catalogue, a high-precision catalogue of more than 118,200 stars, was published in 1997. The lower-precision Tycho Catalogue of more than a million stars was published at the same time, while the enhanced Tycho-2 Catalogue of 2.5 million stars was published in 2000. Hipparcos' follow-up mission, Gaia, was launched in 2013.

<span class="mw-page-title-main">Very-long-baseline interferometry</span> Comparing widely separated telescope wavefronts

Very-long-baseline interferometry (VLBI) is a type of astronomical interferometry used in radio astronomy. In VLBI a signal from an astronomical radio source, such as a quasar, is collected at multiple radio telescopes on Earth or in space. The distance between the radio telescopes is then calculated using the time difference between the arrivals of the radio signal at different telescopes. This allows observations of an object that are made simultaneously by many radio telescopes to be combined, emulating a telescope with a size equal to the maximum separation between the telescopes.

<i>Gaia</i> (spacecraft) European optical space observatory for astrometry

Gaia is a space observatory of the European Space Agency (ESA), launched in 2013 and expected to operate until 2025. The spacecraft is designed for astrometry: measuring the positions, distances and motions of stars with unprecedented precision, and the positions of exoplanets by measuring attributes about the stars they orbit such as their apparent magnitude and color. The mission aims to construct by far the largest and most precise 3D space catalog ever made, totalling approximately 1 billion astronomical objects, mainly stars, but also planets, comets, asteroids and quasars, among others.

<span class="mw-page-title-main">UU Aurigae</span> Star in the constellation of Auriga

UU Aurigae is a carbon star in the constellation Auriga. It is approximately 341 parsecs from Earth.

The Catalogue of Fundamental Stars is a series of six astrometric catalogues of high precision positional data for a small selection of stars to define a celestial reference frame, which is a standard coordinate system for measuring positions of stars.

In astronomy, an equinox is either of two places on the celestial sphere at which the ecliptic intersects the celestial equator. Although there are two such intersections, the equinox associated with the Sun's ascending node is used as the conventional origin of celestial coordinate systems and referred to simply as "the equinox". In contrast to the common usage of spring/vernal and autumnal equinoxes, the celestial coordinate system equinox is a direction in space rather than a moment in time.

<span class="mw-page-title-main">3C 286</span> Quasar often used for calibration

3C 286, also known by its position as 1328+307 or 1331+305, is a quasar at redshift 0.8493 with a radial velocity of 164,137 km/s. It is part of the Third Cambridge Catalogue of Radio Sources.

In geodesy and astrometry, earth orientation parameters (EOP) describe irregularities in the rotation of planet Earth. EOP provide the rotational transform from the International Terrestrial Reference System (ITRS) to the International Celestial Reference System (ICRS), or vice versa, as a function of time.

<span class="mw-page-title-main">Lennart Lindegren</span> Swedish astronomer

Lennart Lindegren is a member of the staff at Lund Observatory, Sweden, where he obtained his PhD in 1980, and became a full professor of astronomy in 2000. Space astrometry and its various applications has been his main focus in astronomy since 1976. His career has been marked by his continuous involvement in, leadership of, and profound contributions to, ESA's Hipparcos and Gaia missions over their entire duration.

<span class="mw-page-title-main">Phi Cygni</span> Star in the constellation Cygnus

Phi Cygni, Latinized from φ Cygni, is a binary star system in the northern constellation of Cygnus. It is faintly visible to the naked eye with an apparent visual magnitude of 4.70. The annual parallax shift is 12.25 mas as measured from Earth, which yields a distance estimate of around 266 light years. It is moving further from the Sun with a radial velocity of +4.5 km/s.

HD 189276 is a single star in the northern constellation Cygnus, positioned near the northern constellation border with Draco. It has an orange hue and is faintly visible to the naked eye with an apparent visual magnitude of 4.98. The star is located at a distance of approximately 820 light years from the Sun based on parallax, and it has an absolute magnitude of −2.25. It is drifting further away with a radial velocity of +4 km/s. The star has a high peculiar velocity of 38.5+1.8
−2.2 km/s and thus is a probable runaway star.

The barycentric celestial reference system (BCRS) is a coordinate system used in astrometry to specify the location and motions of astronomical objects. It was created in 2000 by the International Astronomical Union (IAU) to be the global standard reference system for objects located outside the gravitational vicinity of Earth: planets, moons, and other Solar System bodies, stars and other objects in the Milky Way galaxy, and extra-galactic objects.

Ye Shuhua is a Chinese astronomer and professor at Shanghai Astronomical Observatory, known for achieving one of the world's most precise measurements of Universal Time in the 1960s, and for establishing the very-long-baseline interferometry (VLBI) and satellite laser ranging (SLR) techniques in China.

<i>Gaia</i> catalogues Catalogues consisting of data from the Gaia misson.

The Gaia catalogues are star catalogues created using the results obtained by Gaia space telescope.

Jean Kovalevsky was a French astronomer, specializing in celestial mechanics. He is known as a primary initiator and a leader of the Hipparcos space experiment.

References

  1. 1 2 The XXIst General Assembly of the International Astronomical Union (1991). "Resolution No. A4; Recommendations from the Working Group on Reference System" (PDF). Resolutions adopted at the General Assemblies. International Astronomical Union. Retrieved 13 June 2022.
  2. 1 2 3 4 The XXlIIrd General Assembly of the International Astronomical Union (1997). "Resolution No B2; On the international celestial reference system" (PDF). Resolutions adopted at the General Assemblies. International Astronomical Union. Retrieved 13 June 2022.
  3. Walter, Hans G.; Sovers, Oscar J. (2000), Astrometry of Fundamental Catalogues: The Evolution from Optical to Radio Reference Frames, Berlin: Springer, p. 1, ISBN   9783540674368
  4. Arias, E.F.; Charlot, P.; Feissel, M.; Lestrade, J.-F. (1995), "The Extragalactic Reference System of the International Earth Rotation Service, ICRS", Astronomy and Astrophysics, 303: 604–608, Bibcode:1995A&A...303..604A
  5. "International Celestial Reference System (ICRS)". aa.usno.navy.mil. US Naval Observatory. Retrieved 23 June 2022.
  6. 1 2 3 4 The XXXIst General Assembly of the International Astronomical Union (2021). "Resolution B3, On the Gaia Celestial Reference Frame" (PDF). Resolutions adopted at the General Assemblies. International Astronomical Union. Retrieved 9 June 2022.
  7. 1 2 Wilkins, G.A. (1990). "The Past, Present and Future of Reference Systems for Astronomy and Geodesy". In Lieske, J. H.; Abalakin, V. K (eds.). Symposium - International Astronomical Union, Inertial Coordinate System on the Sky. Vol. 141. Cambridge University Press. pp. 39–46. doi:10.1017/S0074180900086149.{{cite book}}: |journal= ignored (help)
  8. "International Celestial Reference System (ICRS)". U.S. Naval Observatory, Astronomical Applications. Retrieved 24 June 2022. A reference system ... defines the origin and fundamental planes (or axes) of the coordinate system. It also specifies all of the constants, models, and algorithms used to transform between observable quantities and reference data that conform to the system. A reference frame consists of a set of identifiable fiducial points on the sky (specific astronomical objects), along with their coordinates, that serves as the practical realization of a reference system.
  9. "International Celestial Reference System (ICRS)". U.S. Naval Observatory, Astronomical Applications. Retrieved 23 June 2022.
  10. "International Celestial Reference System (ICRS)". U S Naval Observatory, Astronomical Applications Department. Retrieved 22 June 2022.
  11. Ma, C.; Arias, E. F.; Eubanks, T. M.; et al. (July 1998), "The International Celestial Reference Frame as Realized by Very Long Baseline Interferometry", Astronomical Journal, 116 (1): 516–546, Bibcode:1998AJ....116..516M, doi: 10.1086/300408 , S2CID   120005941
  12. 1 2 3 "IERS Technical Note No. 35: The Second Realization of the International Celestial Reference Frame by Very Long Baseline Interferometry" (PDF). International Earth Rotation and Reference Systems Service (IERS). Archived from the original (PDF) on 25 July 2015. Retrieved 5 April 2014.
  13. Steigerwald, Bell. "NASA - New Celestial Map Gives Directions for GPS". www.nasa.gov. NASA. Archived from the original on 3 December 2020. Retrieved 5 June 2018.
  14. Fey, Alan L. "The International Celestial Reference Frame". usno.navy.mil. US Naval Observatory (USNO). Retrieved 23 June 2022.
  15. Boboltz, David A.; Gaume, R. A.; Fey, A. L.; Ma, C.; Gordon, D. (1 January 2010). "The Second Realization of the International Celestial Reference Frame (ICRF2) by Very Long Baseline Interferometry". American Astronomical Society Meeting Abstracts #215. 215. AAS: 469.06. Bibcode:2010AAS...21546906B . Retrieved 18 July 2022.
  16. Fey, A. L.; Gordon, D.; Jacobs, C. S.; Ma, C.; Gaume, R. A.; Arias, E. F.; Bianco, G.; Boboltz, D. A.; Böckmann, S.; Bolotin, S.; Charlot, P.; Collioud, A.; Engelhardt, G.; Gipson, J.; Gontier, A.-M.; Heinkelmann, R.; Kurdubov, S.; Lambert, S.; Lytvyn, S.; MacMillan, D. S.; Malkin, Z.; Nothnagel, A.; Ojha, R.; Skurikhina, E.; Sokolova, J.; Souchay, J.; Sovers, O. J.; Tesmer, V.; Titov, O.; Wang, G.; Zharov, V. (24 July 2015). "The Second Realization of the International Celestial Reference Frame by Very Long Baseline Interferometry". The Astronomical Journal. 150 (2): 58. Bibcode:2015AJ....150...58F. doi:10.1088/0004-6256/150/2/58. hdl: 11603/17528 . ISSN   1538-3881. S2CID   3281444.
  17. Charlot, P.; Jacobs, C.S.; Gordon, D.; et al. (2020). "The third realization of the International Celestial Reference Frame by very long baseline interferometry". Astronomy and Astrophysics. 644 (A159): A159. arXiv: 2010.13625 . Bibcode:2020A&A...644A.159C. doi: 10.1051/0004-6361/202038368 . S2CID   225068756 . Retrieved 16 June 2022.
  18. "The ICRF". IERS ICRS Center. Paris Observatory. Retrieved 25 December 2018.
  19. "The International Celestial Reference System (ICRS)". International Earth Rotation and Reference Systems Service. Retrieved 11 February 2020.
  20. Kovalevsky, J.; Lindegren, L.; Perryman, M.A.C.; et al. (1997). "The Hipparcos Catalogue as a realisation of the extragalactic reference system". Astronomy and Astrophysics. 323: 620–633. Retrieved 20 June 2022.
  21. Gaia Collaboration; Mignard, F.; Klioner, S.; Lindegren, L.; et al. (2018), "Gaia Data Release 2. The celestial reference frame (Gaia-CRF2)", Astronomy & Astrophysics, 616 (A14): A14, arXiv: 1804.09377 , Bibcode:2018A&A...616A..14G, doi:10.1051/0004-6361/201832916, S2CID   52838272
  22. Lindegren, L.; Hernandez, J.; Bombrun, A.; Klioner, S.; et al. (2018), "Gaia Data Release 2 – The astrometric solution", Astronomy & Astrophysics, 616 (A2): A2, arXiv: 1804.09366 , Bibcode:2018A&A...616A...2L, doi:10.1051/0004-6361/201832727, S2CID   54497421
  23. Gaia Collaboration (2022), "Gaia Early Data Release 3: The celestial reference frame (Gaia-CRF3)", Astronomy & Astrophysics, 667, arXiv: 2204.12574 , Bibcode:2022A&A...667A.148G, doi: 10.1051/0004-6361/202243483 , S2CID   248405779
  24. "Gaia Early Data Release 3 (Gaia EDR3)". ESA. Retrieved 12 December 2020.

Further reading

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.