Astronomical system of units
This article's factual accuracy may be compromised due to out-of-date information. (February 2013)
This article's factual accuracy is disputed. (November 2015)
The astronomical system of units, formally called the IAU (1976) System of Astronomical Constants, is a system of measurement developed for use in astronomy. It was adopted by the International Astronomical Union (IAU) in 1976, and has been significantly updated in 1994 and 2009 (see astronomical constant).
The system was developed because of the difficulties in measuring and expressing astronomical data in International System of Units (SI units). In particular, there is a huge quantity of very precise data relating to the positions of objects within the solar system which cannot conveniently be expressed or processed in SI units. Through a number of modifications, the astronomical system of units now explicitly recognizes the consequences of general relativity, which is a necessary addition to the International System of Units in order to accurately treat astronomical data.
The astronomical system of units is a tridimensional system, in that it defines units of length, mass and time. The associated astronomical constants also fix the different frames of reference that are needed to report observations. The system is a conventional system, in that neither the unit of length nor the unit of mass are true physical constants, and there are at least three different measures of time.
Astronomical unit of time
Astronomical unit of mass
The astronomical unit of mass is the solar mass. The symbol M☉ is often used to refer to this unit. The solar mass (M☉), 92×1030 kg, is a standard way to express 1.988mass in astronomy, used to describe the masses of other stars and galaxies. It is equal to the mass of the Sun, about 000 times the mass of the 333Earth or 1,048 times the mass of Jupiter.
In practice, the masses of celestial bodies appear in the dynamics of the solar system only through the products GM, where G is the constant of gravitation. In the past, GM of the sun could be determined experimentally with only limited accuracy. Its present accepted value is G M☉=1.327 124 420 99 × 1020±1010 m3s−2
Jupiter mass (MJ or MJUP), is the unit of mass equal to the total mass of the planet Jupiter, ×1027 kg. Jupiter mass is used to describe masses of the 1.898gas giants, such as the outer planets and extrasolar planets. It is also used in describing brown dwarfs and Neptune-mass planets.
Earth mass (M⊕) is the unit of mass equal to that of the Earth. 1 M⊕ = ×1024 kg. Earth mass is often used to describe masses of rocky 5.9742terrestrial planets. It is also used to describe Neptune-mass planets. One Earth mass is 15 times a Jupiter mass. 0.003
Astronomical unit of length
The astronomical unit of length is now defined as exactly 149,597,870,700 meters. It was formerly defined as that length for which the Gaussian gravitational constant (k) takes the value 20209895 when the units of measurement are the astronomical units of length, mass and time. 0.017 The dimensions of k2 are those of the constant of gravitation (G), i.e., L3M−1T−2. The term “unit distance” is also used for the length A while, in general usage, it is usually referred to simply as the “astronomical unit”, symbol au, AU or ua.
An equivalent definition of the astronomical unit is the radius of an unperturbed circular Newtonian orbit about the Sun of a particle having infinitesimal mass, moving with a mean motion of 20209895 radians per day. 0.017 It is approximately equal to the mean Earth–Sun distance.
The speed of light in IAU is the defined value c0 = 792458 m/s of the SI units. In terms of this speed, the astronomical unit of length has the presently accepted value: 299 1 ua = c0τA = 97870700×1011 ± 3 m, where τA is the transit time of light across the astronomical unit. The astronomical unit of length is determined by the condition that the measured data in the 1.495ephemeris match observations, and that in turn decides the transit time τA.
Other units for astronomical distances
|Astronomical Range||Typical Units|
|Distances to satellites||kilometres|
|Distances to near-Earth objects||lunar distance|
|Planetary distances||astronomical units, gigametres|
|Distances to nearby stars||parsecs, light-years|
|Distances at the galactic scale||kiloparsecs|
|Distances to nearby galaxies||megaparsecs|
The distances to distant galaxies are typically not quoted in distance units at all, but rather in terms of redshift. The reasons for this are that converting redshift to distance requires knowledge of the Hubble constant which was not accurately measured until the early 21st century, and that at cosmological distances, the curvature of space-time allows one to come up with multiple definitions for distance. For example, the distance as defined by the amount of time it takes for a light beam to travel to an observer is different from the distance as defined by the apparent size of an object.
- Resolution No. 10 of the XVIth General Assembly of the International Astronomical Union, Grenoble, 1976.
- In particular, there is the barycentric celestial reference system (BCRS) centered at the barycenter of the solar system, and the geocentric celestial reference system (GCRS) centered at the center of mass of the Earth (including its fluid envelopes) Dennis D. McCarthy, P. Kenneth Seidelmann (2009). "Resolution B1.3: Definition of the barycentric celestial reference system and geocentric celestial reference system XXIVth International Astronomical Union General Assembly (2000)". Time: from Earth rotation to atomic physics. Wiley-VCH. p. 105. ISBN 3-527-40780-4.<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
- Gérard Petit and Brian Luzum, eds. (2010). "Table 1.1: IERS numerical standards" (PDF). IERS technical note no. 36: General definitions and numerical standards. International Earth Rotation and Reference Systems Service. <templatestyles src="Module:Citation/CS1/styles.css"></templatestyles> For complete document see Gérard Petit and Brian Luzum, eds. (2010). IERS Conventions (2010): IERS technical note no. 36. International Earth Rotation and Reference Systems Service. ISBN 978-3-89888-989-6. <templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
- International Astronomical Union, ed. (31 August 2012), "RESOLUTION B2 on the re-definition of the astronomical unit of length" (PDF), RESOLUTION B2, Beijing, China: International Astronomical Union,
The XXVIII General Assembly of International Astronomical Union … recommends … 1. that the astronomical unit be re-defined to be a conventional unit of length equal to 149 597 870 700 m exactly<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>
- International Bureau of Weights and Measures (2006), The International System of Units (SI) (PDF) (8th ed.), p. 126, ISBN 92-822-2213-6<templatestyles src="Module:Citation/CS1/styles.css"></templatestyles>.