The astronomical unit (au)

Reasons, consequences and process regarding the IAU 2012 re-definition of the astronomical unit

Nicole Capitaine

Observatoire de Paris, October 2012


Presentation of the resolution proposal at the IAU GA (August 2012)

IAU 2012 Resolution B2: Re-definition of the astronomical unit of length (PDF file)

UAI 2012 Résolution B2: Re-définition de l'unité astronomique de longueur (fichier PDF)


1- The astronomical unit as part of the astronomical system of units

- It is convenient for astronomers to use, for certain applications, an astronomical system of units, in which the unit of mass is equal to the mass of the Sun, MS, the unit of time is one day, D, and the unit of length is the astronomical unit of length (or simply the "astronomical unit").
- The astronomical unit is a unit of length approximating the Sun-Earth distance that it is in common use by astronomers for expressing distances.

2- The old definition of the astronomical unit

- The au was defined by a mathematical expression involving the mass of the Sun, the length of the day and a fixed number, chosen as being a conventional value of a constant designated as the "Gaussian gravitational constant".
- More precisely, the au was "that length for which the Gaussian gravitational constant, k, takes the value of 0.017 202 098 95 when the units of measurements are the astronomical unit of length, mass and time", or equivalently "the radius of an unperturbed circular Newtonian orbit about the Sun of a particle having infinitesimal mass, moving with an angular frequency of 0.017 202 098 95 radians per day".
- The practice of using the value of k as a fixed constant which served to define the astronomical unit was in use unofficially since the 19th century and officially since 1938.
- The fixed number chosen for k came from an old measurement of the Earth's mean motion around the Sun.
- Expressing distances in astronomical unit as defined above allowed astronomers to overcome the difficulty of measuring distances in some physical unit (such as the meter).
- Such a practice was useful for many years because astronomers were not able to make distance measurements in the solar system as precisely as they could measure angles.

3- The problems encountered with the old definition

- Due to the complexity of the above definition, there have been many incorrect descriptions of the au and wrong statements about what it was intended to be.
- With the old definition, the length of the au in Système International (SI) meters was determined by observations in the solar system so that the value in fact depended on the theory of motion and observations being used.
- The description of the old definition was based on a Newtonian concept which was difficult to extend to the framework of General relativity, which is the framework needed by modern dynamical astronomy.
- The value in SI units of the solar mass parameter (i.e. the product, GMS, of MS by the gravitational constant G) had to be derived from a mathematical formula and the value in meters of the au, which did not give a direct access to that parameter.
- The accuracy of modern range measurements (i.e. uncertainty of a few meters in a length of 150 millions of kilometers) makes the use of the practice (described in 2-) unnecessary.

4- The new definition (IAU 2012 Resolution B2)

- The new definition is such that the au is a conventional unit of length equal to a fixed number of SI meters.
- The conventional value (i.e. 149 597 870 700 m exactly) adopted for the new definition has been chosen to be consistent with the best estimate of the numerical value of the au corresponding to the old definition, which was provided in the IAU 2009 System of astronomical constants. - This definition of the astronomical unit is to be used with all forms of the metrics used in General Relativity.

5- Advantages of the new definition

- It eliminates possible conflicts with SI units.
- It eliminates dependence on theories of motion.
- It eliminates requirements for additional conventions to account for the effects of General Relativity.
- It makes it easier to deal with possible variations in the mass of the Sun.

6- Consequences for the users of the change of definition

- The change of definition of the astronomical unit mainly concerns those in the field of high-accuracy solar system dynamics, because there is a change of status of that unit: its value in SI meter is now fixed to a conventional number and has no more to be estimated by observations as it was with the old definition.
- The new definition makes that unit more understandable to other scientists, engineers, and software designers.
- The astronomical unit is also used in the definition of other astronomical measurement scales. However, the relative difference between the old and the new definitions is so small that there would be no significant effect in changing our understanding of distances to objects outside our solar system considering the precision with which they are known today. The reason for that is that the numerical value of the new definition has been chosen to be consistent with the best estimate corresponding to the old definition.

7- Process followed for the adoption of the new definition

- The question of fixing the length of the au goes back several years, and has been discussed at international meetings as well as within groups of experts, especially since 2009, in particular within the IAU Working Group on Numerical standards for fundamental astronomy.
- There were objections to the change from a few people who considered either that the change would be difficult to implement in the solar system ephemeredes software, or that it would induce discrepancies with the previous practice, or because they were attached to the historical definition. But after a few years of discussion and the concrete proof of the possibility of changing the definition by the producers of solar system ephemerides, all agreed on the necessity of that re-definition.
- A draft resolution proposal was submitted to the astronomical community in September 2011 during the "Journées 2011 "Systèmes de référence" in Vienna, which was largely discussed during that meeting and resulted in an improved wording of the proposal.
- That revised draft was then submitted by the President of Division 1 (Fundamental Astronomy) of the International astronomical union (D.D. McCarthy) to the relevant commissions of that Division, which resulted in a few improvements of the wording or proposals of changes that have not all be agreed. Minor improvements in the wording have been proposed during Joint Discussion 7 at the General Assembly of the IAU, the day before the publication of the text of the Resolution in the GA newspaper which was submitted to the GA.
- The Resolution (IAU 2012 Resolution B2) was voted at the final meeting of the General assembly of the IAU (30 August).

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