Standard gravitational parameter

{| class="wikitable floatright"

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! Body

! colspan="2"|μ [m³⋅s⁻²]

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| Sun

| style="border-right:none;"|

| style="border-left :none;"|× 10²⁰

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| Ceres

| style="border-right:none;"|

| style="border-left :none;"|× 10¹⁰ while orbits, at least in the solar system, can be measured with great precision and used to determine μ with similar precision.

For a circular orbit around a central body, where the centripetal force provided by gravity is :

<math display="block">\mu = rv^2 = r^3\omega^2 = \frac{4\pi^2r^3}{T^2} ,</math>

where r is the orbit radius, v is the orbital speed, ω is the angular speed, and T is the orbital period.

This can be generalized for elliptic orbits:

<math display="block">\mu = \frac{4\pi^2a^3}{T^2} ,</math>

where a is the semi-major axis, which is Kepler's third law.

For parabolic trajectories rv² is constant and equal to 2μ. For elliptic and hyperbolic orbits magnitude of μ = 2 times the magnitude of a times the magnitude of ε, where a is the semi-major axis and ε is the specific orbital energy.

General case

In the more general case where the bodies need not be a large one and a small one, e.g. a binary star system, we define:

• the vector r is the position of one body relative to the other
• r, v, and in the case of an elliptic orbit, the semi-major axis a, are defined accordingly (hence r is the distance)
• μ = Gm₁ + Gm₂ = μ₁ + μ₂, where m₁ and m₂ are the masses of the two bodies.

Then:

• for circular orbits, rv² = r³ω² = 4π²r³/T² = μ
• for elliptic orbits, (with a expressed in AU; T in years and M the total mass relative to that of the Sun, we get )
• for parabolic trajectories, rv² is constant and equal to 2μ
• for elliptic and hyperbolic orbits, μ is twice the semi-major axis times the negative of the specific orbital energy, where the latter is defined as the total energy of the system divided by the reduced mass.

In a pendulum

The standard gravitational parameter can be determined using a pendulum oscillating above the surface of a body as:

<math display="block">\mu \approx \frac{4 \pi^2 r^2 L}{T^2} </math>

where r is the radius of the gravitating body, L is the length of the pendulum, and T is the period of the pendulum (for the reason of the approximation see Pendulum in mechanics).

Solar system

Geocentric gravitational constant

G, the gravitational parameter for the Earth as the central body, is called the geocentric gravitational constant. It equals .

The value of this constant became important with the beginning of spaceflight in the 1950s, and great effort was expended to determine it as accurately as possible during the 1960s. Sagitov (1969) cites a range of values reported from 1960s high-precision measurements, with a relative uncertainty of the order of 10⁻⁶.

During the 1970s to 1980s, the increasing number of artificial satellites in Earth orbit further facilitated high-precision measurements,

and the relative uncertainty was decreased by another three orders of magnitude, to about (1 in 500 million) as of 1992.

Measurement involves observations of the distances from the satellite to Earth stations at different times, which can be obtained to high accuracy using radar or laser ranging.

Heliocentric gravitational constant

G, the gravitational parameter for the Sun as the central body,

is called the heliocentric gravitational constant or geopotential of the Sun and equals

The relative uncertainty in G, cited at below 10⁻¹⁰ as of 2015,<!--7.5e-11 as of 2015--> is smaller than the uncertainty in G <!--2e-9 as of 1992-->

because G is derived from the ranging of interplanetary probes, and the absolute error of the distance measures to them is about the same as the earth satellite ranging measures, while the absolute distances involved are much bigger.<!-- OR maybe it is because one source is dated 1992 and the other is dated 2015? -->

See also

• Astronomical system of units
• Planetary mass

References