Standard gravitational parameter

Body	μ (km³s⁻²)
Sun	7011132712440018000♠132712440018(9)^[1]
Mercury	7004220320000000000♠22032
Venus	7005324859000000000♠324859
Earth	7005398600441700000♠398600.4418(9)
Moon	7003490280000000000♠4902.8000
Mars	7004428280000000000♠42828
Ceres	7001631000000000000♠63.1(3)^[2]^[3]
Jupiter	7008126686534000000♠126686534
Saturn	7007379311870000000♠37931187
Uranus	7006579393900000000♠5793939(13)^[4]
Neptune	7006683652900000000♠6836529
Pluto	7002871000000000000♠871(5)^[5]
Eris	7003110800000000000♠1108(13)^[6]

In celestial mechanics, the standard gravitational parameter μ of a celestial body is the product of the gravitational constant G and the mass M of the body.

\mu=GM \

For several objects in the Solar System, the value of μ is known to greater accuracy than either G or M.^[7] The SI units of the standard gravitational parameter are m³s⁻².

Small body orbiting a central body

The relation between properties of mass and their associated physical constants. Every massive object is believed to exhibit all five properties. However, due to extremely large or extremely small constants, it is generally impossible to verify more than two or three properties for any object.

The Schwarzschild radius (r_s) represents the ability of mass to cause curvature in space and time.

The standard gravitational parameter (μ) represents the ability of a massive body to exert Newtonian gravitational forces on other bodies.

Inertial mass (m) represents the Newtonian response of mass to forces.

Rest energy (E₀) represents the ability of mass to be converted into other forms of energy.

The Compton wavelength (λ) represents the quantum response of mass to local geometry.

The central body in an orbital system can be defined as the one whose mass (M) is much larger than the mass of the orbiting body (m), or M≫m. This approximation is standard for planets orbiting the Sun or most moons and greatly simplifies equations.

For a circular orbit around a central body:

\mu = rv^2 = r^3\omega^2 = 4\pi^2r^3/T^2 \

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:

\mu=4\pi^2a^3/T^2 \

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 μ = 2a|ε|, where ε is the specific orbital energy.

Two bodies orbiting each other

In the more general case where the bodies need not be a large one and a small one (the two-body problem), 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, 4π²a³/T² = μ (with a expressed in AU; T in seconds and M the total mass relative to that of the Sun, we get a³/T² = M)
for parabolic trajectories, rv² is constant and equal to 2μ
for elliptic and hyperbolic orbits, μ is twice the semi-major axis times the absolute value of the specific orbital energy, where the latter is defined as the total energy of the system divided by the reduced mass.

Terminology and accuracy

Note that the reduced mass is also denoted by $\mu.\!\,$ .

The value for the Earth is called the geocentric gravitational constant and equals 7005398600441700000♠398600.4418±0.0008 km³s⁻². Thus the uncertainty is 1 to 7008500000000000000♠500000000, much smaller than the uncertainties in G and M separately (1 to 7003700000000000000♠7000 each).

The value for the Sun is called the heliocentric gravitational constant or geopotential of the sun and equals 7011132712440018000♠1.32712440018×10¹¹ km³s⁻².

References

↑ "Astrodynamic Constants". NASA/JPL. 27 February 2009. Retrieved 27 July 2009.
↑ E.V. Pitjeva (2005). "High-Precision Ephemerides of Planets — EPM and Determination of Some Astronomical Constants" (PDF). Solar System Research 39 (3): 176. Bibcode:2005SoSyR..39..176P. doi:10.1007/s11208-005-0033-2.
↑ D. T. Britt; D. Yeomans; K. Housen; G. Consolmagno (2002). "Asteroid density, porosity, and structure". In W. Bottke; A. Cellino; P. Paolicchi; R.P. Binzel. [http://www.lpi.usra.edu/books/AsteroidsIII/download.html Asteroids III] (PDF). University of Arizona Press. p. 488.
↑ R.A. Jacobson; J.K. Campbell; A.H. Taylor; S.P. Synnott (1992). "The masses of Uranus and its major satellites from Voyager tracking data and Earth-based Uranian satellite data". Astronomical Journal 103 (6): 2068–2078. Bibcode:1992AJ....103.2068J. doi:10.1086/116211.
↑ M.W. Buie; W.M. Grundy; E.F. Young; L.A. Young et al. (2006). "Orbits and photometry of Pluto's satellites: Charon, S/2005 P1, and S/2005 P2". Astronomical Journal 132: 290. arXiv:astro-ph/0512491. Bibcode:2006AJ....132..290B. doi:10.1086/504422.
↑ M.E. Brown; E.L. Schaller (2007). "The Mass of Dwarf Planet Eris". Science 316 (5831): 1586. Bibcode::2007Sci...316.1585B. doi:10.1126/science.1139415. PMID 17569855.
↑ This is mostly because μ can be measured by observational astronomy alone, as it has been for centuries. Decoupling it into G and M must be done by measuring the force of gravity in sensitive laboratory conditions, as first done in the Cavendish experiment.

Gravitational orbits

Orbits

General	Box Capture Circular Elliptical / Highly elliptical Escape Graveyard Hyperbolic trajectory Inclined / Non-inclined Osculating Parabolic trajectory Parking Synchronous semi sub

Geocentric	Geosynchronous Geostationary Sun-synchronous Low Earth Medium Earth High Earth Molniya Near-equatorial Orbit of the Moon Polar Tundra Two-line elements

About other points	Areosynchronous Areostationary Halo Lissajous Lunar Heliocentric Heliosynchronous

Parameters

Shape/Size	$e\,\!$ Eccentricity $a\,\!$ Semi-major axis $b\,\!$ Semi-minor axis $Q,q\,\!$ Apsides

Orientation	$i\,\!$ Inclination $\Omega\,\!$ Longitude of the ascending node $\omega\,\!$ Argument of periapsis $\varpi\,\!$ Longitude of the periapsis

Position	$M\,\!$ Mean anomaly $\nu\,\!$ True anomaly $E\,\!$ Eccentric anomaly $L\,\!$ Mean longitude $l\,\!$ True longitude

Variation	$T\,\!$ Orbital period $n\,\!$ Mean motion $v\,\!$ Orbital speed $t_0\,\!$ Epoch

Maneuvers

Collision avoidance (spacecraft) Delta-v Delta-v budget Bi-elliptic transfer Geostationary transfer Gravity assist Gravity turn Hohmann transfer Low energy transfer Oberth effect Inclination change Phasing Rocket equation Rendezvous Transposition, docking, and extraction

Other orbital mechanics topics

Celestial coordinate system Characteristic energy Ephemeris Equatorial coordinate system Ground track Hill sphere Interplanetary Transport Network Kepler's laws of planetary motion Lagrangian point n-body problem Orbit equation Orbital state vectors Perturbation Retrograde motion Specific orbital energy Specific relative angular momentum

List of orbits

Standard gravitational parameter

Small body orbiting a central body

Two bodies orbiting each other

Terminology and accuracy

See also

References