Orbital speed

The orbital speed of a body, generally a planet, a natural satellite, an artificial satellite, or a multiple star, is the speed at which it orbits around the barycenter of a system, usually around a more massive body. It can be used to refer to either the mean orbital speed, i.e. the average speed as it completes an orbit, or the speed at a particular point in its orbit such as perihelia.^{[not verified in body]}

The orbital speed at any position in the orbit can be computed from the distance to the central body at that position, and the specific orbital energy, which is independent of position: the kinetic energy is the total energy minus the potential energy.

Radial trajectories

In the case of radial motion:^{[citation needed]}

If the specific orbital energy is positive, the body's kinetic energy is greater than its potential energy: The orbit is thus open, following a hyperbola with focus at the other body. See radial hyperbolic trajectory
For the zero-energy case, the body's kinetic energy is exactly equal to its potential energy: the orbit is thus a parabola with focus at the other body. See radial parabolic trajectory.
If the energy is negative, the body's potential energy is greater than its kinetic energy: The orbit is thus closed. The motion is on an ellipse with one focus at the other body. See radial elliptic trajectory, free-fall time.

Transverse orbital speed

The transverse orbital speed is inversely proportional to the distance to the central body because of the law of conservation of angular momentum, or equivalently, Kepler's second law. This states that as a body moves around its orbit during a fixed amount of time, the line from the barycenter to the body sweeps a constant area of the orbital plane, regardless of which part of its orbit the body traces during that period of time.^[1]

This law implies that the body moves slower near its apoapsis than near its periapsis, because at the smaller distance along the arc it needs to trace to cover the same area.

Mean orbital speed

For orbits with small eccentricity, the length of the orbit is close to that of a circular one, and the mean orbital speed can be approximated either from observations of the orbital period and the semimajor axis of its orbit, or from knowledge of the masses of the two bodies and the semimajor axis.^{[citation needed]}

v_o \approx {2 \pi a \over T}

v_o \approx \sqrt{\mu \over a}

where $v$ is the orbital velocity, $a$ is the length of the semimajor axis, $T$ is the orbital period, and $μ = GM$ is the standard gravitational parameter. Note that this is only an approximation that holds true when the orbiting body is of considerably lesser mass than the central one, and eccentricity is close to zero.

Taking into account the mass of the orbiting body,

v_o \approx \sqrt{G (m_1 + m_2) \over r}

where $m 1$ is the mass of the orbiting body, $m 2$ is the mass of the body being orbited, $r$ is specifically the distance between the two bodies (which is the sum of the distances from each to the center of mass), and $G$ is the gravitational constant. This is still a simplified version; it doesn't allow for elliptical orbits, but it does at least allow for bodies of similar masses.

When one of the masses is almost negligible compared to the other mass, as the case for Earth and Sun, one can approximate the previous formula to get:

v_o \approx \sqrt{\frac{GM}{r}}

or assuming $r$ equal to the body's radius

v_o \approx \frac{v_e}{\sqrt{2}}

Where $M$ is the (greater) mass around which this negligible mass or body is orbiting, and $v e$ is the escape velocity.

For an object in an eccentric orbit orbiting a much larger body, the length of the orbit decreases with orbital eccentricity $e$ , and is an ellipse. This can be used to obtain a more accurate estimate of the average orbital speed:

v_o = \frac{2\pi a}{T}\left[1-\frac{1}{4}e^2-\frac{3}{64}e^4 -\frac{5}{256}e^6 -\frac{175}{16384}e^8 - \dots \right]

^[2]

The mean orbital speed decreases with eccentricity.

Precise orbital speed

For the precise orbital speed of a body at any given point in its trajectory, both the mean distance and the precise distance are taken into account:

v = \sqrt {\mu \left({2 \over r} - {1 \over a}\right)}

where $μ$ is the standard gravitational parameter, $r$ is the distance at which the speed is to be calculated, and $a$ is the length of the semi-major axis of the elliptical orbit. For the Earth at perihelion,

v = \sqrt {1.327 \times 10^{20} ~m^3 s^{-2} \cdot \left({2 \over 1.471 \times 10^{11} ~m} - {1 \over 1.496 \times 10^{11} ~m}\right)} \approx 30,300 ~m/s

which is slightly faster than Earth's average orbital speed of 29,800 m/s, as expected from Kepler's 2nd Law.

Tangential velocities at altitude

orbit	Center-to-center distance	Altitude above the Earth's surface	Speed	Orbital period	Specific orbital energy
Standing on Earth's surface at the equator (for comparison -- not an orbit)	6,378 km	0 km	465.1 m/s (1,040 mph)	1 day (24h)	−62.6 MJ/kg
Orbiting at Earth's surface (equator)	6,378 km	0 km	7.9 km/s (17,672 mph)	1 h 24 min 18 sec	−31.2 MJ/kg
Low Earth orbit	6,600 to 8,400 km	200 to 2,000 km	circular orbit: 6.9 to 7.8 km/s (15,430 mph to 17,450 mph) respectively elliptic orbit: 6.5 to 8.2 km/s respectively	1 h 29 min to 2 h 8 min	−29.8 MJ/kg
Molniya orbit	6,900 to 46,300 km	500 to 39,900 km	1.5 to 10.0 km/s (3,335 mph to 22,370 mph) respectively	11 h 58 min	−4.7 MJ/kg
Geostationary	42,000 km	35,786 km	3.1 km/s (6,935 mph)	23 h 56 min	−4.6 MJ/kg
Orbit of the Moon	363,000 to 406,000 km	357,000 to 399,000 km	0.97 to 1.08 km/s (2,170 to 2,416 mph) respectively	27.3 days	−0.5 MJ/kg