Circular orbit

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Two bodies with a slight difference in mass orbiting around a common barycenter with circular orbits.

For other meanings of the term "orbit", see orbit (disambiguation)

In astrodynamics or celestial mechanics a circular orbit is an elliptic orbit with the eccentricity equal to 0. It is an example of a rotation around a fixed axis: this axis is the line through the center of mass perpendicular to the plane of motion.

1 Circular acceleration
2 Velocity
3 Orbital period
4 Energy
5 Equation of motion
6 Delta-v to reach a circular orbit
7 See also

Transverse acceleration (perpendicular to velocity) causes change in direction. If it is constant in magnitude and changing in direction with the velocity, we get a circular motion. For this centripetal acceleration we have

$\mathbf{a} = - \frac{v^2}{r} \frac{\mathbf{r}}{r} = - \omega^2 \mathbf{r}$

where:

$v\,$ is orbital velocity of orbiting body,
$r\,$ is radius of the circle
$\omega \$ is angular frequency, measured in radian per second.

Under standard assumptions the orbital velocity ( $v\,$ ) of a body traveling along circular orbit can be computed as:

$v=\sqrt{\mu\over{r}}$

where:

$r\,$ is radius of orbit equal to radial distance of orbiting body from central body,
$\mu\,$ is standard gravitational parameter.

Conclusion:

Velocity is constant along the path.

Under standard assumptions the orbital period ( $T\,\!$ ) of a body traveling along circular orbit can be computed as:

$T={2\pi\over{\sqrt{\mu}}}r^{3\over{2}}$

where:

$r\,$ is orbit radius equal to radial distance of orbiting body from central body,
$\mu\,$ is standard gravitational parameter.

Conclusions:

The orbital period is the same as that for an elliptic orbit with the semi-major axis ( $a\,\!$ ) equal to orbit radius.

Under standard assumptions, specific orbital energy ( $\epsilon\,$ ) is negative and the orbital energy conservation equation for this orbit takes the form:

${v^2\over{2}}-{\mu\over{r}}=-{\mu\over{2r}}=\epsilon< 0\,\!$

where:

$v\,$ is orbital velocity of orbiting body,
$r\,$ is radius of orbit equal to radial distance of orbiting body from central body,
$\mu\,$ is standard gravitational parameter.

The virial theorem applies even without taking a time-average:

the potential energy of the system is equal to twice the total energy
the kinetic energy of the system is equal to minus the total energy

Thus the escape velocity from any distance is √2 times the speed in a circular orbit at that distance: the kinetic energy is twice as much, hence the total energy is zero!

Under standard assumptions, the orbital equation becomes:

$r={{h^2}\over{\mu}}$

where:

$r\,$ is radial distance of orbiting body from central body,
$h\,$ is specific angular momentum of the orbiting body,
$\mu\,$ is standard gravitational parameter.

Maneuvering into a large circular orbit, e.g. a geostationary orbit, requires a larger delta-v than an escape orbit, although the latter implies getting arbitrarily far away and having more energy than needed for the orbital speed of the circular orbit. It is also a matter of maneuvering into the orbit. See also Hohmann transfer orbit.

v • d • e Orbits

Orbit types by characteristics:	Box orbit \| Circular orbit \| Ecliptic orbit \| Elliptic orbit \| Highly Elliptical Orbit \| Graveyard orbit \| Hyperbolic trajectory \| Inclined orbit \| Osculating orbit \| Parabolic trajectory \| Capture orbit \| Escape orbit \| Semi-synchronous orbit \| Subsynchronous orbit \| Synchronous orbit
Earth-centered orbits:	Geosynchronous orbit \| Geostationary orbit \| Sun-synchronous orbit \| Low Earth orbit \| Medium Earth Orbit \| Molniya orbit \| Near equatorial orbit \| Orbit of the Moon \| Polar orbit \| Polar sun synchronous orbit \| Tundra orbit
Orbits about other bodies:	Areosynchronous orbit \| Areostationary orbit \| Lunar orbit \| Heliocentric orbit \| Heliosynchronous orbit

Orbital elements:	Inclination ( $i\,\!$ ) \| Longitude of the ascending node ( $\Omega\,\!$ ) \| Eccentricity ( $e\,\!$ ) \| Argument of periapsis ( $\omega\,\!$ ) \| Semimajor axis ( $a\,\!$ ) \| Mean anomaly at epoch ( $M_o\,\!$ )
Other orbital parameters:	True anomaly ( $v\,$ ) \| Semi-major axis ( $a\,$ ) \| Semi-minor axis ( $b\,$ ) \| Linear eccentricity ( $\epsilon\,$ ) \| Eccentric anomaly ( $E\,$ ) \| Mean longitude ( $L\,$ ) \| True longitude ( $l\,$ ) \| Orbital period ( $T\,$ )
Orbital maneuvers:	Bi-elliptic transfer \| Geostationary transfer orbit \| Gravitational slingshot \| Hohmann transfer orbit \| Orbital inclination change \| Orbit phasing \| Space rendezvous

Other orbital mechanics topics:	Apsis \| Celestial coordinate system \| Delta-v budget \| Epoch \| Ephemeris \| Equatorial coordinate system \| Ground track \| Interplanetary Transport Network \| Kepler's laws of planetary motion \| Lagrangian point \| List of orbits \| n-body problem \| Orbit equation \| Orbital state vectors \| Retrograde and direct motion \| Specific orbital energy \| Specific relative angular momentum