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Encyclopedia > Orbital velocity vector

In astrodynamics or celestial dynamics orbital state vectors (sometimes State Vectors) are vectors of position ( $\mathbf{r}$ ) and velocity ( $\mathbf{v}$ ) that together with their time ( $t\,$ ) ( epoch) uniquely determine the state of an orbiting body.

State vectors are excellent for pre-launch orbital predictions when combined with time (epoch) expressed as an offset to the launch time. This makes the state vectors time-independent and good general prediction for orbit.

Orbital position vector and orbital velocity vector and other orbit's elements

Contents

4 Relation to orbital elements

5 See also

Frame of reference

The state vectors must be considered in a particular inertial frame of reference setting. For most practical applications in astrodynamics this is usually assumed to have the following properties:

cartesian right-handed coordinate system:
- with x-axis pointing to vernal equinox,
- with z-axis pointing upwards.

Position vector

The orbital position vector' $\mathbf{r}$ is a cartesian vector describing the position of the orbiting body in Frame of reference. Together, the orbital position vector and orbital velocity vector describe uniquely the state of an orbiting body and thus are called Orbital state vectors

Velocity vector

Orbital velocity vector $\mathbf{v}$ is a cartesian vector describing velocity of the orbiting body in Frame of reference . Orbital velocity vector together with orbital position vector describe uniquely state of the orbiting body and thus are called Orbital state vectors.

For any object moving through space, the velocity vector is tangent to the trajectory. If $\hat\mathbf{u}_t$ is the unit vector tangent to the trajectory, then

$\mathbf{v} = v\hat\mathbf{u}_t$

Derivation

Orbital velocity vector $\mathbf{v}\,$ can be derived from orbital position vector $\mathbf{r}\,$ by differentiation with respect to time:

$\mathbf{v} = {d\mathbf{r}\over{dt}}$

Relation to orbital elements

Orbital state vectors are equivalent to orbital elements (Keplerian elements) and each can be computed with each other (and used to derive other parameters of the orbit).

Both state vectors and orbital elements have unique adventages over the other. Computed in advance state vectors are more useful for orbital prediction. A time-independent state vector can be combined with the launch time using xxx method in order to arrive at a valid set of orbital elements whereas computed in advance orbital elements are valid only when launch occurs without the slip.

In astrodynamics Orbital state vectors ( $\mathbf{r}$ and $\mathbf{v}$ ) are used with the help of following auxiliary vectors:

specific relative angular momentum vector $\mathbf{h}=\mathbf{r}\times\mathbf{v}$

Orbital state vectors can than be used to calculate following orbital elements (Keplerian elements) (see their definitions for directions):

Inclination ( $i\,$ )
Eccentricity ( $e\,$ )
Longitude of ascending node ( $\Omega\,$ )
Argument of periapsis ( $\omega\,$ )
Mean anomaly ( $M\,$ )
Orbital period ( $T\,$ )

together with time ( $t\,$ ) ( epoch) those can be used to compute other orbit's parameters:

True anomaly ( $v\,$ )
Semi-major axis ( $a\,$ )
Semi-minor axis ( $b\,$ )
Linear eccentricity ( $\epsilon\,$ )
Periapsis distance ( $d_p\,$ )
Apoapsis distance ( $d_a\,$ )
Eccentric anomaly ( $E\,$ )
Mean longitude ( $L\,$ )
True longitude ( $l\,$ )

orbital velocity: Definition and Much More from Answers.com (652 words)
	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.
	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.
	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.

A Correction to a Famous Equation (4808 words)
	The radius of the circle is obviously not a velocity; it is a distance.
	Neither the orbital velocity nor the tangential velocity (nor the vector ∆v) change in magnitude over any interval, so calculating any change in any v, or an a that was a change in v, would only give us the number 0.
	The orbital "velocity" is a complex motion made up of the tangential velocity and the centripetal acceleration.

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