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Categories: Astrodynamics | Celestial mechanics

True anomaly

In astronomy, the true anomaly ( $T\,\!$ , also written $v\$ ) is the angle between the direction z-s of periapsis and the current position p of an object on its orbit, measured at the focus s of the ellipse (the point around which the object orbits). In the diagram below, true anomaly is the angle z-s-p.

Calculation from state vectors

For elliptic orbits true anomaly $T\,\!$ can be calculated from orbital state vectors as:

$T = \arccos { {\mathbf{e} \cdot \mathbf{r}} \over { \mathbf{\left |e \right |} \mathbf{\left |r \right |} }}$ (if $\mathbf{r} \cdot \mathbf{v} < 0$ then replace T by 2π − T)

where:

$\mathbf{v}\,$ is orbital velocity vector of the orbiting body,
$\mathbf{e}\,$ is eccentricity vector,
$\mathbf{r}\,$ is orbital position vector (segment sp) of the orbiting body.

For circular orbits this can be simplified to:

$T = \arccos { {\mathbf{n} \cdot \mathbf{r}} \over { \mathbf{\left |n \right |} \mathbf{\left |r \right |} }}$ (if $\mathbf{n} \cdot \mathbf{v} >0$ then replace T by 2π − T)

where:

$\mathbf{n}$ is vector pointing towards the ascending node (i.e. the z-component of $\mathbf{n}$ is zero).

For circular orbits with the inclination of zero this can be simplified further to:

$T = \arccos { r_x \over { \mathbf{\left |r \right |}}}$ (if $v_x\ > 0$ then replace T by 2π − T)

where:

$r_x \,$ is x-component of orbital position vector $\mathbf{r}$ ,
$v_x \,$ is x-component of orbital velocity vector $\mathbf{v}$ .

Other relations

The relation between T and E, the eccentric anomaly, is:

$\cos{T} = {{\cos{E} - e} \over {1 - e \cdot \cos{E}}},\,$

or equivalently

$\tan{T \over 2} = \sqrt{{{1+e} \over {1-e}}} \tan{E \over 2}.$

The relations between the radius (position vector magnitude) and the anomalies are:

$r = a \left ( 1 - e \cdot \cos{E} \right )\,\!$

and

$r = a{(1 - e^2) \over (1 + e \cdot \cos{T})}\,\!$

where a is the orbit's semi-major axis (segment cz).

See also

Categories: Astrodynamics | Celestial mechanics

01-04-2007 01:18:14
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