Astrodynamics/Classical Orbit Elements

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It is possible to specify an orbit entirely using a set of 5 parameters. With these 5 parameters, we can specify precisely where an orbit is, how it is oriented in 3-D space, and what size it is. If we have an optional sixth parameter, we can determine exactly where the satellite is in it's orbit at any arbitrary time t.

However, before we discuss the 6 orbit parameters, we need to introduce a few new terms.

If the earth's equator is a plane, the fundamental plane (as it is in the geocentric-equatorial coordinate system, which we will be using in this section), and the orbit forms a plane (the "orbital plane") that contains the vectors r and v, then the line formed by the intersection of these two planes is known as the line of nodes.

We can find the vector n by taking the cross product of the angular momentum vector, h, and the unit vector K:

${\displaystyle 𝐧=𝐡\times 𝐊}$

n is a unit vector on the line of nodes that points in the direction of the ascending node. The ascending node is the spot where the satellite crosses the equatorial plane in a northerly direction. Likewise, the descending node is the point where the satellite crosses the equatorial plane in the southerly direction.

In an equatorial orbit, n is undefined, and there are no nodes.

Direct means the satellite is traveling around the earth from west to east. Retrograde means the satellite is traveling from east to west.

This image shows two planes, the orbital plane (pale yellow) and the ecliptic (gray). The earth, or prime focus is considered to be at the dot at the center of the two planes. Notice how the orbit crosses the ecliptic at two points: once going northward (the ascending node), and once going southward (the descending node). The descending node is not marked in this picture, but it's location should be obvious. We will explane some of the other terms below.

Now that we have the node vector, along with the vectors r, v, and h, we can find our 5 classical orbital elements.

The semi-major axis, a is half the distance between the periapsis and the apoapsis.

The eccentricity e we have already seen defines the shape of the orbit.

The inclination, i is the angle between the K unit vector and the angular momentum vector h. It can be calculated using:

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${\displaystyle i=\arccos \frac{h_K}{h}}$

The angle of inclination is always less then 180°.

The longitude of the ascending node, Ω, is the angle between the ascending node and the I unit vector. It can be calculated as:

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${\displaystyle \mathrm{\Omega }=\arccos \frac{n_I}{n}}$

If the n_J component is greater then zero, then Ω is less then 180°. Otherwise, Ω is greater then 180°.

The argument of periapsis is the angle in the orbital plane between the ascending node and the periapsis. We can calculate it as:

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${\displaystyle \omega =\arccos \frac{𝐧\cdot 𝐞}{ne}}$

If e_K is greater then 0, then ω is less then 180°. Otherwise, ω is greater then 180°.

The time of periapsis passage is the time when the satellite reaches periapsis. We define this time as T_p. It can be determined from observation.

From the five classical orbital elements, we can determine r and v.

${\displaystyle 𝐫=r\cos (\nu )𝐏+r\sin (\nu )𝐐}$

${\displaystyle 𝐯=\sqrt{\frac{\mu }{p}}[-sin(\nu )𝐏+e𝐐+\cos (\nu )𝐐]}$

Where P and Q are unit vectors in the perifocal coordinate system. Using our coordinate transformations, we can convert these into geocentric-equatorial coordinates.