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Theoretically, an orbit described by Kepler is ideal as Earth is considered to be a
perfect sphere and the force acting around the Earth is the centrifugal force. This force
is supposed to balance the gravitational pull of the earth.
In reality, other forces also play an important role and affect the motion of the
satellite. These forces are the gravitational forces of Sun and Moon along with the
atmospheric drag.
Effect of Sun and Moon is more pronounced on geostationary earth satellites where as
the atmospheric drag effect is more pronounced for low earth orbit satellites.
As the shape of Earth is not a perfect sphere, it causes some variations in the path
followed by the satellites around the primary. As the Earth is bulging from the
equatorial belt, and keeping in mind that an orbit is not a physical entity, and it is the
forces resulting from an oblate Earth which act on the satellite produce a change in
the orbital parameters.
This causes the satellite to drift as a result of regression of the nodes and the latitude
of the point of perigee (point closest to the Earth). This leads to rotation of the line of
apsides. As the orbit itself is moving with respect to the Earth, the resultant changes
are seen in the values of argument of perigee and right ascension of ascending node.
Due to the non-spherical shape of Earth, one more effect called as the “Satellite
Graveyard” is seen. The non-spherical shape leads to the small value of eccentricity at
the equatorial plane. This causes a gravity gradient on GEO satellite and makes them
drift to one of the two stable points which coincide with minor axis of the equatorial
ellipse.
Working satellites are made to drift back to their position but out-of-service satellites
are eventually drifted to these points, and making that point a Satellite Graveyard.
Atmospheric Drag
For Low Earth orbiting satellites, the effect of atmospheric drag is more pronounces.
The impact of this drag is maximum at the point of perigee. Drag (pull towards the
Earth) has an effect on velocity of Satellite (velocity reduces).
This causes the satellite to not reach the apogee height successive revolutions. This
leads to a change in value of semi-major axis and eccentricity. Satellites in service are
maneuvered by the earth station back to their original orbital position. Vaishnavi amamcherla (talk) 16:11, 14 November 2021 (UTC)[reply]