The
artificial satellites orbit around the Earth in polar
or
geostationary
orbits.
A satellite remains in orbit around the Earth due to the balance between the Earth's gravitational force on the satellite and the centrifugal force of the rotation of the satellite around the Earth.
The gravity force of the Earth on a satellite is inversely proportional to the square of the distance between the Earth and the satellite, while the centrifugal force increases with its orbital velocity. There is a direct link between the satellite's distance from the Earth and its orbital velocity. In fact, a satellite, that orbits around the Earth at a low distance, experiences a strong attractive gravity force and consequently it has to move, for that distance, with a high velocity, adequate to generate a centrifugal force capable to balance the gravity force of the Earth.
This is true if the satellite is in vacuum; it means that the satellite must have a distance from the Earth such that the atmosphere braking effect can be neglected. Otherwise, the satellite would loose speed because of friction and it would fall, ultimately, on the Earth.
The satellites are placed into orbit by launchers.
Examples of modern launchers are:
Ariane
5 for
positioning the satellites in geostationary
or
polar
orbits.
Ariane
5 ECA V189 launcher is readied for lift-off...........Credits:
ESA/CNES/ARIANESPACE – Photo Optique Video CSG, 2009
Vega
for
transporting small loads (300 - 2000)kg in low
orbits or
polar
sun – synchronous orbits.
Vega
VV01 ready for launch................. Credits: ESA – S.
Corvaja, 2012
Watch these videos to find out more about the launchers and to experience the emotion to see a launch:
