Satellite system comprising two satellites attached to each other and method for launching them into orbit

The invention claimed is: 1. A satellite system, comprising: a first satellite, called carrier satellite; and a second satellite, called piggyback satellite, said piggyback satellite being releasably fixed to said carrier satellite, said piggyback satellite being releasable, on command, from said carrier satellite to provoke separation of said carrier satellite and from said piggyback satellite, each of said carrier and piggyback satellites comprising an Earth face, wherein, said piggyback satellite comprises: a first propulsion system with a first propellant reserve suitable for keeping said piggyback satellite in orbit, and said carrier satellite comprises: a second propulsion system with a second propellant reserve configured to perform a change of orbit of said carrier satellite and of said piggyback satellite fixed to said carrier satellite, and said piggyback satellite is fixed onto the Earth face of the carrier satellite, such that the Earth face of said piggyback satellite is substantially at right angles to the Earth face of said carrier satellite. 2. The satellite system as claimed in claim 1 , wherein the carrier satellite and the piggyback satellite are arranged in a same launch vehicle. 3. The satellite system as claimed in claim 1 , wherein the carrier satellite and the piggyback satellite do not share any data bus. 4. The satellite system as claimed in claim 1 , wherein the piggyback satellite remains passive while fixed to the carrier satellite, and becomes active when separated from the carrier satellite. 5. The satellite system as claimed in claim 1 , wherein the carrier satellite comprises a substantially cylindrical rigid support structure which defines a longitudinal axis of said carrier satellite extending between the Earth face and an opposite anti-Earth face of said carrier satellite, and said piggyback satellite is fixed onto said support structure. 6. The satellite system as claimed in claim 1 , further comprising heating lines located in said piggyback satellite. 7. The satellite system as claimed in claim 1 , comprising a plurality of piggyback satellites stacked one on top of the other on the Earth face of the carrier satellite, the Earth face of each of said piggyback satellites being substantially at right angles to said Earth face of said carrier satellite. 8. A method for stationing on a mission orbit at least one of the satellites of a set of satellites comprising a first satellite, called carrier satellite, and a second satellite, called piggyback satellite, each of said satellites comprising an Earth face, said method comprising steps of: a) forming a satellite system as claimed in claim 1 , b) placing said satellite system in a launch vehicle suitable for transferring the satellite system from the Earth's surface to an initial orbit, c) injecting said satellite system into said initial orbit by said launch vehicle, d) transferring said satellite system, by the propulsion system of said carrier satellite, into or in proximity to the mission orbit of said piggyback satellite, and e) separating said piggyback satellite from said carrier satellite. 9. The method as claimed in claim 8 , wherein step a) comprises: forming a satellite system comprising a plurality of piggyback satellites stacked one on top of the other on the Earth face of the carrier satellite, the Earth face of each of said piggyback satellites being substantially at right angles to said Earth face of said carrier satellite, and and repeating steps d) and e) for each of said piggyback satellites. 10. The method as claimed in claim 8 , further comprising, after step e), a step f) of transferring said carrier satellite into a carrier satellite orbit. 11. The method as claimed in claim 10 , wherein the mission orbit of the carrier satellite is a geostationary orbit. 12. The method as claimed in claim 8 , wherein the mission orbit of the piggyback satellite is a geostationary orbit. 13. A satellite system, comprising: a first self-propelled satellite configured for changing an orbit of the satellite system, the first self-propelled satellite being called a carrier satellite; and a second self-propelled satellite, called a piggyback satellite, said piggyback satellite being releasably fixed to said carrier satellite, said piggyback satellite being releasable, on command, from said carrier satellite to provoke separation of said carrier satellite and from said piggyback satellite, wherein each of said carrier and piggyback satellites comprises an Earth face, and wherein said piggyback satellite is fixed onto the Earth face of the carrier satellite, such that the Earth face of said piggyback satellite is substantially at right angles to the Earth face of said carrier satellite.