Several best practices are used to minimize the number of launched objects becoming uncontrollable space debris, varying in technique depending on the object's orbit. Most protective measures ensure that satellites and other artificial objects only remain in their operational orbits for as long as they are functional and controllable. These responsibilities fall on the satellite operator, who is bound by international agreements for how to dispose of orbiting objects.
Suborbital trajectories Objects launched onto suborbital trajectories such as
sounding rocket payloads and
ballistic missile warheads do not achieve orbital velocities and fall back to earth at the end of the flight, so they do not require any intentional care on the part of the operator to ensure reentry and disposal. The
Space Shuttle external tank is designed to quickly dispose of itself after launch. The large external tank remains attached to the Space Shuttle orbiter from liftoff until when it and the orbiter are traveling at just below orbital velocity and have an altitude of approximately 113 km (70 mi), at which point it detaches and follows a ballistic trajectory quickly reentering the atmosphere. Most of the external tank disintegrates due to the heat of reentry, while the orbiter uses
reaction control thrusters to complete its orbital insertion.
Low Earth orbit The vast majority of artificial satellites and space stations orbit in
Low Earth orbits (LEO), with mean altitudes lower than 2000 km (1200 mi). LEO satellites are close to the thicker parts of the atmosphere where safe reentry is practical because the
Delta-v required to decelerate from LEO is small. Most LEO satellites use the last of their remaining onboard
station-keeping fuel (used to maintain the satellite's orbit against forces like atmospheric drag that gradually perturb the orbit) to execute de-orbit burns and dispose of themselves. The ease of access for de-orbiting LEO satellites at end of life makes it a successful method for controlling the space debris risk in LEO.
Medium Earth orbit and higher Orbits with mean altitudes higher than LEO (such as
Medium Earth orbits (MEO),
Geosynchronous orbit/
Geostationary orbit (GSO/GEO), and other species) are far from the denser parts of the atmosphere, making full de-orbit burns significantly more impractical. Few satellite designs have sufficient fuel margins to be able to afford such a maneuver at the end of their lives. Satellites at altitudes towards the lower bound of MEO can use the "25-year rule" to decelerate with onboard propulsion so that it will fall out of orbit within 25 years, but this provision is only allowed if satellite operators can prove by statistical analysis that there is less than a 1/10,000 chance that the
atmospheric reentry will cause human injury or property damage. Satellites disposed of in this fashion reenter the atmosphere in an area of the South Pacific Ocean far from inhabited areas called the
spacecraft cemetery.
Graveyard orbits Spacecraft orbiting at higher altitudes between LEO and
High Earth orbit (HEO), most commonly in the highly specific and crowded GSO/GEO, are too far to make use of the "25-year rule". GSO and GEO require that the orbital plane be almost perfectly equatorial and the altitude be as close to a perfectly circular 35,786 km (22,236 mi), which means that space is limited and satellites cannot be allowed to stay past their useful life. Instead of decelerating for reentry, most satellites at these altitudes accelerate slightly into higher
graveyard orbits where they will forever remain out of the way of interaction with operational satellites.
Empty rocket stages remaining in orbit Historically, many
multi-stage launcher designs completely expended their fuel to achieve orbit and left their spent rocket stages in orbit, as in the former Soviet
Zenit family of rockets. These upper stages are large artificial satellites, which depending on the orbit can take many years to reenter. Most modern designs include sufficient fuel margins for de-orbit burns after injecting payload into orbit.
SpaceX's
Falcon 9 is a launch vehicle designed to minimize the effect of its upper stage on space debris. The rocket is composed of two stages, the first of which is suborbital. It reenters within minutes of launch, either intentionally using fuel reserved for stage recovery to land for reuse or is left to continue on its ballistic trajectory and disintegrate upon reentry into the atmosphere. Falcon 9 second stages are dealt with using different techniques depending on the orbit. For
Low Earth orbits, the second stage uses remaining fuel to perform a de-orbit burn and disintegrate in the atmosphere. Stages stranded in
Medium Earth orbits, like
Geostationary transfer orbits (GTO) and
Geostationary orbit (GEO), generally don't have sufficient fuel to de-orbit themselves. GTO trajectories are designed such that the second stage's orbit will naturally decay and reenter the atmosphere after a few months, while stages from missions targeting direct insertion into GEO will remain for a lot longer. == Collision prediction methods ==