An orbiting cannon ball showing various sub-orbital and orbital possibilities.

Various earth orbits to scale; Cyan represents low earth orbit

A Low Earth Orbit (LEO) is generally defined as an orbit within the locus extending from the Earth?s surface up to an altitude of 2,000 km. Given the rapid orbital decay of objects below approximately 200 km, the commonly accepted definition for LEO is between 160 - 2000 km (100 - 1240 miles) above the Earth's surface.^[1][2]

With the exception of the lunar flights of the Apollo program, and the sub-orbital flights of the Mercury program and the X-15 and SpaceShipOne rocket planes, all human spaceflights have been in LEO, including all Space Shuttle and space station missions. The altitude record for a human spaceflight in LEO was Gemini 11 with an apogee of 1374.1 km.

Orbital Characteristics

Objects in LEO encounter atmospheric drag in the form of gases in the thermosphere (approximately 80-500 km up) or exosphere (approximately 500 km and up), depending on orbit height. LEO is an orbit around Earth between the atmosphere and below the inner Van Allen radiation belt. The altitude is usually not less than 300 km because that would be impractical due to the larger atmospheric drag.

Equatorial Low Earth Orbits (ELEO) are a subset of LEO. These orbits, with low inclination to the Equator, allow rapid revisit times and have the lowest delta-v requirement of any orbit. Orbits with a high inclination angle are usually called polar orbits.

Higher orbits include medium Earth orbit (MEO), sometimes called intermediate circular orbit (ICO), and further above, Geostationary orbit (GEO). Orbits higher than low orbit can lead to earlier failure of electronic components due to intense radiation and charge accumulation, while commercial devices such as laptops have been used successfully in LEO during manned flight.

Human use

International Space Station photographed from space shuttle Atlantis on 19 June 2007.

The International Space Station is in a LEO that varies from to above the Earth's surface.^[3]

While a majority of artificial satellites are placed in LEO, where they travel at about , making one complete revolution around the Earth in about 90 minutes, many communication satellites require geostationary orbits, and move at the same angular velocity as the Earth. Since it requires less energy to place a satellite into a LEO and the LEO satellite needs less powerful amplifiers for successful transmission, LEO is still used for many communication applications. Because these LEO orbits are not geostationary, a network (or "constellation") of satellites is required to provide continuous coverage. Lower orbits also aid remote sensing satellites because of the added detail that can be gained. Remote sensing satellites can also take advantage of sun-synchronous LEO orbits at an altitude of about and near polar inclination. ENVISAT is one example of an Earth observation satellite that makes use of this particular type of LEO.

Although the Earth's pull due to gravity in LEO is not much less than on the surface of the Earth, people and objects in orbit experience weightlessness due to the effects of freefall.

Atmospheric and gravity drag associated with launch typically add 1,500-2,000 m/s to the \Delta{v}\, (delta-V) required to reach normal LEO orbital velocity of around .

Space debris

The LEO environment is becoming congested with space debris which has caused a growing concern in recent years, since collisions at orbital velocities can be highly damaging or dangerous and can produce even more space debris in the process, called the Kessler Syndrome. The Space Control Center, part of United States Strategic Command (formerly the United States Space Command), currently tracks more than 8,500 objects larger than 10cm in LEO.^[4]

See also

• List of orbits
• Escape velocity
• Medium Earth Orbit (MEO)
• Highly Elliptical Orbit (HEO)
• specific orbital energy examples
• International Space Station
• Atmospheric reentry
• Satellite phone

References

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