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{{Short description|Orbit around Earth between 160 and 2000 km}}
{{Short description|Orbit around Earth between 160 and 2000 km}}
{{Comparison satellite navigation orbits}}


A '''low Earth orbit''' ('''LEO''') is an [[geocentric orbit|orbit around Earth]] with a [[orbital period|period]] of 128 minutes or less (making at least 11.25 orbits per day) and an [[orbital eccentricity|eccentricity]] less than 0.25.<ref>{{cite web |url=https://www.space-track.org/#/recent |title=Current Catalog Files |access-date=July 13, 2018 |quote=LEO: Mean Motion > 11.25 & Eccentricity < 0.25 |archive-date=June 26, 2018 |archive-url=https://web.archive.org/web/20180626190758/https://www.space-track.org/#/recent |url-status=live}}</ref> Most of the artificial objects in [[outer space]] are in LEO, with an altitude never more than about one-third of the [[Earth radius|radius of Earth]].<ref>{{cite journal |last1=Sampaio|first1=Jarbas |last2=Wnuk|first2=Edwin |last3=Vilhena de Moraes|first3=Rodolpho |last4=Fernandes|first4=Sandro |date=2014-01-01 |title=Resonant Orbital Dynamics in LEO Region: Space Debris in Focus |url=https://www.researchgate.net/publication/273597440 |journal=Mathematical Problems in Engineering |volume=2014 |page=Figure 1: Histogram of the mean motion of the cataloged objects |doi=10.1155/2014/929810 |doi-access=free |access-date=2018-07-13 |archive-date=2021-10-01 |archive-url=https://web.archive.org/web/20211001030902/https://www.researchgate.net/publication/273597440_Resonant_Orbital_Dynamics_in_LEO_Region_Space_Debris_in_Focus |url-status=live}}</ref>
A '''low Earth orbit''' ('''LEO''') is an [[geocentric orbit|orbit around Earth]] with a [[orbital period|period]] of 128 minutes or less (making at least 11.25 orbits per day) and an [[orbital eccentricity|eccentricity]] less than 0.25.<ref>{{cite web |url=https://www.space-track.org/#/recent |title=Current Catalog Files |access-date=July 13, 2018 |quote=LEO: Mean Motion > 11.25 & Eccentricity < 0.25 |archive-date=June 26, 2018 |archive-url=https://web.archive.org/web/20180626190758/https://www.space-track.org/#/recent |url-status=live}}</ref> Most of the artificial objects in [[outer space]] are in LEO, with an altitude never more than about one-third of the [[Earth radius|radius of Earth]] (or about 2000 kilometers).<ref>{{cite journal |last1=Sampaio|first1=Jarbas |last2=Wnuk|first2=Edwin |last3=Vilhena de Moraes|first3=Rodolpho |last4=Fernandes|first4=Sandro |date=2014-01-01 |title=Resonant Orbital Dynamics in LEO Region: Space Debris in Focus |url=https://www.researchgate.net/publication/273597440 |journal=Mathematical Problems in Engineering |volume=2014 |page=Figure 1: Histogram of the mean motion of the cataloged objects |doi=10.1155/2014/929810 |doi-access=free |access-date=2018-07-13 |archive-date=2021-10-01 |archive-url=https://web.archive.org/web/20211001030902/https://www.researchgate.net/publication/273597440_Resonant_Orbital_Dynamics_in_LEO_Region_Space_Debris_in_Focus |url-status=live}}</ref>


The term ''LEO region'' is also used for the area of space below an [[altitude]] of {{cvt|2000|km|mi}} (about one-third of Earth's radius).<ref name="UNOOSA">{{cite web |date=September 2007 |title=IADC Space Debris Mitigation Guidelines |url=http://www.unoosa.org/documents/pdf/spacelaw/sd/IADC-2002-01-IADC-Space_Debris-Guidelines-Revision1.pdf |publisher=INTER-AGENCY SPACE DEBRIS COORDINATION COMMITTEE: Issued by Steering Group and Working Group 4 |quote=Region A, Low Earth Orbit (or LEO) Region – spherical region that extends from the Earth's surface up to an altitude (Z) of 2,000 km |access-date=2018-07-17 |archive-date=2018-07-17 |archive-url=https://web.archive.org/web/20180717154257/http://www.unoosa.org/documents/pdf/spacelaw/sd/IADC-2002-01-IADC-Space_Debris-Guidelines-Revision1.pdf |url-status=live}}</ref> Objects in orbits that pass through this zone, even if they have an [[apogee]] further out or are [[sub-orbital spaceflight|sub-orbital]], are carefully tracked since they present a collision risk to the many LEO satellites.
The term ''LEO region'' is also used for the area of space below an [[altitude]] of {{cvt|2000|km|mi}} (about one-third of Earth's radius).<ref name="UNOOSA">{{cite web |date=September 2007 |title=IADC Space Debris Mitigation Guidelines |url=http://www.unoosa.org/documents/pdf/spacelaw/sd/IADC-2002-01-IADC-Space_Debris-Guidelines-Revision1.pdf |publisher=INTER-AGENCY SPACE DEBRIS COORDINATION COMMITTEE: Issued by Steering Group and Working Group 4 |quote=Region A, Low Earth Orbit (or LEO) Region – spherical region that extends from the Earth's surface up to an altitude (Z) of 2,000 km |access-date=2018-07-17 |archive-date=2018-07-17 |archive-url=https://web.archive.org/web/20180717154257/http://www.unoosa.org/documents/pdf/spacelaw/sd/IADC-2002-01-IADC-Space_Debris-Guidelines-Revision1.pdf |url-status=live}}</ref> Objects in orbits that pass through this zone, even if they have an [[apogee]] further out or are [[sub-orbital spaceflight|sub-orbital]], are carefully tracked since they present a collision risk to the many LEO satellites.


All crewed [[space station]]s to date have been within LEO. From 1968 to 1972, the [[Apollo program]]'s lunar missions sent humans beyond LEO. Since the end of the Apollo program, no [[human spaceflight]]s have been beyond LEO.
No [[human spaceflight]]s other than the lunar missions of the [[Apollo program]] have taken place beyond LEO. All crewed [[space station]]s to date have operated within LEO.


== Defining characteristics ==
== Defining characteristics ==
A wide variety of sources<ref>{{Cite web|title=Definition of LOW EARTH ORBIT|url=https://www.merriam-webster.com/dictionary/low%20earth%20orbit|access-date=2018-07-08|website=Merriam-Webster Dictionary|language=en|archive-date=2018-07-08|archive-url=https://web.archive.org/web/20180708162215/https://www.merriam-webster.com/dictionary/low%20earth%20orbit|url-status=live}}</ref><ref>{{Cite web|title=Frequently Asked Questions|url=https://www.faa.gov/space/additional_information/faq/#s1|access-date=2020-02-14|publisher=FAA|language=en-us|quote=LEO refers to orbits that are typically less than 2,400 km (1,491 mi) in altitude.|archive-date=2020-06-02|archive-url=https://web.archive.org/web/20200602021356/https://www.faa.gov/space/additional_information/faq/#s1|url-status=live}}</ref><ref>{{Cite news|last=Campbell|first=Ashley|date=2015-07-10|title=SCaN Glossary|language=en|publisher=NASA|url=https://www.nasa.gov/directorates/heo/scan/definitions/glossary/index.html#L|access-date=2018-07-12|quote=Low Earth Orbit (LEO): A geocentric orbit with an altitude much less than the Earth's radius. Satellites in this orbit are between 80 and 2000 kilometers above the Earth's surface.|archive-date=2020-08-03|archive-url=https://web.archive.org/web/20200803122937/https://www.nasa.gov/directorates/heo/scan/definitions/glossary/index.html#L|url-status=live}}</ref> define LEO in terms of [[altitude]]. The altitude of an object in an [[elliptic orbit]] can vary significantly along the orbit. Even for [[circular orbit]]s, the altitude above ground can vary by as much as {{cvt|30|km|mi}} (especially for [[polar orbit]]s) due to the [[flattening|oblateness]] of [[figure of the Earth|Earth's spheroid figure]] and local [[topography]]. While definitions based on altitude are inherently ambiguous, most of them fall within the range specified by an orbit period of 128 minutes because, according to [[orbital period|Kepler's third law]], this corresponds to a [[semi-major and semi-minor axes|semi-major axis]] of {{cvt|8413|km|mi}}. For circular orbits, this in turn corresponds to an altitude of {{cvt|2042|km|mi}} above the mean radius of Earth, which is consistent with some of the upper altitude limits in some LEO definitions.
A wide variety of sources<ref>{{Cite web|title=Definition of LOW EARTH ORBIT|url=https://www.merriam-webster.com/dictionary/low%20earth%20orbit|access-date=2018-07-08|website=Merriam-Webster Dictionary|language=en|archive-date=2018-07-08|archive-url=https://web.archive.org/web/20180708162215/https://www.merriam-webster.com/dictionary/low%20earth%20orbit|url-status=live}}</ref><ref>{{Cite web|title=Frequently Asked Questions|url=https://www.faa.gov/space/additional_information/faq/#s1|access-date=2020-02-14|publisher=FAA|language=en-us|quote=LEO refers to orbits that are typically less than 2,400 km (1,491 mi) in altitude.|archive-date=2020-06-02|archive-url=https://web.archive.org/web/20200602021356/https://www.faa.gov/space/additional_information/faq/#s1|url-status=live}}</ref><ref>{{Cite news|last=Campbell|first=Ashley|date=2015-07-10|title=SCaN Glossary|language=en|publisher=NASA|url=https://www.nasa.gov/directorates/heo/scan/definitions/glossary/index.html#L|access-date=2018-07-12|quote=Low Earth Orbit (LEO): A geocentric orbit with an altitude much less than the Earth's radius. Satellites in this orbit are between 80 and 2000 kilometers above the Earth's surface.|archive-date=2020-08-03|archive-url=https://web.archive.org/web/20200803122937/https://www.nasa.gov/directorates/heo/scan/definitions/glossary/index.html#L|url-status=live}}</ref> define LEO in terms of [[altitude]]. The altitude of an object in an [[elliptic orbit]] can vary significantly along the orbit. Even for [[circular orbit]]s, the altitude above ground can vary by as much as {{cvt|30|km|mi}} (especially for [[polar orbit]]s) due to the [[flattening|oblateness]] of [[figure of the Earth|Earth's spheroid figure]] and local [[topography]]. While definitions based on altitude are inherently ambiguous, most of them fall within the range specified by an orbit period of 128 minutes because, according to [[orbital period|Kepler's third law]], this corresponds to a [[semi-major and semi-minor axes|semi-major axis]] of {{cvt|8413|km|mi}}. For circular orbits, this in turn corresponds to an altitude of {{cvt|2042|km|mi}} above the mean radius of Earth, which is consistent with some of the upper altitude limits in some LEO definitions.


The LEO region is defined by some sources as a region in space that LEO orbits occupy.<ref name="UNOOSA" /><ref>{{Cite news|others=David Hitt : NASA Educational Technology Services, Alice Wesson : JPL, J.D. Harrington : HQ;, Larry Cooper : HQ;, Flint Wild : MSFC;, Ann Marie Trotta : HQ;, Diedra Williams : MSFC|date=2015-06-01|title=What Is an Orbit?|language=en|work=NASA|url=https://www.nasa.gov/audience/forstudents/5-8/features/nasa-knows/what-is-orbit-58.html|access-date=2018-07-08|quote=LEO is the first 100 to 200 miles (161 to 322&nbsp;km) of space.|archive-date=2018-03-27|archive-url=https://web.archive.org/web/20180327095840/https://www.nasa.gov/audience/forstudents/5-8/features/nasa-knows/what-is-orbit-58.html|url-status=live}}</ref><ref>{{Cite news|last=Steele|first=Dylan|date=2016-05-03|title=A Researcher's Guide to: Space Environmental Effects|language=en|page=7|work=NASA|url=https://www.nasa.gov/connect/ebooks/researchers_guide_space_environment_detail.html|access-date=2018-07-12|quote=the low-Earth orbit (LEO) environment, defined as 200–1,000 km above Earth's surface|archive-date=2016-11-17|archive-url=https://web.archive.org/web/20161117060640/http://www.nasa.gov/connect/ebooks/researchers_guide_space_environment_detail.html|url-status=live}}</ref> Some [[highly elliptical orbit]]s may pass through the LEO region near their lowest altitude (or [[apsis|perigee]]) but are not in an LEO orbit because their highest altitude (or [[apsis|apogee]]) exceeds {{cvt|2000|km|mi}}. [[sub-orbital spaceflight|Sub-orbital]] objects can also reach the LEO region but are not in an LEO orbit because they [[atmospheric entry|re-enter the atmosphere]]. The distinction between LEO orbits and the LEO region is especially important for analysis of possible collisions between objects which may not themselves be in LEO but could collide with satellites or debris in LEO orbits.
The LEO region is defined by some sources as a region in space that LEO orbits occupy.<ref name="UNOOSA" /><ref>{{Cite news|others=David Hitt : NASA Educational Technology Services, Alice Wesson : JPL, J.D. Harrington : HQ;, Larry Cooper : HQ;, Flint Wild : MSFC;, Ann Marie Trotta : HQ;, Diedra Williams : MSFC|date=2015-06-01|title=What Is an Orbit?|language=en|work=NASA|url=https://www.nasa.gov/audience/forstudents/5-8/features/nasa-knows/what-is-orbit-58.html|access-date=2018-07-08|quote=LEO is the first 100 to 200 miles (161 to 322&nbsp;km) of space.|archive-date=2018-03-27|archive-url=https://web.archive.org/web/20180327095840/https://www.nasa.gov/audience/forstudents/5-8/features/nasa-knows/what-is-orbit-58.html|url-status=live}}</ref><ref>{{Cite news|last=Steele|first=Dylan|date=2016-05-03|title=A Researcher's Guide to: Space Environmental Effects|language=en|page=7|work=NASA|url=https://www.nasa.gov/connect/ebooks/researchers_guide_space_environment_detail.html|access-date=2018-07-12|quote=the low-Earth orbit (LEO) environment, defined as 200–1,000 km above Earth's surface|archive-date=2016-11-17|archive-url=https://web.archive.org/web/20161117060640/http://www.nasa.gov/connect/ebooks/researchers_guide_space_environment_detail.html|url-status=live}}</ref> Some [[highly elliptical orbit]]s may pass through the LEO region near their lowest altitude (or [[apsis|perigee]]) but are not in a LEO orbit because their highest altitude (or [[apsis|apogee]]) exceeds {{cvt|2000|km|mi|0}}. [[sub-orbital spaceflight|Sub-orbital]] objects can also reach the LEO region but are not in a LEO orbit because they [[atmospheric entry|re-enter the atmosphere]]. The distinction between LEO orbits and the LEO region is especially important for analysis of possible collisions between objects which may not themselves be in LEO but could collide with satellites or debris in LEO orbits.


[[File:Orbitalaltitudes.svg|center|700px]]
[[File:Orbitalaltitudes.svg|center|700px]]
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The mean orbital velocity needed to maintain a stable low Earth orbit is about {{convert|7.8|km/s|mi/s|sigfig=2|abbr=on}}, which translates to {{convert|28000|km/h|mi/h|sigfig=2|abbr=on}}. However, this depends on the exact altitude of the orbit. Calculated for a circular orbit of {{convert|200|km|abbr=on}} the orbital velocity is {{convert|7.79|km/s|mi/s|sigfig=3|abbr=on}}, but for a higher {{convert|1500|km|abbr=on}} orbit the velocity is reduced to {{convert|7.12|km/s|mi/s|sigfig=3|abbr=on}}.<ref>{{Cite web|url=http://www.spaceacademy.net.au/watch/track/leopars.htm|title=LEO parameters|website=www.spaceacademy.net.au|access-date=2015-06-12|archive-date=2016-02-11|archive-url=https://web.archive.org/web/20160211202014/http://www.spaceacademy.net.au/watch/track/leopars.htm|url-status=live}}</ref> The launch vehicle's [[delta-v]] needed to achieve low Earth orbit starts around {{convert|9.4|km/s|mi/s|sigfig=2|abbr=on}}.
The mean orbital velocity needed to maintain a stable low Earth orbit is about {{convert|7.8|km/s|mi/s|sigfig=2|abbr=on}}, which translates to {{convert|28000|km/h|mi/h|sigfig=2|abbr=on}}. However, this depends on the exact altitude of the orbit. Calculated for a circular orbit of {{convert|200|km|abbr=on}} the orbital velocity is {{convert|7.79|km/s|mi/s|sigfig=3|abbr=on}}, but for a higher {{convert|1500|km|abbr=on}} orbit the velocity is reduced to {{convert|7.12|km/s|mi/s|sigfig=3|abbr=on}}.<ref>{{Cite web|url=http://www.spaceacademy.net.au/watch/track/leopars.htm|title=LEO parameters|website=www.spaceacademy.net.au|access-date=2015-06-12|archive-date=2016-02-11|archive-url=https://web.archive.org/web/20160211202014/http://www.spaceacademy.net.au/watch/track/leopars.htm|url-status=live}}</ref> The launch vehicle's [[delta-v]] needed to achieve low Earth orbit starts around {{convert|9.4|km/s|mi/s|sigfig=2|abbr=on}}.


The pull of [[gravity]] in LEO is only slightly less than on the Earth's surface. This is because the distance to LEO from the Earth's surface is much less than the Earth's radius. However, an object in orbit is in a permanent [[free fall]] around Earth, because in orbit both the [[Gravity|gravitational force]] and the [[centrifugal force]] balance out each other.{{efn|It is important to note here that “free fall” by definition requires that ''gravity'' is the only force acting on the object. That definition is still fulfilled when falling around Earth, as the other force, the ''centrifugal force'' is a [[fictitious force]].}} As a result, spacecraft in orbit continue to stay in orbit, and people inside or outside such craft continuously experience [[weightlessness]].
The pull of [[gravity]] in LEO is only slightly less than on the Earth's surface. This is because the distance to LEO from the Earth's surface is much less than the Earth's radius. However, an object in orbit is in a permanent [[free fall]] around Earth, because in orbit the [[Gravity|gravitational force]] and the [[centrifugal force]] balance each other out.{{efn|It is important to note here that “free fall” by definition requires that ''gravity'' is the only force acting on the object. That definition is still fulfilled when falling around Earth, as the other force, the ''centrifugal force'' is a [[fictitious force]].}} As a result, spacecraft in orbit continue to stay in orbit, and people inside or outside such craft continuously experience [[weightlessness]].


Objects in LEO encounter atmospheric drag from [[gases]] in the [[thermosphere]] (approximately 80–600&nbsp;km above the surface) or [[exosphere]] (approximately {{cvt|600|km|-2|disp=or}} and higher), depending on orbit height. Orbits of satellites that reach altitudes below {{cvt|300|km}} decay fast due to atmospheric drag. Objects in LEO orbit Earth between the denser part of the atmosphere and below the inner [[Van Allen radiation belt]].
Objects in LEO encounter atmospheric drag from [[gases]] in the [[thermosphere]] (approximately 80–600&nbsp;km above the surface) or [[exosphere]] (approximately {{cvt|600|km|-2|disp=or}} and higher), depending on orbit height. Orbits of satellites that reach altitudes below {{cvt|300|km}} decay fast due to atmospheric drag. Objects in LEO orbit Earth between the denser part of the atmosphere and below the inner [[Van Allen radiation belt]].


Equatorial low Earth orbits ('''ELEO''') are a subset of LEO. These orbits, with low inclination to the Equator, allow rapid revisit times of low-latitude places on Earth and have the lowest [[delta-v]] requirement (i.e., fuel spent) of any orbit, provided they have the direct (not retrograde) orientation with respect to the Earth's rotation. Orbits with a very high inclination angle to the equator are usually called [[polar orbit]]s or [[Sun-synchronous orbit|Sun-synchronous orbits]].
Equatorial low Earth orbits ('''ELEO''') are a subset of LEO. These orbits, with low inclination to the Equator, allow rapid revisit times over low-latitude locations on Earth. Prograde equatorial LEOs also have lower [[delta-v]] launch requirements because they take advantage of the Earth's rotation. Other useful LEO orbits including [[polar orbit]]s and [[Sun-synchronous orbit]]s have a higher inclinations to the equator and provide coverage for higher latitudes on Earth.
Some of the first generation of [[Starlink]] satellites used polar orbits which provide coverage everywhere on Earth. Later Starlink constellations orbit at a lower inclination and provide more coverage for populated areas.


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 early failure of electronic components due to intense [[radiation]] and charge accumulation.
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 early failure of electronic components due to intense [[radiation]] and charge accumulation.


In 2017, "very low Earth orbits" ('''VLEO''') began to be seen in [[regulatory agency|regulatory]] filings. These orbits, below about {{Cvt|450|km|mi|-1}}, require the use of novel technologies for [[orbit raising]] because they operate in orbits that would ordinarily decay too soon to be economically useful.<ref>{{Cite journal|last1=Crisp|first1=N. H.|last2=Roberts|first2=P. C. E.|last3=Livadiotti|first3=S.|last4=Oiko|first4=V. T. A.|last5=Edmondson|first5=S.|last6=Haigh|first6=S. J.|last7=Huyton|first7=C.|last8=Sinpetru|first8=L.|last9=Smith|first9=K. L.|last10=Worrall|first10=S. D.|last11=Becedas|first11=J.|date=August 2020|title=The Benefits of Very Low Earth Orbit for Earth Observation Missions|journal=[[Progress in Aerospace Sciences]]|volume=117|pages=100619|doi=10.1016/j.paerosci.2020.100619|arxiv=2007.07699|bibcode=2020PrAeS.11700619C|s2cid=220525689}}</ref><ref name=pa20170303>{{cite news |last=Messier |first=Doug |url=http://www.parabolicarc.com/2017/03/03/spacex-launch-12000-satellites/ |title=SpaceX Wants to Launch 12,000 Satellites |work=Parabolic Arc |date=2017-03-03 |access-date=2018-01-22 |archive-date=2020-01-22 |archive-url=https://web.archive.org/web/20200122203256/http://www.parabolicarc.com/2017/03/03/spacex-launch-12000-satellites/ |url-status=live }}</ref>
In 2017, "[[very low Earth orbit]]s" ('''VLEO''') began to be seen in [[regulatory agency|regulatory]] filings. These orbits, below about {{Cvt|450|km|mi|-1}}, require the use of novel technologies for [[orbit raising]] because they operate in orbits that would ordinarily decay too soon to be economically useful.<ref>{{Cite journal|last1=Crisp|first1=N. H.|last2=Roberts|first2=P. C. E.|last3=Livadiotti|first3=S.|last4=Oiko|first4=V. T. A.|last5=Edmondson|first5=S.|last6=Haigh|first6=S. J.|last7=Huyton|first7=C.|last8=Sinpetru|first8=L.|last9=Smith|first9=K. L.|last10=Worrall|first10=S. D.|last11=Becedas|first11=J.|date=August 2020|title=The Benefits of Very Low Earth Orbit for Earth Observation Missions|journal=[[Progress in Aerospace Sciences]]|volume=117|pages=100619|doi=10.1016/j.paerosci.2020.100619|arxiv=2007.07699|bibcode=2020PrAeS.11700619C|s2cid=220525689}}</ref><ref name=pa20170303>{{cite news |last=Messier |first=Doug |url=http://www.parabolicarc.com/2017/03/03/spacex-launch-12000-satellites/ |title=SpaceX Wants to Launch 12,000 Satellites |work=Parabolic Arc |date=2017-03-03 |access-date=2018-01-22 |archive-date=2020-01-22 |archive-url=https://web.archive.org/web/20200122203256/http://www.parabolicarc.com/2017/03/03/spacex-launch-12000-satellites/ |url-status=live }}</ref>


==Use==
==Use==
[[File:Sunrise To Sunset Aboard The ISS.OGG|thumb|Roughly half an orbit of the [[International Space Station]].]]
[[File:Sunrise To Sunset Aboard The ISS.OGG|thumb|Roughly half an orbit of the [[International Space Station]]]]


A low Earth orbit requires the lowest amount of energy for satellite placement. It provides high bandwidth and low communication [[latency (engineering)|latency]]. Satellites and space stations in LEO are more accessible for crew and servicing.
A low Earth orbit requires the lowest amount of energy for satellite placement. It provides high bandwidth and low communication [[latency (engineering)|latency]]. Satellites and space stations in LEO are more accessible for crew and servicing.
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=== Disadvantages ===
=== Disadvantages ===
Unlike [[geosynchronous satellite]], satellites in LEO have a small [[field of view]] and so can observe and communicate with only a fraction of the Earth at a time. This means that a network (or "[[Satellite constellation|constellation]]") of satellites is required to provide continuous coverage. Satellites in lower regions of LEO also suffer from fast [[orbital decay]] and require either periodic re-boosting to maintain a stable orbit or launching replacement satellites when old ones re-enter.
Unlike [[geosynchronous satellite|geosynchronous satellites]], satellites in low orbit have a small [[field of view]] and can only observe and communicate with a fraction of the Earth at a given time. This means that a large network (or [[Satellite constellation|constellation]]) of satellites is required to provide continuous coverage.

Satellites at lower altitudes of orbit are in the atmosphere and suffer from rapid [[orbital decay]], requiring either periodic re-boosting to maintain stable orbits, or the launching of replacements for those that re-enter the atmosphere. The effects of adding such quantities of vaporized metals to Earth's [[stratosphere]] are potentially of concern but currently unknown.<ref>https://www.scientificamerican.com/article/space-junk-is-polluting-earths-stratosphere-with-vaporized-metal/</ref>


===Examples===
===Examples===
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* [[Earth observation satellite]]s, also known as [[remote sensing]] satellites, including [[spy satellite]]s and other [[Earth imaging]] satellites, use LEO as they are able to see the surface of the Earth more clearly by being closer to it. A majority of artificial [[satellite]]s are placed in LEO.<ref>{{Cite web|title = NASA Earth Observatory|url = http://earthobservatory.nasa.gov/Features/OrbitsCatalog/|website = earthobservatory.nasa.gov|date = 2009-09-04|access-date = 2015-11-28|language = en|first = Riebeek|last = Holli|archive-date = 2018-05-27|archive-url = https://web.archive.org/web/20180527202627/https://earthobservatory.nasa.gov/Features/OrbitsCatalog/|url-status = live}}</ref> Satellites can also take advantage of consistent lighting of the surface below via [[Sun-synchronous orbit|Sun-synchronous LEO orbits]] at an altitude of about {{convert|800|km|mi|-1|abbr=on}} and near polar inclination. [[Envisat]] (2002–2012) is one example.
* [[Earth observation satellite]]s, also known as [[remote sensing]] satellites, including [[spy satellite]]s and other [[Earth imaging]] satellites, use LEO as they are able to see the surface of the Earth more clearly by being closer to it. A majority of artificial [[satellite]]s are placed in LEO.<ref>{{Cite web|title = NASA Earth Observatory|url = http://earthobservatory.nasa.gov/Features/OrbitsCatalog/|website = earthobservatory.nasa.gov|date = 2009-09-04|access-date = 2015-11-28|language = en|first = Riebeek|last = Holli|archive-date = 2018-05-27|archive-url = https://web.archive.org/web/20180527202627/https://earthobservatory.nasa.gov/Features/OrbitsCatalog/|url-status = live}}</ref> Satellites can also take advantage of consistent lighting of the surface below via [[Sun-synchronous orbit|Sun-synchronous LEO orbits]] at an altitude of about {{convert|800|km|mi|-1|abbr=on}} and near polar inclination. [[Envisat]] (2002–2012) is one example.
* The [[Hubble Space Telescope]] orbits at about {{convert|540|km|mi|abbr=on}} above Earth.
* The [[Hubble Space Telescope]] orbits at about {{convert|540|km|mi|abbr=on}} above Earth.
* The Chinese [[Tiangong space station]] was launched in April of 2021 and currently orbits between about {{convert|340|km}} and {{convert|450|km}}.
* The Chinese [[Tiangong space station]] was launched in April 2021, and currently orbits between about {{convert|340|km}} and {{convert|450|km}}.
* The [[gravimetry]] mission [[GRACE-FO]] orbits at about {{convert|500|km|mi|abbr=on}} as did its predecessor, [[Gravity Recovery and Climate Experiment|GRACE]].

; In fiction
* In the film ''[[2001: A Space Odyssey (film)|2001: A Space Odyssey]]'', Earth's transit station ("Space Station V") "orbited 300 km above Earth".<ref>{{Cite web|url=https://www.esa.int/ESA_Multimedia/Images/2012/01/Space_station_from_2001_A_Space_Odyssey|title = Space station from 2001: A Space Odyssey}}</ref>


==== Former ====
==== Former ====
* The Chinese [[Tiangong-1]] station was in orbit at about {{convert|355|km}},<ref>{{Cite web |url=http://www.people.com.cn/h/2011/1001/c25408-1418236438.html |title="天宫一号成功完成二次变轨" |access-date=2020-10-13 |archive-date=2011-11-13 |archive-url=https://web.archive.org/web/20111113130054/http://www.people.com.cn/h/2011/1001/c25408-1418236438.html |url-status=dead }}</ref> until its de-orbiting in 2018.
* The Chinese [[Tiangong-1]] station was in orbit at about {{convert|355|km}},<ref>{{Cite web |url=http://www.people.com.cn/h/2011/1001/c25408-1418236438.html |title="天宫一号成功完成二次变轨" |access-date=2020-10-13 |archive-date=2011-11-13 |archive-url=https://web.archive.org/web/20111113130054/http://www.people.com.cn/h/2011/1001/c25408-1418236438.html |url-status=dead }}</ref> until its de-orbiting in 2018.
* The Chinese [[Tiangong-2]] station was in orbit at about {{convert|370|km|mi|abbr=on}}, until its de-orbiting in 2019.
* The Chinese [[Tiangong-2]] station was in orbit at about {{convert|370|km|mi|abbr=on}}, until its de-orbiting in 2019.
* [[Gravimetry]] missions such as [[Gravity Field and Steady-State Ocean Circulation Explorer|GOCE]] orbited at about {{convert|255|km|mi|abbr=on}} to measure Earth's gravity field at highest sensitivity. The mission lifetime was limited because of atmospheric drag. [[Gravity Recovery and Climate Experiment|GRACE]] and [[GRACE-FO]] were orbiting at about {{convert|500|km|mi|abbr=on}}.
* [[Gravity Field and Steady-State Ocean Circulation Explorer|GOCE]], another gravimetry mission, orbited at about {{convert|255|km|mi|abbr=on}}.

==== In fiction ====
* In the film ''[[2001: A Space Odyssey (film)|2001: A Space Odyssey]]'', Earth's transit station ("Space Station V") "orbited 300 km above Earth".<ref>{{Cite web |title=Space station from 2001: A Space Odyssey |url=https://www.esa.int/ESA_Multimedia/Images/2012/01/Space_station_from_2001_A_Space_Odyssey}}</ref>


==Space debris==
==Space debris==
{{missing information|section|debris lifespan|date=August 2023}}
The LEO environment is becoming congested with [[space debris]] because of the frequency of object launches.<ref>{{Cite web|last=United Nations Office for Outer Space Affairs|date=2010|title=Space Debris Mitigation Guidelines of the Committee on the Peaceful Uses of Outer Space|url=https://www.iadc-home.org/documents_public/view/search_field/eNortjI2tlJy1CsuTcpKTS7RdtTLS8xNBVIlielAMjk_ryQ1r6RYyRpcMAypDUU~/page/1/id/126#u|url-status=live|access-date=October 19, 2021|website=Inter-Agency Space Debris Coordination Committee (IADC)}}</ref> This has caused growing concern in recent years, since collisions at orbital velocities can be dangerous or deadly. Collisions can produce additional space debris, creating a [[domino effect]] known as [[Kessler syndrome]]. The Orbital Debris Program, part of [[NASA]], tracks over 25,000 objects larger than 10 cm in LEO, the estimated number between 1 and 10 cm in diameter is 500,000. The amount of particles bigger than 1 mm exceeds 100 million.<ref>{{Cite web |title=ARES {{!}} Orbital Debris Program Office {{!}} Frequently Asked Questions |url=https://www.orbitaldebris.jsc.nasa.gov/faq/ |access-date=2022-09-02 |website=NASA.gov |archive-url=https://web.archive.org/web/20220902133204/https://www.orbitaldebris.jsc.nasa.gov/faq/ |archive-date=2022-09-02}}</ref> The particles travel at speeds up to {{convert|17,500|mi/h|km/s km/h mi/h|abbr=on|order=out|sigfig=2|adj=ri0}}, so even a small particle impact can severely damage a spacecraft.<ref>{{Cite web |last=Garcia |first=Mark |date=2015-04-13 |title=Space Debris and Human Spacecraft |url=http://www.nasa.gov/mission_pages/station/news/orbital_debris.html |access-date=2022-09-02 |website=NASA.gov |archive-url=https://web.archive.org/web/20220908122950/https://www.nasa.gov/mission_pages/station/news/orbital_debris.html |archive-date=2022-09-08}}</ref>
The LEO environment is becoming congested with [[space debris]] because of the frequency of object launches.<ref>{{Cite web|last=United Nations Office for Outer Space Affairs|date=2010|title=Space Debris Mitigation Guidelines of the Committee on the Peaceful Uses of Outer Space|url=https://www.iadc-home.org/documents_public/view/search_field/eNortjI2tlJy1CsuTcpKTS7RdtTLS8xNBVIlielAMjk_ryQ1r6RYyRpcMAypDUU~/page/1/id/126#u|access-date=October 19, 2021|website=Inter-Agency Space Debris Coordination Committee (IADC)}}</ref> This has caused growing concern in recent years, since collisions at orbital velocities can be dangerous or deadly. Collisions can produce additional space debris, creating a [[domino effect]] known as [[Kessler syndrome]]. [[NASA|NASA's]] Orbital Debris Program tracks over 25,000 objects larger than 10 cm diameter in LEO, while the estimated number between 1 and 10 cm is 500,000, and the number of particles bigger than 1 mm exceeds 100 million.<ref>{{Cite web |title=ARES {{!}} Orbital Debris Program Office {{!}} Frequently Asked Questions |url=https://www.orbitaldebris.jsc.nasa.gov/faq/ |access-date=2022-09-02 |website=NASA.gov |archive-url=https://web.archive.org/web/20220902133204/https://www.orbitaldebris.jsc.nasa.gov/faq/ |archive-date=2022-09-02}}</ref> The particles travel at speeds up to {{convert|17,500|mi/h|km/s km/h mi/h|abbr=on|order=out|sigfig=2|adj=ri0}}, so even a small impact can severely damage a spacecraft.<ref>{{Cite web |last=Garcia |first=Mark |date=2015-04-13 |title=Space Debris and Human Spacecraft |url=http://www.nasa.gov/mission_pages/station/news/orbital_debris.html |access-date=2022-09-02 |website=NASA.gov |archive-url=https://web.archive.org/web/20220908122950/https://www.nasa.gov/mission_pages/station/news/orbital_debris.html |archive-date=2022-09-08}}</ref>


==See also==
==See also==
{{colbegin}}
{{colbegin}}
* [[Comparison of orbital launch systems]]
* [[Comparison of orbital launch systems]]
* [[Geostationary]] orbit (GEO)
* [[Geostationary orbit]] (GEO)
* [[Heavy lift launch vehicle]]
* [[Heavy-lift launch vehicle]]
* [[High Earth orbit]] (HEO)
* [[High Earth orbit]] (HEO)
* [[Highly elliptical orbit]] (HEO)
* [[Highly elliptical orbit]] (HEO)

Latest revision as of 04:48, 17 May 2024

A low Earth orbit (LEO) is an orbit around Earth with a period of 128 minutes or less (making at least 11.25 orbits per day) and an eccentricity less than 0.25.[1] Most of the artificial objects in outer space are in LEO, with an altitude never more than about one-third of the radius of Earth (or about 2000 kilometers).[2]

The term LEO region is also used for the area of space below an altitude of 2,000 km (1,200 mi) (about one-third of Earth's radius).[3] Objects in orbits that pass through this zone, even if they have an apogee further out or are sub-orbital, are carefully tracked since they present a collision risk to the many LEO satellites.

No human spaceflights other than the lunar missions of the Apollo program have taken place beyond LEO. All crewed space stations to date have operated within LEO.

Defining characteristics[edit]

A wide variety of sources[4][5][6] define LEO in terms of altitude. The altitude of an object in an elliptic orbit can vary significantly along the orbit. Even for circular orbits, the altitude above ground can vary by as much as 30 km (19 mi) (especially for polar orbits) due to the oblateness of Earth's spheroid figure and local topography. While definitions based on altitude are inherently ambiguous, most of them fall within the range specified by an orbit period of 128 minutes because, according to Kepler's third law, this corresponds to a semi-major axis of 8,413 km (5,228 mi). For circular orbits, this in turn corresponds to an altitude of 2,042 km (1,269 mi) above the mean radius of Earth, which is consistent with some of the upper altitude limits in some LEO definitions.

The LEO region is defined by some sources as a region in space that LEO orbits occupy.[3][7][8] Some highly elliptical orbits may pass through the LEO region near their lowest altitude (or perigee) but are not in a LEO orbit because their highest altitude (or apogee) exceeds 2,000 km (1,243 mi). Sub-orbital objects can also reach the LEO region but are not in a LEO orbit because they re-enter the atmosphere. The distinction between LEO orbits and the LEO region is especially important for analysis of possible collisions between objects which may not themselves be in LEO but could collide with satellites or debris in LEO orbits.

Orbital characteristics[edit]

The mean orbital velocity needed to maintain a stable low Earth orbit is about 7.8 km/s (4.8 mi/s), which translates to 28,000 km/h (17,000 mph). However, this depends on the exact altitude of the orbit. Calculated for a circular orbit of 200 km (120 mi) the orbital velocity is 7.79 km/s (4.84 mi/s), but for a higher 1,500 km (930 mi) orbit the velocity is reduced to 7.12 km/s (4.42 mi/s).[9] The launch vehicle's delta-v needed to achieve low Earth orbit starts around 9.4 km/s (5.8 mi/s).

The pull of gravity in LEO is only slightly less than on the Earth's surface. This is because the distance to LEO from the Earth's surface is much less than the Earth's radius. However, an object in orbit is in a permanent free fall around Earth, because in orbit the gravitational force and the centrifugal force balance each other out.[a] As a result, spacecraft in orbit continue to stay in orbit, and people inside or outside such craft continuously experience weightlessness.

Objects in LEO encounter atmospheric drag from gases in the thermosphere (approximately 80–600 km above the surface) or exosphere (approximately 600 km or 400 mi and higher), depending on orbit height. Orbits of satellites that reach altitudes below 300 km (190 mi) decay fast due to atmospheric drag. Objects in LEO orbit Earth between the denser part of the atmosphere and below the inner Van Allen radiation belt.

Equatorial low Earth orbits (ELEO) are a subset of LEO. These orbits, with low inclination to the Equator, allow rapid revisit times over low-latitude locations on Earth. Prograde equatorial LEOs also have lower delta-v launch requirements because they take advantage of the Earth's rotation. Other useful LEO orbits including polar orbits and Sun-synchronous orbits have a higher inclinations to the equator and provide coverage for higher latitudes on Earth. Some of the first generation of Starlink satellites used polar orbits which provide coverage everywhere on Earth. Later Starlink constellations orbit at a lower inclination and provide more coverage for populated areas.

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 early failure of electronic components due to intense radiation and charge accumulation.

In 2017, "very low Earth orbits" (VLEO) began to be seen in regulatory filings. These orbits, below about 450 km (280 mi), require the use of novel technologies for orbit raising because they operate in orbits that would ordinarily decay too soon to be economically useful.[10][11]

Use[edit]

Roughly half an orbit of the International Space Station

A low Earth orbit requires the lowest amount of energy for satellite placement. It provides high bandwidth and low communication latency. Satellites and space stations in LEO are more accessible for crew and servicing.

Since it requires less energy to place a satellite into a LEO, and a satellite there needs less powerful amplifiers for successful transmission, LEO is used for many communication applications, such as the Iridium phone system. Some communication satellites use much higher geostationary orbits and move at the same angular velocity as the Earth as to appear stationary above one location on the planet.

Disadvantages[edit]

Unlike geosynchronous satellites, satellites in low orbit have a small field of view and can only observe and communicate with a fraction of the Earth at a given time. This means that a large network (or constellation) of satellites is required to provide continuous coverage.

Satellites at lower altitudes of orbit are in the atmosphere and suffer from rapid orbital decay, requiring either periodic re-boosting to maintain stable orbits, or the launching of replacements for those that re-enter the atmosphere. The effects of adding such quantities of vaporized metals to Earth's stratosphere are potentially of concern but currently unknown.[12]

Examples[edit]

Former[edit]

  • The Chinese Tiangong-1 station was in orbit at about 355 kilometres (221 mi),[15] until its de-orbiting in 2018.
  • The Chinese Tiangong-2 station was in orbit at about 370 km (230 mi), until its de-orbiting in 2019.
  • GOCE, another gravimetry mission, orbited at about 255 km (158 mi).

In fiction[edit]

Space debris[edit]

The LEO environment is becoming congested with space debris because of the frequency of object launches.[17] This has caused growing concern in recent years, since collisions at orbital velocities can be dangerous or deadly. Collisions can produce additional space debris, creating a domino effect known as Kessler syndrome. NASA's Orbital Debris Program tracks over 25,000 objects larger than 10 cm diameter in LEO, while the estimated number between 1 and 10 cm is 500,000, and the number of particles bigger than 1 mm exceeds 100 million.[18] The particles travel at speeds up to 7.8 km/s (28,000 km/h; 17,500 mph), so even a small impact can severely damage a spacecraft.[19]

See also[edit]

Notes[edit]

  1. ^ It is important to note here that “free fall” by definition requires that gravity is the only force acting on the object. That definition is still fulfilled when falling around Earth, as the other force, the centrifugal force is a fictitious force.

References[edit]

  1. ^ "Current Catalog Files". Archived from the original on 26 June 2018. Retrieved 13 July 2018. LEO: Mean Motion > 11.25 & Eccentricity < 0.25
  2. ^ Sampaio, Jarbas; Wnuk, Edwin; Vilhena de Moraes, Rodolpho; Fernandes, Sandro (1 January 2014). "Resonant Orbital Dynamics in LEO Region: Space Debris in Focus". Mathematical Problems in Engineering. 2014: Figure 1: Histogram of the mean motion of the cataloged objects. doi:10.1155/2014/929810. Archived from the original on 1 October 2021. Retrieved 13 July 2018.
  3. ^ a b "IADC Space Debris Mitigation Guidelines" (PDF). INTER-AGENCY SPACE DEBRIS COORDINATION COMMITTEE: Issued by Steering Group and Working Group 4. September 2007. Archived (PDF) from the original on 17 July 2018. Retrieved 17 July 2018. Region A, Low Earth Orbit (or LEO) Region – spherical region that extends from the Earth's surface up to an altitude (Z) of 2,000 km
  4. ^ "Definition of LOW EARTH ORBIT". Merriam-Webster Dictionary. Archived from the original on 8 July 2018. Retrieved 8 July 2018.
  5. ^ "Frequently Asked Questions". FAA. Archived from the original on 2 June 2020. Retrieved 14 February 2020. LEO refers to orbits that are typically less than 2,400 km (1,491 mi) in altitude.
  6. ^ Campbell, Ashley (10 July 2015). "SCaN Glossary". NASA. Archived from the original on 3 August 2020. Retrieved 12 July 2018. Low Earth Orbit (LEO): A geocentric orbit with an altitude much less than the Earth's radius. Satellites in this orbit are between 80 and 2000 kilometers above the Earth's surface.
  7. ^ "What Is an Orbit?". NASA. David Hitt : NASA Educational Technology Services, Alice Wesson : JPL, J.D. Harrington : HQ;, Larry Cooper : HQ;, Flint Wild : MSFC;, Ann Marie Trotta : HQ;, Diedra Williams : MSFC. 1 June 2015. Archived from the original on 27 March 2018. Retrieved 8 July 2018. LEO is the first 100 to 200 miles (161 to 322 km) of space.{{cite news}}: CS1 maint: others (link)
  8. ^ Steele, Dylan (3 May 2016). "A Researcher's Guide to: Space Environmental Effects". NASA. p. 7. Archived from the original on 17 November 2016. Retrieved 12 July 2018. the low-Earth orbit (LEO) environment, defined as 200–1,000 km above Earth's surface
  9. ^ "LEO parameters". www.spaceacademy.net.au. Archived from the original on 11 February 2016. Retrieved 12 June 2015.
  10. ^ Crisp, N. H.; Roberts, P. C. E.; Livadiotti, S.; Oiko, V. T. A.; Edmondson, S.; Haigh, S. J.; Huyton, C.; Sinpetru, L.; Smith, K. L.; Worrall, S. D.; Becedas, J. (August 2020). "The Benefits of Very Low Earth Orbit for Earth Observation Missions". Progress in Aerospace Sciences. 117: 100619. arXiv:2007.07699. Bibcode:2020PrAeS.11700619C. doi:10.1016/j.paerosci.2020.100619. S2CID 220525689.
  11. ^ Messier, Doug (3 March 2017). "SpaceX Wants to Launch 12,000 Satellites". Parabolic Arc. Archived from the original on 22 January 2020. Retrieved 22 January 2018.
  12. ^ https://www.scientificamerican.com/article/space-junk-is-polluting-earths-stratosphere-with-vaporized-metal/
  13. ^ "Higher Altitude Improves Station's Fuel Economy". NASA. Archived from the original on 15 May 2015. Retrieved 12 February 2013.
  14. ^ Holli, Riebeek (4 September 2009). "NASA Earth Observatory". earthobservatory.nasa.gov. Archived from the original on 27 May 2018. Retrieved 28 November 2015.
  15. ^ ""天宫一号成功完成二次变轨"". Archived from the original on 13 November 2011. Retrieved 13 October 2020.
  16. ^ "Space station from 2001: A Space Odyssey".
  17. ^ United Nations Office for Outer Space Affairs (2010). "Space Debris Mitigation Guidelines of the Committee on the Peaceful Uses of Outer Space". Inter-Agency Space Debris Coordination Committee (IADC). Retrieved 19 October 2021.
  18. ^ "ARES | Orbital Debris Program Office | Frequently Asked Questions". NASA.gov. Archived from the original on 2 September 2022. Retrieved 2 September 2022.
  19. ^ Garcia, Mark (13 April 2015). "Space Debris and Human Spacecraft". NASA.gov. Archived from the original on 8 September 2022. Retrieved 2 September 2022.

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