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{{Short description|Coordinate system used on the Moon}}
[[Image:Moon-map.png|right|400px]]
[[Image:Moon-map.png|thumb|400px|Near side of the moon]]
[[File:Astronomy for the use of schools and academies (1882) (14577550018).jpg|thumb|Chart of lunar maria with lines of longitude and latitude.]]
[[File:Copernican_System_farside_plate_11B_Wilhelms1987.jpg|thumb|Chart of the far side of the moon with lines of longitude and latitude.]]
The '''selenographic coordinate system''' is used to refer to locations on the surface of [[Earth]]'s [[moon]]. Any position on the lunar surface can be referenced by specifying two numerical values, which are comparable to the [[latitude]] and [[longitude]] of Earth. The longitude gives the position east or west of the Moon's prime meridian, which is the line passing from the [[lunar north pole]] through the point on the lunar surface directly facing Earth to the [[lunar south pole]]. (See also [[prime meridian|Earth's prime meridian]].) This can be thought of as the midpoint of the visible Moon as seen from the Earth. The latitude gives the position north or south of the lunar [[equator]]. Both of these coordinates are given in [[degree (angle)|degrees]].


Astronomers defined the fundamental location in the selenographic coordinate system by the small, bowl-shaped satellite crater '[[Mösting (crater)|Mösting A]]'{{citation needed|reason=Probably wrong. See: https://the-moon.wikispaces.com/Selenographic+Coordinates|date=September 2015}}. The coordinates of this crater are defined as:
'''Selenographic coordinates''' are used to refer to locations on the surface of [[Earth]]'s [[moon]]. Any position on the lunar surface can be referenced by specifying two numerical values, which are comparable to the [[latitude]] and [[longitude]] of Earth. The longitude gives the position east or west of the Moon's prime meridian, which is the line of longitude passing through the point on the lunar surface directly facing Earth. (See also [[prime meridian|Earth's prime meridian]].) This can be thought of as the mid-point of the visible Moon as seen from the Earth. The latitude gives the position north or south of the lunar [[equator]]. Both of these coordinates are given in terms of [[degree (angle)|degrees]].

Astronomers defined the fundamental location in the selenographic coordinate system by the small, bowl-shaped satellite crater '[[Mösting (crater)|Mösting A]]'. The coordinates of this crater are defined as:


:{| border="0"
:{| border="0"
|''Latitude:''
|''Latitude:''
|3° 12' 43.2"
|3° 12' 43.2" South
|-
|-
|''Longitude:''
|''Longitude:''
|5° 12' 39.6"
|5° 12' 39.6" West
|}
|}


The coordinate system has become precisely defined due to the [[Lunar Laser Ranging Experiment]].
Later, the coordinate system has become more precisely defined due to the [[Lunar Laser Ranging Experiment]].


Anything past 90°E or 90°W is on the "unseen" side of the moon.
Anything past 90°E or 90°W would not be seen from Earth, except for [[libration]], which makes [[Moon#Two sides of the Moon|59% of the Moon visible]].

== Longitude ==

Longitude on the Moon is measured both east and west from its [[prime meridian]]. When no direction is specified, east is positive and west is negative.

Roughly speaking, the Moon's prime meridian lies near the center of the Moon's disc as seen from Earth. For precise applications, many coordinate systems have been defined for the Moon, each with a slightly different prime meridian. The [[International Astronomical Union|IAU]] recommends the "mean Earth/polar axis" system,<ref>[https://astrogeology.usgs.gov/Projects/WGCCRE/WGCCRE2003preprint.pdf IAU/IAG Working Group on Cartographic Coordinates and Rotational Elements: 2003]</ref> in which the prime meridian is the average direction (from the Moon's center) of the Earth's center.<ref>[http://lunar.gsfc.nasa.gov/library/451-SCI-000958.pdf A Standardized Lunar Coordinate System for the Lunar Reconnaissance Orbiter]</ref>


== Selenographic colongitude ==
== Selenographic colongitude ==
The '''selenographic colongitude''' is the longitude of the morning [[Terminator (solar)|terminator]] on the Moon, as measured in degrees westward from the prime meridian. The morning terminator forms a half-circle across the Moon where the Sun is just starting to rise. As the Moon continues in its orbit, this line advances in longitude. The value of the selenographic colongitude increases from 0° to 359° in the direction of the advancing terminator.


The '''selenographic colongitude''' is the longitude of the morning [[Lunar terminator|terminator on the Moon]], as measured in degrees westward from the prime meridian. The morning terminator forms a half-circle across the Moon where the Sun is just starting to rise. As the Moon continues in its orbit, this line advances in longitude. The value of the selenographic colongitude increases from 0° to 359° in the direction of the advancing terminator.
Sunrise occurs at the prime meridian when the Moon reaches First Quarter, after one fourth of a [[lunar day]]. At this location the selenographic colongitude at sunrise is defined as 0°. Thus, by the time of the [[Full Moon]] the colongitude increases to 90°; at Last Quarter it is 180°, and at the [[New Moon]] the colongitude reaches 270°. Note that the Moon is nearly invisible from the Earth at New Moon phase except during a [[solar eclipse]].


Sunrise occurs at the prime meridian when the [[Lunar phase]] reaches First Quarter, after one fourth of a [[lunar day]]. At this location the selenographic colongitude at sunrise is defined as 0°. Thus, by the time of the [[Full Moon]] the colongitude increases to 90°; at Last Quarter it is 180°, and at the [[New Moon]] the colongitude reaches 270°. Note that the Moon is nearly invisible from the Earth at New Moon phase except during a [[solar eclipse]].
The low [[angle of incidence]] of arriving sunlight tends to pick out features by the sharp shadows they cast, thus the area near the terminator is usually the most favorable for viewing or [[photograph|photographing]] lunar features through a [[telescope]]. The observer will need to know the location of the terminator to plan observations of selected features. The selenographic colongitude is useful for this purpose.


The low [[angle of incidence (optics)|angle of incidence]] of arriving sunlight tends to pick out features by the sharp shadows they cast, thus the area near the terminator is usually the most favorable for viewing or [[photograph]]ing lunar features through a [[telescope]]. The observer will need to know the location of the terminator to plan observations of selected features. The selenographic colongitude is useful for this purpose.
The selenographic longitude of the evening terminator is equal to the colongitude plus 180°.

The selenographic longitude of the evening terminator is equal to the colongitude plus 180°.<ref name="ruklcolpres">[[Antonín Rükl]]: ''Atlas Měsíce'', Aventinum (Praha 1991), chapter Tabulky pro výpočet hodnoty colongitudo, page 212, {{ISBN|80-85277-10-7}} {{in lang|cs}}</ref>

==See also==
*[[Planetary coordinate system]]
*[[Selenoid]]


==References==
==References==
{{Reflist}}
*"A Unified Lunar Control Network &mdash; The Near Side", Merton E. Davies, Tim R. Colvin, & Donald L. Mayer, RAND Corporation, Santa Monica, 1987.
*"A Unified Lunar Control Network &mdash; The Near Side", Merton E. Davies, Tim R. Colvin, & Donald L. Mayer, RAND Corporation, Santa Monica, 1987.

{{The Moon}}


[[Category:Lunar science]]
[[Category:Lunar science]]
[[Category:Angle]]
[[Category:Angle]]
[[Category:Coordinate systems]]


[[da:Selenografiske koordinater]]
[[de:Selenografische Koordinaten]]
[[fr:Coordonnées sélénographiques]]
[[es:Coordenadas selenográficas]]
[[pl:Współrzędne selenograficzne]]

Latest revision as of 11:32, 26 February 2024

Near side of the moon
Chart of lunar maria with lines of longitude and latitude.
Chart of the far side of the moon with lines of longitude and latitude.

The selenographic coordinate system is used to refer to locations on the surface of Earth's moon. Any position on the lunar surface can be referenced by specifying two numerical values, which are comparable to the latitude and longitude of Earth. The longitude gives the position east or west of the Moon's prime meridian, which is the line passing from the lunar north pole through the point on the lunar surface directly facing Earth to the lunar south pole. (See also Earth's prime meridian.) This can be thought of as the midpoint of the visible Moon as seen from the Earth. The latitude gives the position north or south of the lunar equator. Both of these coordinates are given in degrees.

Astronomers defined the fundamental location in the selenographic coordinate system by the small, bowl-shaped satellite crater 'Mösting A'[citation needed]. The coordinates of this crater are defined as:

Latitude: 3° 12' 43.2" South
Longitude: 5° 12' 39.6" West

Later, the coordinate system has become more precisely defined due to the Lunar Laser Ranging Experiment.

Anything past 90°E or 90°W would not be seen from Earth, except for libration, which makes 59% of the Moon visible.

Longitude[edit]

Longitude on the Moon is measured both east and west from its prime meridian. When no direction is specified, east is positive and west is negative.

Roughly speaking, the Moon's prime meridian lies near the center of the Moon's disc as seen from Earth. For precise applications, many coordinate systems have been defined for the Moon, each with a slightly different prime meridian. The IAU recommends the "mean Earth/polar axis" system,[1] in which the prime meridian is the average direction (from the Moon's center) of the Earth's center.[2]

Selenographic colongitude[edit]

The selenographic colongitude is the longitude of the morning terminator on the Moon, as measured in degrees westward from the prime meridian. The morning terminator forms a half-circle across the Moon where the Sun is just starting to rise. As the Moon continues in its orbit, this line advances in longitude. The value of the selenographic colongitude increases from 0° to 359° in the direction of the advancing terminator.

Sunrise occurs at the prime meridian when the Lunar phase reaches First Quarter, after one fourth of a lunar day. At this location the selenographic colongitude at sunrise is defined as 0°. Thus, by the time of the Full Moon the colongitude increases to 90°; at Last Quarter it is 180°, and at the New Moon the colongitude reaches 270°. Note that the Moon is nearly invisible from the Earth at New Moon phase except during a solar eclipse.

The low angle of incidence of arriving sunlight tends to pick out features by the sharp shadows they cast, thus the area near the terminator is usually the most favorable for viewing or photographing lunar features through a telescope. The observer will need to know the location of the terminator to plan observations of selected features. The selenographic colongitude is useful for this purpose.

The selenographic longitude of the evening terminator is equal to the colongitude plus 180°.[3]

See also[edit]

References[edit]

  1. ^ IAU/IAG Working Group on Cartographic Coordinates and Rotational Elements: 2003
  2. ^ A Standardized Lunar Coordinate System for the Lunar Reconnaissance Orbiter
  3. ^ Antonín Rükl: Atlas Měsíce, Aventinum (Praha 1991), chapter Tabulky pro výpočet hodnoty colongitudo, page 212, ISBN 80-85277-10-7 (in Czech)
  • "A Unified Lunar Control Network — The Near Side", Merton E. Davies, Tim R. Colvin, & Donald L. Mayer, RAND Corporation, Santa Monica, 1987.
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