Geographic coordinate system: Difference between revisions
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{{Short description|System to specify locations on Earth}} |
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''This article is about longitude and latitude; see also [[transverse Mercator projection|UTM coordinate system]]'' |
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{{pp-move}} |
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{{Pp-pc|small=yes}} |
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{{Broader|Spatial reference system}} |
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{{Use dmy dates|date=May 2019}} |
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{{Use American English|date=June 2024}} |
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[[File:FedStats Lat long.svg|thumb|upright=1.2|Longitude lines are perpendicular to and latitude lines are parallel to the Equator]] |
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{{Geodesy}} |
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A '''geographic coordinate system''' ('''GCS''') is a [[spherical coordinate system|spherical]] or [[geodetic coordinates|geodetic coordinate]] system for measuring and communicating [[position (geometry)|positions]] directly on [[Earth]] as [[latitude]] and [[longitude]].<ref name="chang2016">{{cite book |last1=Chang |first1=Kang-tsung |title=Introduction to Geographic Information Systems |date=2016 |publisher=McGraw-Hill |isbn=978-1-259-92964-9 |page=24 |edition=9th}}</ref> It is the simplest, oldest and most widely used type of the various [[spatial reference systems]] that are in use, and forms the basis for most others. Although latitude and longitude form a coordinate [[tuple]] like a [[cartesian coordinate system]], the geographic coordinate system is not cartesian because the measurements are angles and are not on a planar surface.<ref name="DiBiase">{{cite web |last=DiBiase |first=David |title=The Nature of Geographic Information |url=https://www.e-education.psu.edu/natureofgeoinfo/c2_p10.html |access-date=18 February 2024 |archive-date=19 February 2024 |archive-url=https://web.archive.org/web/20240219075125/https://www.e-education.psu.edu/natureofgeoinfo/c2_p10.html |url-status=live }}</ref> |
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The '''geographic (earth-mapping) coordinate system''' expresses every horizontal position on Earth by two of the three coordinates of a [[Spherical_coordinates#Spherical_coordinates|spherical coordinate system]] which is aligned with the spin axis of the [[Earth]]. |
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A full GCS specification, such as those listed in the [[EPSG Geodetic Parameter Dataset|EPSG]] and ISO 19111 standards, also includes a choice of [[geodetic datum]] (including an [[Earth ellipsoid]]), as different datums will yield different latitude and longitude values for the same location.<ref name="epsg">{{cite web |title=Using the EPSG geodetic parameter dataset, Guidance Note 7-1 |url=https://epsg.org/guidance-notes.html |website=EPSG Geodetic Parameter Dataset |publisher=Geomatic Solutions |access-date=15 December 2021 |archive-date=15 December 2021 |archive-url=https://web.archive.org/web/20211215215824/https://epsg.org/guidance-notes.html |url-status=live }}</ref> |
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== History == |
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== The [[sexagesimal]] geographic coordinate standard system == |
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{{also|History of geodesy}} |
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The [[invention]] of a geographic coordinate system is generally credited to [[Eratosthenes]] of [[Cyrene, Libya|Cyrene]], who composed his now-lost ''[[Geography (Eratosthenes)|Geography]]'' at the [[Library of Alexandria]] in the 3rd century BC.<ref>{{Citation |last=McPhail |first=Cameron |title=Reconstructing Eratosthenes'<!--sic--> Map of the World |pages=20–24 |url=https://ourarchive.otago.ac.nz/bitstream/handle/10523/1713/McPhailCameron2011MA.pdf |year=2011 |publisher=University of Otago |location=[[Dunedin]] |access-date=14 March 2015 |archive-date=2 April 2015 |archive-url=https://web.archive.org/web/20150402095830/https://ourarchive.otago.ac.nz/bitstream/handle/10523/1713/McPhailCameron2011MA.pdf |url-status=live }}.</ref> A century later, [[Hipparchus#Geography|Hipparchus]] of [[Nicaea]] improved on this system by determining latitude from stellar measurements rather than solar altitude and determining longitude by timings of [[lunar eclipse]]s, rather than [[dead reckoning]]. In the 1st or 2nd century, [[Marinus of Tyre]] compiled an extensive gazetteer and [[equirectangular projection|mathematically plotted world map]] using coordinates measured east from a [[prime meridian]] at the westernmost known land, designated the [[Fortunate Isles]], off the coast of western Africa around the [[Canary Islands|Canary]] or [[Cape Verde|Cape Verde Islands]], and measured north or south of the island of [[Rhodes]] off [[Asia Minor]]. [[Ptolemy]] credited him with the full adoption of longitude and latitude, rather than measuring latitude in terms of the length of the [[midsummer]] day.<ref>{{Citation |last=Evans |first=James |title=The History and Practice of Ancient Astronomy |url=https://books.google.com/books?id=LVp_gkwyvC8C&pg=PA102 |pages=102–103 |publisher=Oxford University Press |year=1998 |location=Oxford, England |isbn=9780199874453 |access-date=5 May 2020 |archive-date=17 March 2023 |archive-url=https://web.archive.org/web/20230317171201/https://books.google.com/books?id=LVp_gkwyvC8C&pg=PA102 |url-status=live }}.</ref> |
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[[Image:WorldMapLongLat-eq-circles-tropics-non.png|thumb|450px|Map of [[Earth]] showing lines of [[latitude]] (horizontally) and [[longitude]] (vertically); [http://www.cia.gov/cia/publications/factbook/reference_maps/pdf/political_world.pdf large version] (pdf)]] |
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Borrowing from theories of ancient [[Babylonian]]s, later expanded by the famous [[History of Ancient Greece|Greek]] thinker and geographer [[Ptolemy]], a full circle is assigned 360 [[degree (angle)|degree]]s (360°). This is also called [[absolute location]] |
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Ptolemy's 2nd-century ''[[Geography (Ptolemy)|Geography]]'' used the same prime meridian but measured latitude from the [[Equator]] instead. After their work was translated into [[Arabic]] in the 9th century, [[Al-Khwarizmi|Al-Khwārizmī]]'s ''[[Book of the Description of the Earth]]'' corrected Marinus' and Ptolemy's errors regarding the length of the [[Mediterranean Sea]],{{NoteTag|The pair had accurate absolute distances within the Mediterranean but underestimated the [[circumference of the Earth]], causing their degree measurements to overstate its length west from Rhodes or Alexandria, respectively.}} causing [[Geography and cartography in the medieval Islamic world|medieval Arabic cartography]] to use a prime meridian around 10° east of Ptolemy's line. Mathematical cartography resumed in Europe following [[Maximus Planudes]]' recovery of Ptolemy's text a little before 1300; the text was translated into [[Latin]] at [[Republic of Florence|Florence]] by [[Jacopo d'Angelo]] around 1407.<!--more sources at linked pages--> |
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It defines two angles measured from the center of the Earth: |
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In 1884, the [[United States]] hosted the [[International Meridian Conference]], attended by representatives from twenty-five nations. Twenty-two of them agreed to adopt the longitude of the [[Royal Observatory, Greenwich|Royal Observatory]] in [[Greenwich]], England as the zero-reference line. The [[Dominican Republic]] voted against the motion, while France and [[Brazil]] abstained.<ref>{{cite web |publisher=Greenwich 2000 Limited |url = http://wwp.millennium-dome.com/info/conference.htm |title=The International Meridian Conference |website=Millennium Dome: The O2 in Greenwich |date=9 June 2011 |access-date=31 October 2012 |url-status=dead |archive-url = https://web.archive.org/web/20120806065207/http://wwp.millennium-dome.com/info/conference.htm |archive-date=6 August 2012 }}</ref> France adopted [[Greenwich Mean Time]] in place of local determinations by the [[Paris Observatory]] in 1911. |
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*the [[latitude]] (Lat.) is the vertical data and measures the angle between any point and the [[equator]]. Lines of constant latitude are called [[parallel]]s. They trace circles on the surface of the Earth, but the only parallel that is a [[great circle]] is the [[equator]] (latitude=0 degrees),with each [[Geographical pole|pole]] being 90 degrees ([[north pole]] +90°; [[south pole]] −90° ). |
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==Latitude and longitude== |
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*the [[longitude]] (Long.) is the horizontal data and measures the angle east-wards from an arbitrary point on the Earth: [[Greenwich]] in [[London]] ([[U.K.]]) is the accepted zero-longitude point internationally in most modern societies (longitude=0 or 360 degrees). Longitude is measured form 0 to +360 deg, going east from the zeropoint (Greenwich or 0°), being 180 degrees the opposite point on the globe to Greenwich. Lines of constant longitude are called [[meridian]]s . The meridian passing through Greenwich is the [[Prime Meridian]]. Unlike parallels, all meridians are great circles, and meridians are not parallel: they intersect at the north and south poles. |
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[[File:Latitude_and_longitude_graticule_on_a_sphere.svg|thumb|upright=1.2|Diagram of the latitude {{mvar|ϕ}} and longitude {{mvar|λ}} angle measurements for a spherical model of the Earth.]] |
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{{Main|Latitude|Longitude}} |
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The ''latitude'' [[Phi|{{mvar|φ}}]] of a point on Earth's surface is the angle between the equatorial plane and the straight line that passes through that point and through (or close to) the center of the Earth.{{NoteTag|Alternative versions of latitude and longitude include geocentric coordinates, which measure with respect to Earth's center; geodetic coordinates, which model Earth as an [[ellipsoid]]; and geographic coordinates, which measure with respect to a plumb line at the location for which coordinates are given.}} Lines joining points of the same latitude trace circles on the surface of Earth called [[circle of latitude|parallels]], as they are parallel to the Equator and to each other. The [[North Pole]] is 90° N; the [[South Pole]] is 90° S. The 0° parallel of latitude is designated the [[Equator]], the [[fundamental plane (spherical coordinates)|fundamental plane]] of all geographic coordinate systems. The Equator divides the globe into [[Northern Hemisphere|Northern]] and [[Southern Hemisphere]]s. |
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By combining these two angles, the plane position of any location on Earth can be specified. |
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The ''longitude'' [[lambda|{{mvar|λ}}]] of a point on Earth's surface is the angle east or west of a reference [[meridian (geography)|meridian]] to another meridian that passes through that point. All meridians are halves of great [[ellipse]]s (often called [[great circle]]s), which converge at the North and South Poles. The meridian of the British [[Royal Observatory, Greenwich|Royal Observatory]] in [[Greenwich]], in southeast London, England, is the international [[prime meridian]], although some organizations—such as the French {{Lang|fr|[[Institut national de l'information géographique et forestière]]|italic=no}}—continue to use other meridians for internal purposes. The prime meridian determines the proper [[Eastern Hemisphere|Eastern]] and [[Western Hemisphere]]s, although maps often divide these hemispheres further west in order to keep the [[Old World]] on a single side. The [[Antipodes|antipodal]] meridian of Greenwich is both 180°W and 180°E. This is not to be conflated with the [[International Date Line]], which diverges from it in several places for political and convenience reasons, including between far eastern Russia and the far western [[Aleutian Islands]]. |
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For example, [[Baltimore, Maryland]] (in the [[United States|USA]]) has a latitude of 39.3 degrees North, and a longitude of 76.6 degrees West ({{coor d|39.3|N|76.6|W|}}). So, a vector drawn from the center of the Earth to a point 39.3 degrees north of the equator and 76.6 degrees west of Greenwich will pass through Baltimore. |
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The combination of these two components specifies the position of any location on the surface of Earth, without consideration of [[altitude]] or depth. The visual grid on a map formed by lines of latitude and longitude is known as a ''[[Graticule (cartography)|graticule]]''.<ref>{{cite book |url = https://books.google.com/books?id=jPVxSDzVRP0C&q=graticule&pg=PA224 |title=Glossary of the Mapping Sciences |last=American Society of Civil Engineers |date=1 January 1994 |publisher=ASCE Publications|isbn=9780784475706|language=en|page= 224 }}</ref> The origin/zero point of this system is located in the [[Gulf of Guinea]] about {{convert|625|km|sp=us|abbr=on|sigfig=2}} south of [[Tema]], [[Ghana]], a location often facetiously called [[Null Island]]. |
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This latitude/longitude "webbing" is known as the common '''''graticule'''''. There is also a complementary '''transverse graticule''' (meaning the graticule is shifted 90°, so that the poles are on the horizontal equator), upon which all [[spherical trigonometry]] is ultimately based on. |
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<!-- a whole separate article on "transverse graticule" is planned --> |
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== Geodetic datum == |
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Traditionally, degrees have been divided into [[Minute of arc|minutes]] ( ' ) and [[Arcsecond|seconds]] ( " ). There are formats for degrees, all of them appearing in a Lat.-Long. order : |
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{{Main|Geodetic datum}} |
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{{further|Figure of the Earth|Reference ellipsoid|Geographic coordinate conversion|Spatial reference system}} |
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In order to use the theoretical definitions of latitude, longitude, and height to precisely measure actual locations on the physical earth, a ''[[geodetic datum]]'' must be used. A ''horizonal datum'' is used to precisely measure latitude and longitude, while a ''vertical datum'' is used to measure elevation or altitude. Both types of datum bind a mathematical model of the shape of the earth (usually a [[reference ellipsoid]] for a horizontal datum, and a more precise [[geoid]] for a vertical datum) to the earth. Traditionally, this binding was created by a network of [[geodetic control network |control points]], surveyed locations at which monuments are installed, and were only accurate for a region of the surface of the Earth. Newer datums are based on a global network for satellite measurements ([[Satellite navigation|GNSS]], [[Very-long-baseline interferometry|VLBI]], [[Satellite laser ranging|SLR]] and [[DORIS (satellite system)|DORIS]]). |
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* '''DM''' Degree:Minute (49:30.0-123:30.0) |
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* '''DMS''' Degree:Minute:Second (49:30:00-123:30:00) |
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* '''DD''' Decimal Degree (49.5000-123.5000), generally with 4 decimal numbers. |
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To change from DM or DMS to DD, Decimal degrees = whole number of degrees, plus minutes divided by 60, plus seconds divided by 3600. Decimal division is now the most common and standard. |
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This combination of mathematical model and physical binding mean that anyone using the same datum will obtain the same location measurement for the same physical location. However, two different datums will usually yield different location measurements for the same physical location, which may appear to differ by as much as several hundred meters; this not because the location has moved, but because the reference system used to measure it has shifted. Because any [[spatial reference system]] or [[map projection]] is ultimately calculated from latitude and longitude, it is crucial that they clearly state the datum on which they are based. For example, a [[Universal transverse mercator |UTM]] coordinate based on a [[WGS84]] realisation will be different than a UTM coordinate based on [[NAD27]] for the same location. Converting coordinates from one datum to another requires a [[Geographic coordinate conversion#Datum transformations|datum transformation]] such as a [[Helmert transformation]], although in certain situations a simple [[Translation (geometry)|translation]] may be sufficient.<ref name=Irish>{{cite web |url = http://www.osi.ie/GetAttachment.aspx?id=25113681-c086-485a-b113-bab7c75de6fa |title=Making maps compatible with GPS |publisher=Government of Ireland 1999 |access-date=15 April 2008 |archive-url = https://web.archive.org/web/20110721130505/http://www.osi.ie/GetAttachment.aspx?id=25113681-c086-485a-b113-bab7c75de6fa |archive-date=21 July 2011 |url-status=dead }}</ref> |
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The equator is obviously an important part of this coordinate system, it represents the zeropoint of the latitude angle, and the halfway point between the poles. The equator is the [[fundamental plane]] of the geographic coordinate system. All spherical coordinate systems define such a fundamental plane. |
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Datums may be global, meaning that they represent the whole Earth, or they may be regional,<ref>{{cite web | publisher = Ordnance Survey | title = A guide to the coordinate systems in Great Britain | url = https://docs.os.uk/os-downloads/resources/a-guide-to-coordinate-systems-in-great-britain/the-shape-of-the-earth }}</ref> meaning that they represent an ellipsoid best-fit to only a portion of the Earth. Examples of global datums include the several realizations of [[WGS 84]] (with the 2D datum ensemble EPSG:4326 with 2 meter accuracy as identifier)<ref>{{Cite web|url=https://spatialreference.org/ref/epsg/4326/|title=WGS 84: EPSG Projection -- Spatial Reference|website=spatialreference.org|access-date=5 May 2020|archive-date=13 May 2020|archive-url=https://web.archive.org/web/20200513113544/https://spatialreference.org/ref/epsg/4326/|url-status=live}}</ref><ref>[https://epsg.org/crs_4326/WGS-84.html EPSG:4326]</ref> used for the [[Global Positioning System]],{{NoteTag|WGS 84 is the default datum used in most GPS equipment, but other datums and map projections can be selected.}} and the several realizations of the [[International Terrestrial Reference System and Frame]] (such as ITRF2020 with subcentimeter accuracy), which takes into account [[continental drift]] and [[crustal deformation]].<ref name=Bolstad>{{cite book |last=Bolstad |first=Paul |title=GIS Fundamentals |year=2012 |edition=5th |publisher=Atlas books |isbn=978-0-9717647-3-6 |page=102 |url=http://www.paulbolstad.net/5thedition/samplechaps/Chapter3_5th_small.pdf |access-date=27 January 2018 |archive-date=15 October 2020 |archive-url=https://web.archive.org/web/20201015162738/http://www.paulbolstad.net/5thedition/samplechaps/Chapter3_5th_small.pdf |url-status=dead }}</ref> |
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''This article originates from Jason Harris' Astroinfo which comes along with [[KStars]], a Desktop Planetarium for [[Linux]]/[[KDE]]. See http://edu.kde.org/kstars/index.phtml'' |
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Datums with a regional fit of the ellipsoid that are chosen by a national cartographical organization include the [[North American Datum]]s, the European [[ED50]], and the British [[OSGB36]]. Given a location, the datum provides the latitude <math>\phi</math> and longitude <math>\lambda</math>. In the United Kingdom there are three common latitude, longitude, and height systems in use. WGS{{nbsp}}84 differs at Greenwich from the one used on published maps OSGB36 by approximately 112{{nbsp}}m. ED50 differs from about 120{{nbsp}}m to 180{{nbsp}}m.<ref name=OSGB/> |
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In popular GIS software, data projected in latitude/longitude is often represented as 'Geographic Coordinate System'. For example, data in latitude/longitude with datum as the North American Datum of 1983 is denoted by 'GCS_North_American_1983'. |
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Points on the Earth's surface move relative to each other due to continental plate motion, subsidence, and diurnal [[Earth tide|Earth tidal]] movement caused by the [[Moon]] and the Sun. This daily movement can be as much as a meter. Continental movement can be up to {{nowrap|10 cm}} a year, or {{nowrap|10 m}} in a century. A [[weather system]] high-pressure area can cause a sinking of {{nowrap|5 mm}}. [[Scandinavia]] is rising by {{nowrap|1 cm}} a year as a result of the melting of the ice sheets of the [[quaternary glaciation|last ice age]], but neighboring [[Scotland]] is rising by only {{nowrap|0.2 cm}}. These changes are insignificant if a regional datum is used, but are statistically significant if a global datum is used.<ref name="OSGB">{{Citation |title=A guide to coordinate systems in Great Britain |date=2020 |series=D00659 v3.6 |access-date=17 December 2021|publisher=Ordnance Survey |url=https://www.ordnancesurvey.co.uk/documents/resources/guide-coordinate-systems-great-britain.pdf |archive-url=https://web.archive.org/web/20200402024515/http://www.ordnancesurvey.co.uk/documents/resources/guide-coordinate-systems-great-britain.pdf |archive-date=2020-04-02 |url-status=live }}</ref> |
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== |
==Length of a degree== |
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{{Main|Length of a degree of latitude|Length of a degree of longitude}} |
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{{See also|Arc length#Great circles on Earth}} |
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On the [[Geodetic Reference System 1980|GRS{{nbsp}}80]] or [[World Geodetic System#WGS84|WGS{{nbsp}}84]] spheroid at [[sea level]] at the Equator, one latitudinal second measures 30.715 [[metre|m]], one latitudinal minute is 1843 m and one latitudinal degree is 110.6 km. The circles of longitude, meridians, meet at the geographical poles, with the west–east width of a second naturally decreasing as latitude increases. On the [[Equator]] at sea level, one longitudinal second measures 30.92 m, a longitudinal minute is 1855 m and a longitudinal degree is 111.3 km. At 30° a longitudinal second is 26.76 m, at Greenwich (51°28′38″N) 19.22 m, and at 60° it is 15.42 m. |
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You can use the [[cardinal]] or the [[numerical]] only system: |
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On the WGS{{nbsp}}84 spheroid, the length in meters of a degree of latitude at latitude {{mvar|ϕ}} (that is, the number of meters you would have to travel along a north–south line to move 1 degree in latitude, when at latitude {{mvar|ϕ}}), is about |
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* Cardinal system includes North, South, East, West (i.e., 60° E). |
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* Numerical system uses only numbers. i.e., 60°E is 60° and 60°W is 360°−60° = 300º. |
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{{block indent|1= |
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''PoLat'' uses instead of Equator the North Pole (North pole = 0°, Equator = 90° and South Pole = 180°). In this notation, there are no negative numbers. |
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<math>111132.92 - 559.82\, \cos 2\phi + 1.175\, \cos 4\phi - 0.0023\, \cos 6\phi</math><ref name=GISS>[http://gis.stackexchange.com/questions/75528/length-of-a-degree-where-do-the-terms-in-this-formula-come-from] {{Webarchive|url=https://web.archive.org/web/20160629203521/http://gis.stackexchange.com/questions/75528/length-of-a-degree-where-do-the-terms-in-this-formula-come-from |date=29 June 2016 }} Geographic Information Systems – Stackexchange</ref> |
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}} |
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The returned measure of meters per degree latitude varies continuously with latitude. |
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The [[UGN]] (Unified Geographic Notation) uses: |
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Similarly, the length in meters of a degree of longitude can be calculated as |
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* Numerical system in Decimal degrees. |
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* Latitude appears first, followed by a ''-'', the latitude and UGN. |
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* PoLat is used for latitude. |
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{{block indent|1= |
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I.e., 90.00-18.01 UGN is in the Equator (90°) and 18.01° in the east |
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<math>111412.84\, \cos \phi - 93.5\, \cos 3\phi + 0.118\, \cos 5\phi</math><ref name=GISS/> |
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}} |
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(Those coefficients can be improved, but as they stand the distance they give is correct within a centimeter.) |
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=== Geostationary coordinates === |
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The formulae both return units of meters per degree. |
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[[Geostationary]] satellites (i.e., television satellites ) are over the [[Equator]]. So, their position related to Earth is expressed in longitude degrees. Latitude does not change, and is always zero over the Equator. |
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An alternative method to estimate the length of a longitudinal degree at latitude <math>\phi</math> is to assume a spherical Earth (to get the width per minute and second, divide by 60 and 3600, respectively): |
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===Third dimension : altitude === |
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To completely specify a location on, in, or above the Earth, one has to specify also the elevation / height position. This can e.g., be expressed relative to a [[datum]] such as mean [[sea level]] ([[above mean sea level]]) or the [[geoid]]. The distance to the Earth's center is a practical coordinate both for very deep positions and for positions in space. |
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{{block indent|1= |
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The elevation specifies the vertical position of the Earth surface. |
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<math> \frac{\pi}{180}M_r\cos \phi \!</math> |
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}} |
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where [[Earth radius#Meridional Earth radius|Earth's average meridional radius]] <math>\textstyle{M_r}\,\!</math> is {{nowrap|6,367,449 m}}. Since the Earth is an [[Spheroid#Oblate spheroids|oblate spheroid]], not spherical, that result can be off by several tenths of a percent; a better approximation of a longitudinal degree at latitude <math>\phi</math> is |
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Various elevation / height coordinates either with respect to the surface or some other datum are [[altitude]], [[height]], and [[depth]]. |
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{{block indent|1= |
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<math>\frac{\pi}{180}a \cos \beta \,\!</math> |
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}} |
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where Earth's equatorial radius <math>a</math> equals 6,378,137 m and <math>\textstyle{\tan \beta = \frac{b}{a}\tan\phi}\,\!</math>; for the GRS{{nbsp}}80 and WGS{{nbsp}}84 spheroids, <math display="inline">\tfrac{b}{a}=0.99664719</math>. (<math>\textstyle{\beta}\,\!</math> is known as the [[Latitude#Parametric (or reduced) latitude|reduced (or parametric) latitude]]). Aside from rounding, this is the exact distance along a parallel of latitude; getting the distance along the shortest route will be more work, but those two distances are always within 0.6 m of each other if the two points are one degree of longitude apart. |
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{| class="wikitable" |
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|+ Longitudinal length equivalents at selected latitudes |
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|- |
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! style="width:100px;" | Latitude |
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! style="width:150px;" | City |
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! style="width:100px;" | Degree |
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! style="width:100px;" | Minute |
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! style="width:100px;" | Second |
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! style="width:100px;" | 0.0001° |
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|- |
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| 60° |
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| [[Saint Petersburg]] |
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| style="text-align:center;" | 55.80 km |
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| style="text-align:center;" | 0.930 km |
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| style="text-align:center;" | 15.50 m |
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| style="text-align:center;" | 5.58 m |
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|- |
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| 51° 28′ 38″ N |
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| [[Greenwich]] |
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| style="text-align:center;" | 69.47 km |
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| style="text-align:center;" | 1.158 km |
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| style="text-align:center;" | 19.30 m |
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| style="text-align:center;" | 6.95 m |
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|- |
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| 45° |
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| [[Bordeaux]] |
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| style="text-align:center;" | 78.85 km |
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| style="text-align:center;" | 1.31 km |
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| style="text-align:center;" | 21.90 m |
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| style="text-align:center;" | 7.89 m |
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|- |
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| 30° |
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| [[New Orleans]] |
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| style="text-align:center;" | 96.49 km |
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| style="text-align:center;" | 1.61 km |
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| style="text-align:center;" | 26.80 m |
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| style="text-align:center;" | 9.65 m |
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|- |
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| 0° |
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| [[Quito]] |
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| style="text-align:center;" | 111.3 km |
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| style="text-align:center;" | 1.855 km |
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| style="text-align:center;" | 30.92 m |
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| style="text-align:center;" | 11.13 m |
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|} |
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<!--The Equator is the [[fundamental plane (spherical coordinates)|fundamental plane]] of all geographic coordinate systems. All spherical coordinate systems define such a fundamental plane.--> |
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==Alternate encodings== |
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== The proposed hexadecimal geographic coordinate system == |
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Like any series of multiple-digit numbers, latitude-longitude pairs can be challenging to communicate and remember. Therefore, alternative schemes have been developed for encoding GCS coordinates into alphanumeric strings or words: |
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* the [[Maidenhead Locator System]], popular with radio operators. |
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* the [[World Geographic Reference System]] (GEOREF), developed for global military operations, replaced by the current [[Global Area Reference System]] (GARS). |
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* [[Open Location Code]] or "Plus Codes", developed by Google and released into the public domain. |
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* [[Geohash]], a public domain system based on the Morton [[Z-order curve]]. |
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* [[Mapcode]], an open-source system originally developed at TomTom. |
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* [[What3words]], a proprietary system that encodes GCS coordinates as pseudorandom sets of words by dividing the coordinates into three numbers and looking up words in an indexed dictionary. |
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These are not distinct coordinate systems, only alternative methods for expressing latitude and longitude measurements. |
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Since several years a new, modern, hexadecimal geographic coordinate system is proposed. ''(See also [[hexadecimal time]] and Web link below.)'' |
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== See also == |
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* {{annotated link|Decimal degrees}} |
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The main meridian zero degree hexadecimal (± Q°QQ'q) is identical to the meridian 11°15' East of Greenwich, which also crosses the city center of [[Florence]] ([[Italy]]). It crosses the equator with a continental point of [[confluence]] in [[Gabon]]. |
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* {{annotated link|Geographical distance}} |
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* {{annotated link|Geographic information system}} |
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* {{annotated link|Geo URI scheme}} |
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* [[ISO 6709]], standard representation of geographic point location by coordinates |
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* {{annotated link|Linear referencing}} |
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* {{annotated link|Primary direction}} |
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* [[Planetary coordinate system]] |
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** [[Selenographic coordinate system]] |
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* {{annotated link|Spatial reference system}} |
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* Jan Smits (2015). [http://ica-proj.kartografija.hr/for-librarians.en.html#co Mathematical data for bibliographic descriptions of cartographic materials and spatial data]. ''Geographical co-ordinates''. [[International Cartographic Association|ICA]] Commission on Map Projections. |
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== Notes == |
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Beginning with this main meridian the earth is divided into both sixteen ''eastern'' hexadecimal degrees, designate: ''plus,'' and sixteen ''western'' hexadecimal degrees: ''minus''. |
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{{NoteFoot}} |
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== References == |
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The meridian sixteen hexadecimal degrees: ± H°QQ'q (= 168°45' W of Greenwich) passes, maritime, in the [[Bering Strait]] next to the small uninhabited [[Fairway Rock Island]]. |
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{{Reflist}} |
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=== Sources === |
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Perpendicular to the longitudinal great circle [[Gabon]] - Bering Strait is situated the great circle [[Sumatra]] (in [[Asia]]) - [[Ecuador]] (in [[South America]]), plus and minus eight hexadecimal degrees. It crosses the equator of Earth even with two continental points of confluence, respectively at +T°QQ'q (= 101°15' E Greenwich) and at -T°QQ'q (= 78°45' W of Greenwich). |
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{{refbegin}} |
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* ''Portions of this article are from Jason Harris' "Astroinfo" which is distributed with [[KStars]], a desktop planetarium for [[Linux]]/[[KDE]]. See [http://edu.kde.org/kstars/index.phtml The KDE Education Project – KStars] {{Webarchive|url=https://web.archive.org/web/20080517043629/http://edu.kde.org/kstars/index.phtml |date=17 May 2008 }}'' |
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{{refend}} |
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== External links == |
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In this hexadecimal geographic coordinate system, the sexagesimal main meridian of Greenwich is only one of the 32 hexadecimal main meridians spanned from pole to [[geographical pole|pole]]. |
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* {{Commons category-inline}} |
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{{-}} |
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=== Hexadecimal [[latitude]]s === |
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{{Geographical coordinates |state = autocollapse }} |
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{{Authority control}} |
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[[Category:Geographic coordinate systems| ]] |
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The [[North pole]] is located at latitude ''plus eight'' hexadecimal degrees like the [[South pole]] at latitude ''minus eight'' degrees. |
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[[Category:Cartography]] |
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[[Category:Geographic position|*]] |
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The latitudes plus and minus four hexadecimal degrees correspond respectively to 45° North and 45° South. The latitudes plus and minus two hexadecimal degrees (= 22° 30') are next to the [[tropic]]s, like the latitudes plus and minus six hexadecimal degrees (= 67° 30') are situated near the [[polar circle]]s. ''(The polar circles are now at about 66°33.6', but at less then 66° five milleniums before. cf. [[Obliquity of the ecliptic]].)'' |
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[[Category:Geodesy]] |
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[[Category:Navigation]] |
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=== Advantages of the hexadecimal earthgrid === |
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''Among the various advantages of the hexadecimal geographic coordinate system one can annotate:'' |
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* In sexagesimal maps there is no main grid. Depending on the [[Scale (map)|scale]] used, some maps refer grids in distances of 10°, 4° or 3° for example. Thus even such important latitudes like 45° did not appear. In the hexadecimal grid there is a clear hierarchy of importance. Between two gridlines, if necessary, exactly in the middle, a new gridline can be drawed. This is very useful for zoomings. |
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* Generally binary map scales are harmonic and more practical; for example 1:16,384 or 1:65,536 or 1:262,144 etc. For zooming even ''[[radix]] two'' scales can be employed. |
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* Beyond doubt, the [[Earth]] hemispheres are better divided with one of the four cardinal meridians situated almost in the middle of Bering Strait. |
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''Example:''<br> |
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The city of [[New Orleans]], [[Louisiana]] is located at 29° 57′ 53″ N, 90° 04′ 14″ W. In hexadecimal degrees, this is longitude (always first!) -J°QB'c and latitude +P°CJ'x. This can be pronounced: "Nine degrees, one minute and ten sixteenth East of Florence." As well as: "Two hexadecimal degrees, ''tenty''-nine minutes and fourteen sixteenth north of the equator." |
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==See also== |
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*[[GIS]] |
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*[[GPS]] |
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*[[Geographic coordinates (obtaining)]] |
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*[[Geographic coordinate conversion]] |
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*[[geocode]]s |
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*[[Tropic of Cancer]] |
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*[[Tropic of Capricorn]] |
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*[[Great-circle distance]] explains how to find that quantity if one knows the two latitudes and longitudes. |
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*[[Map projection]] |
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==External links== |
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*[http://math.rice.edu/~lanius/pres/map/mapcoo.html Mathematics Topics-Coordinate System] |
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*[http://jan.ucc.nau.edu/~cvm/latlon_find_location.html How to find your latitude and longitude] |
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*[http://www.cia.gov/cia/publications/factbook/fields/2011.html Geographic coordinates of countries (CIA World Factbook)] |
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*[http://www.paddles.com/users/wildcamp/coordexp.html Coordinates systems]. |
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*[http://www.satsig.net/degrees-minutes-seconds-calculator.htm Degrees, Minutes, Seconds to Decimal Degrees calculator]. |
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*[http://www.hexadecimal.free.fr/ Hexadecimal Earthgrid], four world hemispere maps changing every 675/64 seconds. |
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[[Category:Coordinate systems]] |
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[[category:Cartography]] |
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[[category:Navigation]] |
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[[Category:Geocodes]] |
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[[bg:Географско положение]] |
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[[de:Geografische Koordinaten]] |
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[[et:Geograafilised koordinaadid]] |
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[[el:Γεωγραφικές συντεταγμένες]] |
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[[es:Coordenadas geográficas]] |
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[[ko:지리 좌표계]] |
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[[id:Sistem koordinat geografi]] |
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[[it:Coordinate geografiche]] |
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[[nl:Geografische coördinaten]] |
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[[ja:測地系]] |
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[[pt:Sistema de coordenadas geográficas]] |
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[[ru:Географические координаты]] |
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[[sl:Geografski koordinatni sistem]] |
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[[sv:Jordens koordinatsystem]] |
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Latest revision as of 21:14, 4 January 2025
| Geodesy |
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A geographic coordinate system (GCS) is a spherical or geodetic coordinate system for measuring and communicating positions directly on Earth as latitude and longitude.[1] It is the simplest, oldest and most widely used type of the various spatial reference systems that are in use, and forms the basis for most others. Although latitude and longitude form a coordinate tuple like a cartesian coordinate system, the geographic coordinate system is not cartesian because the measurements are angles and are not on a planar surface.[2]
A full GCS specification, such as those listed in the EPSG and ISO 19111 standards, also includes a choice of geodetic datum (including an Earth ellipsoid), as different datums will yield different latitude and longitude values for the same location.[3]
History
[edit]The invention of a geographic coordinate system is generally credited to Eratosthenes of Cyrene, who composed his now-lost Geography at the Library of Alexandria in the 3rd century BC.[4] A century later, Hipparchus of Nicaea improved on this system by determining latitude from stellar measurements rather than solar altitude and determining longitude by timings of lunar eclipses, rather than dead reckoning. In the 1st or 2nd century, Marinus of Tyre compiled an extensive gazetteer and mathematically plotted world map using coordinates measured east from a prime meridian at the westernmost known land, designated the Fortunate Isles, off the coast of western Africa around the Canary or Cape Verde Islands, and measured north or south of the island of Rhodes off Asia Minor. Ptolemy credited him with the full adoption of longitude and latitude, rather than measuring latitude in terms of the length of the midsummer day.[5]
Ptolemy's 2nd-century Geography used the same prime meridian but measured latitude from the Equator instead. After their work was translated into Arabic in the 9th century, Al-Khwārizmī's Book of the Description of the Earth corrected Marinus' and Ptolemy's errors regarding the length of the Mediterranean Sea,[note 1] causing medieval Arabic cartography to use a prime meridian around 10° east of Ptolemy's line. Mathematical cartography resumed in Europe following Maximus Planudes' recovery of Ptolemy's text a little before 1300; the text was translated into Latin at Florence by Jacopo d'Angelo around 1407.
In 1884, the United States hosted the International Meridian Conference, attended by representatives from twenty-five nations. Twenty-two of them agreed to adopt the longitude of the Royal Observatory in Greenwich, England as the zero-reference line. The Dominican Republic voted against the motion, while France and Brazil abstained.[6] France adopted Greenwich Mean Time in place of local determinations by the Paris Observatory in 1911.
Latitude and longitude
[edit]
The latitude φ of a point on Earth's surface is the angle between the equatorial plane and the straight line that passes through that point and through (or close to) the center of the Earth.[note 2] Lines joining points of the same latitude trace circles on the surface of Earth called parallels, as they are parallel to the Equator and to each other. The North Pole is 90° N; the South Pole is 90° S. The 0° parallel of latitude is designated the Equator, the fundamental plane of all geographic coordinate systems. The Equator divides the globe into Northern and Southern Hemispheres.
The longitude λ of a point on Earth's surface is the angle east or west of a reference meridian to another meridian that passes through that point. All meridians are halves of great ellipses (often called great circles), which converge at the North and South Poles. The meridian of the British Royal Observatory in Greenwich, in southeast London, England, is the international prime meridian, although some organizations—such as the French Institut national de l'information géographique et forestière—continue to use other meridians for internal purposes. The prime meridian determines the proper Eastern and Western Hemispheres, although maps often divide these hemispheres further west in order to keep the Old World on a single side. The antipodal meridian of Greenwich is both 180°W and 180°E. This is not to be conflated with the International Date Line, which diverges from it in several places for political and convenience reasons, including between far eastern Russia and the far western Aleutian Islands.
The combination of these two components specifies the position of any location on the surface of Earth, without consideration of altitude or depth. The visual grid on a map formed by lines of latitude and longitude is known as a graticule.[7] The origin/zero point of this system is located in the Gulf of Guinea about 625 km (390 mi) south of Tema, Ghana, a location often facetiously called Null Island.
Geodetic datum
[edit]In order to use the theoretical definitions of latitude, longitude, and height to precisely measure actual locations on the physical earth, a geodetic datum must be used. A horizonal datum is used to precisely measure latitude and longitude, while a vertical datum is used to measure elevation or altitude. Both types of datum bind a mathematical model of the shape of the earth (usually a reference ellipsoid for a horizontal datum, and a more precise geoid for a vertical datum) to the earth. Traditionally, this binding was created by a network of control points, surveyed locations at which monuments are installed, and were only accurate for a region of the surface of the Earth. Newer datums are based on a global network for satellite measurements (GNSS, VLBI, SLR and DORIS).
This combination of mathematical model and physical binding mean that anyone using the same datum will obtain the same location measurement for the same physical location. However, two different datums will usually yield different location measurements for the same physical location, which may appear to differ by as much as several hundred meters; this not because the location has moved, but because the reference system used to measure it has shifted. Because any spatial reference system or map projection is ultimately calculated from latitude and longitude, it is crucial that they clearly state the datum on which they are based. For example, a UTM coordinate based on a WGS84 realisation will be different than a UTM coordinate based on NAD27 for the same location. Converting coordinates from one datum to another requires a datum transformation such as a Helmert transformation, although in certain situations a simple translation may be sufficient.[8]
Datums may be global, meaning that they represent the whole Earth, or they may be regional,[9] meaning that they represent an ellipsoid best-fit to only a portion of the Earth. Examples of global datums include the several realizations of WGS 84 (with the 2D datum ensemble EPSG:4326 with 2 meter accuracy as identifier)[10][11] used for the Global Positioning System,[note 3] and the several realizations of the International Terrestrial Reference System and Frame (such as ITRF2020 with subcentimeter accuracy), which takes into account continental drift and crustal deformation.[12]
Datums with a regional fit of the ellipsoid that are chosen by a national cartographical organization include the North American Datums, the European ED50, and the British OSGB36. Given a location, the datum provides the latitude and longitude . In the United Kingdom there are three common latitude, longitude, and height systems in use. WGS 84 differs at Greenwich from the one used on published maps OSGB36 by approximately 112 m. ED50 differs from about 120 m to 180 m.[13]
Points on the Earth's surface move relative to each other due to continental plate motion, subsidence, and diurnal Earth tidal movement caused by the Moon and the Sun. This daily movement can be as much as a meter. Continental movement can be up to 10 cm a year, or 10 m in a century. A weather system high-pressure area can cause a sinking of 5 mm. Scandinavia is rising by 1 cm a year as a result of the melting of the ice sheets of the last ice age, but neighboring Scotland is rising by only 0.2 cm. These changes are insignificant if a regional datum is used, but are statistically significant if a global datum is used.[13]
Length of a degree
[edit]On the GRS 80 or WGS 84 spheroid at sea level at the Equator, one latitudinal second measures 30.715 m, one latitudinal minute is 1843 m and one latitudinal degree is 110.6 km. The circles of longitude, meridians, meet at the geographical poles, with the west–east width of a second naturally decreasing as latitude increases. On the Equator at sea level, one longitudinal second measures 30.92 m, a longitudinal minute is 1855 m and a longitudinal degree is 111.3 km. At 30° a longitudinal second is 26.76 m, at Greenwich (51°28′38″N) 19.22 m, and at 60° it is 15.42 m.
On the WGS 84 spheroid, the length in meters of a degree of latitude at latitude ϕ (that is, the number of meters you would have to travel along a north–south line to move 1 degree in latitude, when at latitude ϕ), is about
The returned measure of meters per degree latitude varies continuously with latitude.
Similarly, the length in meters of a degree of longitude can be calculated as
(Those coefficients can be improved, but as they stand the distance they give is correct within a centimeter.)
The formulae both return units of meters per degree.
An alternative method to estimate the length of a longitudinal degree at latitude is to assume a spherical Earth (to get the width per minute and second, divide by 60 and 3600, respectively):
where Earth's average meridional radius is 6,367,449 m. Since the Earth is an oblate spheroid, not spherical, that result can be off by several tenths of a percent; a better approximation of a longitudinal degree at latitude is
where Earth's equatorial radius equals 6,378,137 m and ; for the GRS 80 and WGS 84 spheroids, . ( is known as the reduced (or parametric) latitude). Aside from rounding, this is the exact distance along a parallel of latitude; getting the distance along the shortest route will be more work, but those two distances are always within 0.6 m of each other if the two points are one degree of longitude apart.
| Latitude | City | Degree | Minute | Second | 0.0001° |
|---|---|---|---|---|---|
| 60° | Saint Petersburg | 55.80 km | 0.930 km | 15.50 m | 5.58 m |
| 51° 28′ 38″ N | Greenwich | 69.47 km | 1.158 km | 19.30 m | 6.95 m |
| 45° | Bordeaux | 78.85 km | 1.31 km | 21.90 m | 7.89 m |
| 30° | New Orleans | 96.49 km | 1.61 km | 26.80 m | 9.65 m |
| 0° | Quito | 111.3 km | 1.855 km | 30.92 m | 11.13 m |
Alternate encodings
[edit]Like any series of multiple-digit numbers, latitude-longitude pairs can be challenging to communicate and remember. Therefore, alternative schemes have been developed for encoding GCS coordinates into alphanumeric strings or words:
- the Maidenhead Locator System, popular with radio operators.
- the World Geographic Reference System (GEOREF), developed for global military operations, replaced by the current Global Area Reference System (GARS).
- Open Location Code or "Plus Codes", developed by Google and released into the public domain.
- Geohash, a public domain system based on the Morton Z-order curve.
- Mapcode, an open-source system originally developed at TomTom.
- What3words, a proprietary system that encodes GCS coordinates as pseudorandom sets of words by dividing the coordinates into three numbers and looking up words in an indexed dictionary.
These are not distinct coordinate systems, only alternative methods for expressing latitude and longitude measurements.
See also
[edit]- Decimal degrees – Angular measurements, typically for latitude and longitude
- Geographical distance – Distance measured along the surface of the Earth
- Geographic information system – System to capture, manage, and present geographic data
- Geo URI scheme – System of geographic location identifiers
- ISO 6709, standard representation of geographic point location by coordinates
- Linear referencing – method of spatial referencing
- Primary direction – Celestial coordinate system used to specify the positions of celestial objects
- Planetary coordinate system
- Spatial reference system – System to specify locations on Earth
- Jan Smits (2015). Mathematical data for bibliographic descriptions of cartographic materials and spatial data. Geographical co-ordinates. ICA Commission on Map Projections.
Notes
[edit]- ^ The pair had accurate absolute distances within the Mediterranean but underestimated the circumference of the Earth, causing their degree measurements to overstate its length west from Rhodes or Alexandria, respectively.
- ^ Alternative versions of latitude and longitude include geocentric coordinates, which measure with respect to Earth's center; geodetic coordinates, which model Earth as an ellipsoid; and geographic coordinates, which measure with respect to a plumb line at the location for which coordinates are given.
- ^ WGS 84 is the default datum used in most GPS equipment, but other datums and map projections can be selected.
References
[edit]- ^ Chang, Kang-tsung (2016). Introduction to Geographic Information Systems (9th ed.). McGraw-Hill. p. 24. ISBN 978-1-259-92964-9.
- ^ DiBiase, David. "The Nature of Geographic Information". Archived from the original on 19 February 2024. Retrieved 18 February 2024.
- ^ "Using the EPSG geodetic parameter dataset, Guidance Note 7-1". EPSG Geodetic Parameter Dataset. Geomatic Solutions. Archived from the original on 15 December 2021. Retrieved 15 December 2021.
- ^ McPhail, Cameron (2011), Reconstructing Eratosthenes' Map of the World (PDF), Dunedin: University of Otago, pp. 20–24, archived (PDF) from the original on 2 April 2015, retrieved 14 March 2015.
- ^ Evans, James (1998), The History and Practice of Ancient Astronomy, Oxford, England: Oxford University Press, pp. 102–103, ISBN 9780199874453, archived from the original on 17 March 2023, retrieved 5 May 2020.
- ^ "The International Meridian Conference". Millennium Dome: The O2 in Greenwich. Greenwich 2000 Limited. 9 June 2011. Archived from the original on 6 August 2012. Retrieved 31 October 2012.
- ^ American Society of Civil Engineers (1 January 1994). Glossary of the Mapping Sciences. ASCE Publications. p. 224. ISBN 9780784475706.
- ^ "Making maps compatible with GPS". Government of Ireland 1999. Archived from the original on 21 July 2011. Retrieved 15 April 2008.
- ^ "A guide to the coordinate systems in Great Britain". Ordnance Survey.
- ^ "WGS 84: EPSG Projection -- Spatial Reference". spatialreference.org. Archived from the original on 13 May 2020. Retrieved 5 May 2020.
- ^ EPSG:4326
- ^ Bolstad, Paul (2012). GIS Fundamentals (PDF) (5th ed.). Atlas books. p. 102. ISBN 978-0-9717647-3-6. Archived from the original (PDF) on 15 October 2020. Retrieved 27 January 2018.
- ^ a b A guide to coordinate systems in Great Britain (PDF), D00659 v3.6, Ordnance Survey, 2020, archived (PDF) from the original on 2 April 2020, retrieved 17 December 2021
- ^ a b [1] Archived 29 June 2016 at the Wayback Machine Geographic Information Systems – Stackexchange
Sources
[edit]- Portions of this article are from Jason Harris' "Astroinfo" which is distributed with KStars, a desktop planetarium for Linux/KDE. See The KDE Education Project – KStars Archived 17 May 2008 at the Wayback Machine
External links
[edit]
Media related to Geographic coordinate system at Wikimedia Commons
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