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Web Mercator projection

January 01, 1970

Web Mercator, Google Web Mercator, Spherical Mercator, WGS 84 Web Mercator[1] or WGS 84/Pseudo-Mercator is a variant of the Mercator map projection and is the de facto standard for Web mapping applications. It rose to prominence when Google Maps adopted it in 2005.[2] It is used by virtually all major online map providers, including Google Maps, CARTO, Mapbox,[3] Bing Maps, OpenStreetMap, Mapquest, Esri, and many others.[4] Its official EPSG identifier is EPSG:3857, although others have been used historically.

The Web Mercator projection is almost indistinguishable at global scale from a Mercator projection cropped to around 85°N to 85°S
Homepage of OpenStreetMap in 2018. The standard style for OpenStreetMap, like most Web maps, uses the Web Mercator projection

Properties edit

Web Mercator is a slight variant of the Mercator projection, one used primarily in Web-based mapping programs. It uses the same formulas as the standard Mercator as used for small-scale maps. However, the Web Mercator uses the spherical formulas at all scales whereas large-scale Mercator maps normally use the ellipsoidal form of the projection.[citation needed] The discrepancy is imperceptible at the global scale but causes maps of local areas to deviate slightly from true ellipsoidal Mercator maps at the same scale. This deviation becomes more pronounced further from the equator, and can reach as much as 40 km on the ground.[5][6]

While the Web Mercator's formulas are for the spherical form of the Mercator, geographical coordinates are required to be in the WGS 84 ellipsoidal datum. This discrepancy causes the projection to be slightly non-conformal. General lack of understanding that the Web Mercator differs from standard Mercator usage has caused considerable confusion and misuse.[4]: 87  For all these reasons, the United States Department of Defense through the National Geospatial-Intelligence Agency has declared this map projection to be unacceptable for any official use.[5]

Unlike most map projections for the sphere, the Web Mercator uses the equatorial radius of the WGS 84 spheroid, rather than some compromise between the equatorial and polar radii. This results in a slightly larger map compared to the map's stated (nominal) scale than for most maps.

Formulas edit

Formulas for the Web Mercator are fundamentally the same as for the standard spherical Mercator, but before applying zoom, the "world coordinates" are adjusted such that the upper left corner is (0, 0) and the lower right corner is (  ,  ):[7]

 
where   is the longitude in radians and   is geodetic latitude in radians.[8]

Because the Mercator projects the poles at infinity, a map using the Web Mercator projection cannot show the poles. Services such as Google Maps cut off coverage at 85.051129° north and south. This is not a limitation for street maps, which is the primary purpose for such services. The value 85.051129° is the latitude at which the full projected map becomes a square, and is computed as   given y = 0:

 

Spherical and ellipsoidal mix edit

The projection is neither strictly ellipsoidal nor strictly spherical. EPSG's definition says the projection "uses spherical development of ellipsoidal coordinates".[9] The underlying geographic coordinates are defined using the WGS84 ellipsoidal model of the Earth's surface, but are projected as if defined on a sphere.[6] This practice is uncontroversial for small-scale maps (such as of the entire world), but has little precedent in large-scale maps (such as of a city or province).[10]

Advantages and disadvantages edit

Web Mercator is a spherical Mercator projection, and so it has the same properties as a spherical Mercator: north is up everywhere, meridians are equally spaced vertical lines, angles are locally correct (assuming spherical coordinates), and areas inflate with distance from the equator such that the polar regions are grossly exaggerated. The ellipsoidal Mercator has these same properties, but models the earth as an ellipsoid.

Unlike the ellipsoidal Mercator, however, the Web Mercator is not quite conformal. This means that angles between lines on the surface will not be drawn to the same angles in the map, although they will not deviate enough to be noticeable by eye. Lines deviate because Web Mercator specifies that coordinates be given as surveyed on the WGS 84 ellipsoidal model. By projecting coordinates surveyed against the ellipsoid as if they were surveyed on a sphere, angular relationships change slightly. This is standard practice on the standard spherical Mercator projection, but unlike Web Mercator, the spherical Mercator is not normally used for maps of local areas, such as street maps, and so the accuracy of positions needed for plotting is typically less than the angular deviation caused by using spherical formulas. The benefit the Web Mercator gains is that the spherical form is much simpler to calculate than the ellipsoidal form, and so requires only a fraction of the computing resources.[11]

Identifiers edit

Due to slow adoption by the EPSG registry, the Web Mercator is represented by several different names and spatial reference system identifiers (SRIDs), including EPSG:900913, EPSG:3785 and EPSG:3857, the latter being the official EPSG identifier since 2009.[12]

EPSG:900913 edit

The projected coordinate reference system originally lacked an official spatial reference identifier (SRID), and the Geodesy subcommittee of the OGP's Geomatics committee (also known as EPSG) refused to provide it with one, declaring "We have reviewed the coordinate reference system used by Microsoft, Google, etc. and believe that it is technically flawed. We will not devalue the EPSG dataset by including such inappropriate geodesy and cartography."[13] The unofficial code "EPSG:900913" (GOOGLE transliterated to numbers) came to be used. It was originally defined by Christopher Schmidt in his Technical Ramblings blog[14] and became codified in OpenLayers 2,[15] which, technically, would make OpenLayers the SRID authority.

EPSG:3785 edit

In 2008, EPSG provided the official identifier EPSG:3785 with the official name "Popular Visualisation CRS / Mercator", but noted "It is not an official geodetic system".[6] This definition used a spherical (rather than ellipsoidal) model of the Earth.

EPSG:3857 edit

Later that year, EPSG provided an updated identifier, EPSG:3857 with the official name "WGS 84 / Pseudo-Mercator".[6] The definition switched to using the WGS84 ellipsoid (EPSG:4326), rather than the sphere.

Although the projection is closely associated with Google, Microsoft is listed as the "information source" in EPSG's standards.[12]

Other identifiers edit

Other identifiers that have been used include ESRI:102113, ESRI:102100, and OSGEO:41001.[16][14]

ESRI:102113 corresponds to EPSG:3785 while ESRI:102100 corresponds to EPSG:3857.[17]

WKT definition edit

The projection covers the Earth from −180° to 180° longitude, and 85.05° north and south. Using well-known text representation of coordinate reference systems (WKT), EPSG:3857 is defined as follows:[12] 

PROJCRS["WGS 84 / Pseudo-Mercator", BASEGEOGCRS["WGS 84", ENSEMBLE["World Geodetic System 1984 ensemble",  MEMBER["World Geodetic System 1984 (Transit)", ID["EPSG",1166]],  MEMBER["World Geodetic System 1984 (G730)", ID["EPSG",1152]],  MEMBER["World Geodetic System 1984 (G873)", ID["EPSG",1153]],  MEMBER["World Geodetic System 1984 (G1150)", ID["EPSG",1154]],  MEMBER["World Geodetic System 1984 (G1674)", ID["EPSG",1155]],  MEMBER["World Geodetic System 1984 (G1762)", ID["EPSG",1156]],  MEMBER["World Geodetic System 1984 (G2139)", ID["EPSG",1309]],  ELLIPSOID["WGS 84", 6378137, 298.257223563, LENGTHUNIT["metre", 1, ID["EPSG",9001]], ID["EPSG",7030]],  ENSEMBLEACCURACY[2], ID["EPSG",6326]], ID["EPSG",4326]], CONVERSION["Popular Visualisation Pseudo-Mercator", METHOD["Popular Visualisation Pseudo Mercator", ID["EPSG",1024]], PARAMETER["Latitude of natural origin", 0, ANGLEUNIT["degree", 0.0174532925199433, ID["EPSG",9102]], ID["EPSG",8801]], PARAMETER["Longitude of natural origin", 0, ANGLEUNIT["degree", 0.0174532925199433, ID["EPSG",9102]], ID["EPSG",8802]], PARAMETER["False easting",  0, LENGTHUNIT["metre", 1,  ID["EPSG",9001]], ID["EPSG",8806]], PARAMETER["False northing",  0, LENGTHUNIT["metre", 1,  ID["EPSG",9001]], ID["EPSG",8807]], ID["EPSG",3856]], CS[Cartesian, 2, ID["EPSG",4499]], AXIS["Easting (X)", east], AXIS["Northing (Y)", north], LENGTHUNIT["metre", 1, ID["EPSG",9001]], ID["EPSG",3857]]

References edit

  1. ^ (PDF). National Geospatial-Intelligence Agency. 2014-05-16. Archived from the original (PDF) on 2014-10-09. Retrieved 2014-08-06.
  2. ^ "Google Maps & Earth Help Forum". Retrieved 29 August 2017.
  3. ^ "Our Map Data". MapBox. Retrieved June 20, 2018. Mapbox supports the popular Web Mercator projection, and currently does not support any other projections for display.
  4. ^ a b Battersby, Sarah E.; Finn, Michael P.; Usery, E. Lynn; Yamamoto, Kristina H. (2014). (PDF). Cartographica. 49 (2): 92. doi:10.3138/carto.49.2.2313. S2CID 6403891. Archived from the original on 15 February 2015.
  5. ^ a b . National Geospatial-Intelligence Agency Office of Geomatics. 2014-02-18. Archived from the original on 2017-03-29. Retrieved 4 October 2014.
  6. ^ a b c d "The Google Maps / Bing Maps Spherical Mercator Projection". Alastair Aitchison. 23 January 2011. Retrieved 4 October 2014.
  7. ^ "OpenStreetMap Slippy map tilenames". openstreetmap.org. Retrieved 2018-11-14.
  8. ^ See Inverse Gudermannian_function:  .
  9. ^ . www.epsg-registry.org. Archived from the original on 2012-06-22.
  10. ^ Strebe, Daniel "daan" (2019). "A bevy of area-preserving transforms for map projection designers". Cartography and Geographic Information Science. 46 (3): 260–276. Bibcode:2019CGISc..46..260S. doi:10.1080/15230406.2018.1452632. S2CID 134864785.
  11. ^ "The Earth is Not Round! Utah, NAD83 and WebMercator Projections". Utah GIS Portal. Retrieved 2020-06-20.
  12. ^ a b c EPSG registry. "WGS 84 / Pseudo-Mercator". epsg.org.
  13. ^ "dotMorten | Spherical/Web Mercator: EPSG code 3785". www.sharpgis.net.
  14. ^ a b "Google Projection: 900913". August 7, 2007.
  15. ^ . docs.openlayers.org. Archived from the original on 2021-04-18. Retrieved 2018-11-12.
  16. ^ Klokan Technologies GmbH. "WGS 84 / Pseudo-Mercator - Spherical Mercator, Google Maps, OpenStreetMap, Bing, ArcGIS, ESRI - EPSG:3857". epsg.io.
  17. ^ "102100 vs. 102113 is mixed up?". GeoNet, The Esri Community. October 3, 2012.

January 01, 1970
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Web Mercator Google Web Mercator Spherical Mercator WGS 84 Web Mercator 1 or WGS 84 Pseudo Mercator is a variant of the Mercator map projection and is the de facto standard for Web mapping applications It rose to prominence when Google Maps adopted it in 2005 2 It is used by virtually all major online map providers including Google Maps CARTO Mapbox 3 Bing Maps OpenStreetMap Mapquest Esri and many others 4 Its official EPSG identifier is EPSG 3857 although others have been used historically The Web Mercator projection is almost indistinguishable at global scale from a Mercator projection cropped to around 85 N to 85 S Homepage of OpenStreetMap in 2018 The standard style for OpenStreetMap like most Web maps uses the Web Mercator projection Contents 1 Properties 1 1 Formulas 1 2 Spherical and ellipsoidal mix 1 3 Advantages and disadvantages 2 Identifiers 2 1 EPSG 900913 2 2 EPSG 3785 2 3 EPSG 3857 2 4 Other identifiers 3 WKT definition 4 ReferencesProperties editWeb Mercator is a slight variant of the Mercator projection one used primarily in Web based mapping programs It uses the same formulas as the standard Mercator as used for small scale maps However the Web Mercator uses the spherical formulas at all scales whereas large scale Mercator maps normally use the ellipsoidal form of the projection citation needed The discrepancy is imperceptible at the global scale but causes maps of local areas to deviate slightly from true ellipsoidal Mercator maps at the same scale This deviation becomes more pronounced further from the equator and can reach as much as 40 km on the ground 5 6 While the Web Mercator s formulas are for the spherical form of the Mercator geographical coordinates are required to be in the WGS 84 ellipsoidal datum This discrepancy causes the projection to be slightly non conformal General lack of understanding that the Web Mercator differs from standard Mercator usage has caused considerable confusion and misuse 4 87 For all these reasons the United States Department of Defense through the National Geospatial Intelligence Agency has declared this map projection to be unacceptable for any official use 5 Unlike most map projections for the sphere the Web Mercator uses the equatorial radius of the WGS 84 spheroid rather than some compromise between the equatorial and polar radii This results in a slightly larger map compared to the map s stated nominal scale than for most maps Formulas edit Formulas for the Web Mercator are fundamentally the same as for the standard spherical Mercator but before applying zoom the world coordinates are adjusted such that the upper left corner is 0 0 and the lower right corner is 2 zoom level 1 displaystyle 2 text zoom level 1 nbsp 2 zoom level 1 displaystyle 2 text zoom level 1 nbsp 7 x 1 2 p 2 zoom level p l pixels y 1 2 p 2 zoom level p ln tan p 4 f 2 pixels displaystyle begin aligned x amp left lfloor frac 1 2 pi cdot 2 text zoom level left pi lambda right right rfloor text pixels 5pt y amp left lfloor frac 1 2 pi cdot 2 text zoom level left pi ln left tan left frac pi 4 frac varphi 2 right right right right rfloor text pixels end aligned nbsp where l displaystyle lambda nbsp is the longitude in radians and f displaystyle varphi nbsp is geodetic latitude in radians 8 Because the Mercator projects the poles at infinity a map using the Web Mercator projection cannot show the poles Services such as Google Maps cut off coverage at 85 051129 north and south This is not a limitation for street maps which is the primary purpose for such services The value 85 051129 is the latitude at which the full projected map becomes a square and is computed as f displaystyle varphi nbsp given y 0 f max 2 arctan e p p 2 displaystyle begin aligned varphi text max left 2 arctan e pi frac pi 2 right end aligned nbsp Spherical and ellipsoidal mix edit The projection is neither strictly ellipsoidal nor strictly spherical EPSG s definition says the projection uses spherical development of ellipsoidal coordinates 9 The underlying geographic coordinates are defined using the WGS84 ellipsoidal model of the Earth s surface but are projected as if defined on a sphere 6 This practice is uncontroversial for small scale maps such as of the entire world but has little precedent in large scale maps such as of a city or province 10 Advantages and disadvantages edit Web Mercator is a spherical Mercator projection and so it has the same properties as a spherical Mercator north is up everywhere meridians are equally spaced vertical lines angles are locally correct assuming spherical coordinates and areas inflate with distance from the equator such that the polar regions are grossly exaggerated The ellipsoidal Mercator has these same properties but models the earth as an ellipsoid Unlike the ellipsoidal Mercator however the Web Mercator is not quite conformal This means that angles between lines on the surface will not be drawn to the same angles in the map although they will not deviate enough to be noticeable by eye Lines deviate because Web Mercator specifies that coordinates be given as surveyed on the WGS 84 ellipsoidal model By projecting coordinates surveyed against the ellipsoid as if they were surveyed on a sphere angular relationships change slightly This is standard practice on the standard spherical Mercator projection but unlike Web Mercator the spherical Mercator is not normally used for maps of local areas such as street maps and so the accuracy of positions needed for plotting is typically less than the angular deviation caused by using spherical formulas The benefit the Web Mercator gains is that the spherical form is much simpler to calculate than the ellipsoidal form and so requires only a fraction of the computing resources 11 Identifiers editDue to slow adoption by the EPSG registry the Web Mercator is represented by several different names and spatial reference system identifiers SRIDs including EPSG 900913 EPSG 3785 and EPSG 3857 the latter being the official EPSG identifier since 2009 12 EPSG 900913 edit The projected coordinate reference system originally lacked an official spatial reference identifier SRID and the Geodesy subcommittee of the OGP s Geomatics committee also known as EPSG refused to provide it with one declaring We have reviewed the coordinate reference system used by Microsoft Google etc and believe that it is technically flawed We will not devalue the EPSG dataset by including such inappropriate geodesy and cartography 13 The unofficial code EPSG 900913 GOOGLE transliterated to numbers came to be used It was originally defined by Christopher Schmidt in his Technical Ramblings blog 14 and became codified in OpenLayers 2 15 which technically would make OpenLayers the SRID authority EPSG 3785 edit In 2008 EPSG provided the official identifier EPSG 3785 with the official name Popular Visualisation CRS Mercator but noted It is not an official geodetic system 6 This definition used a spherical rather than ellipsoidal model of the Earth EPSG 3857 edit Later that year EPSG provided an updated identifier EPSG 3857 with the official name WGS 84 Pseudo Mercator 6 The definition switched to using the WGS84 ellipsoid EPSG 4326 rather than the sphere Although the projection is closely associated with Google Microsoft is listed as the information source in EPSG s standards 12 Other identifiers edit Other identifiers that have been used include ESRI 102113 ESRI 102100 and OSGEO 41001 16 14 ESRI 102113 corresponds to EPSG 3785 while ESRI 102100 corresponds to EPSG 3857 17 WKT definition editThe projection covers the Earth from 180 to 180 longitude and 85 05 north and south Using well known text representation of coordinate reference systems WKT EPSG 3857 is defined as follows 12 PROJCRS WGS 84 Pseudo Mercator BASEGEOGCRS WGS 84 ENSEMBLE World Geodetic System 1984 ensemble MEMBER World Geodetic System 1984 Transit ID EPSG 1166 MEMBER World Geodetic System 1984 G730 ID EPSG 1152 MEMBER World Geodetic System 1984 G873 ID EPSG 1153 MEMBER World Geodetic System 1984 G1150 ID EPSG 1154 MEMBER World Geodetic System 1984 G1674 ID EPSG 1155 MEMBER World Geodetic System 1984 G1762 ID EPSG 1156 MEMBER World Geodetic System 1984 G2139 ID EPSG 1309 ELLIPSOID WGS 84 6378137 298 257223563 LENGTHUNIT metre 1 ID EPSG 9001 ID EPSG 7030 ENSEMBLEACCURACY 2 ID EPSG 6326 ID EPSG 4326 CONVERSION Popular Visualisation Pseudo Mercator METHOD Popular Visualisation Pseudo Mercator ID EPSG 1024 PARAMETER Latitude of natural origin 0 ANGLEUNIT degree 0 0174532925199433 ID EPSG 9102 ID EPSG 8801 PARAMETER Longitude of natural origin 0 ANGLEUNIT degree 0 0174532925199433 ID EPSG 9102 ID EPSG 8802 PARAMETER False easting 0 LENGTHUNIT metre 1 ID EPSG 9001 ID EPSG 8806 PARAMETER False northing 0 LENGTHUNIT metre 1 ID EPSG 9001 ID EPSG 8807 ID EPSG 3856 CS Cartesian 2 ID EPSG 4499 AXIS Easting X east AXIS Northing Y north LENGTHUNIT metre 1 ID EPSG 9001 ID EPSG 3857 References edit WGS 84 and the Web Mercator Projection NGA Office of Geomatics PDF National Geospatial Intelligence Agency 2014 05 16 Archived from the original PDF on 2014 10 09 Retrieved 2014 08 06 Google Maps amp Earth Help Forum Retrieved 29 August 2017 Our Map Data MapBox Retrieved June 20 2018 Mapbox supports the popular Web Mercator projection and currently does not support any other projections for display a b Battersby Sarah E Finn Michael P Usery E Lynn Yamamoto Kristina H 2014 Implications of Web Mercator and Its Use in Online Mapping PDF Cartographica 49 2 92 doi 10 3138 carto 49 2 2313 S2CID 6403891 Archived from the original on 15 February 2015 a b NGA U NGA Advisory Notice on Web Mercator UNCLASSIFIED National Geospatial Intelligence Agency Office of Geomatics 2014 02 18 Archived from the original on 2017 03 29 Retrieved 4 October 2014 a b c d The Google Maps Bing Maps Spherical Mercator Projection Alastair Aitchison 23 January 2011 Retrieved 4 October 2014 OpenStreetMap Slippy map tilenames openstreetmap org Retrieved 2018 11 14 See Inverse Gudermannian function gd 1 x ln tan x 2 p 4 displaystyle operatorname gd 1 x ln left tan left frac x 2 frac pi 4 right right nbsp Custom report www epsg registry org Archived from the original on 2012 06 22 Strebe Daniel daan 2019 A bevy of area preserving transforms for map projection designers Cartography and Geographic Information Science 46 3 260 276 Bibcode 2019CGISc 46 260S doi 10 1080 15230406 2018 1452632 S2CID 134864785 The Earth is Not Round Utah NAD83 and WebMercator Projections Utah GIS Portal Retrieved 2020 06 20 a b c EPSG registry WGS 84 Pseudo Mercator epsg org dotMorten Spherical Web Mercator EPSG code 3785 www sharpgis net a b Google Projection 900913 August 7 2007 Spherical Mercator OpenLayers docs openlayers org Archived from the original on 2021 04 18 Retrieved 2018 11 12 Klokan Technologies GmbH WGS 84 Pseudo Mercator Spherical Mercator Google Maps OpenStreetMap Bing ArcGIS ESRI EPSG 3857 epsg io 102100 vs 102113 is mixed up GeoNet The Esri Community October 3 2012 Retrieved from https en wikipedia org w index php title Web Mercator projection amp oldid 1199199004, wikipedia, wiki, book, books, library,

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