World Geodetic System

TheWorld Geodetic System(WGS) is a standard used incartography,geodesy,andsatellite navigationincludingGPS.The current version,WGS 84,defines anEarth-centered, Earth-fixed coordinate systemand ageodetic datum,and also describes the associatedEarth Gravitational Model(EGM) andWorld Magnetic Model(WMM). The standard is published and maintained by the United StatesNational Geospatial-Intelligence Agency.^[1]

History

Efforts to supplement the various nationalsurveyingsystems began in the 19th century withF.R. Helmert'sfamous bookMathematische und Physikalische Theorien der Physikalischen Geodäsie(Mathematical and Physical Theories of Physical Geodesy).AustriaandGermanyfounded theZentralbüro für die Internationale Erdmessung(Central Bureau of InternationalGeodesy), and a series of globalellipsoidsof the Earth were derived (e.g., Helmert 1906,Hayford1910 and 1924).

A unified geodetic system for the whole world became essential in the 1950s for several reasons:

Internationalspace scienceand the beginning ofastronautics.
The lack of inter-continental geodetic information.
The inability of the largegeodetic systems,such as European Datum (ED50),North American Datum(NAD), andTokyo Datum(TD), to provide a worldwide geo-data basis
Need for global maps fornavigation,aviation, andgeography.
WesternCold Warpreparedness necessitated a standardised,NATO-wide geospatial reference system, in accordance with the NATOStandardisation Agreement

WGS 60

In the late 1950s, theUnited States Department of Defense,together withscientistsof other institutions and countries, began to develop the needed world system to which geodetic data could be referred and compatibility established between the coordinates of widely separated sites of interest. Efforts of the U.S. Army, Navy and Air Force were combined leading to the DoD World Geodetic System 1960 (WGS 60). The termdatumas used here refers to a smooth surface somewhat arbitrarily defined as zero elevation, consistent with a set of surveyor's measures of distances between various stations, and differences in elevation, all reduced to a grid oflatitudes,longitudes,andelevations.Heritage surveying methods found elevation differences from a local horizontal determined by thespirit level,plumb line,or an equivalent device that depends on the local gravity field (seephysical geodesy). As a result, the elevations in the data are referenced to thegeoid,a surface that is not readily found usingsatellite geodesy.The latter observational method is more suitable for global mapping. Therefore, a motivation, and a substantial problem in the WGS and similar work is to patch together data that were not only made separately, for different regions, but to re-reference the elevations to an ellipsoid model rather than to thegeoid.

In accomplishing WGS 60, a combination of available surfacegravitydata,astro-geodeticdata and results from HIRAN^[2]and CanadianSHORANsurveys were used to define a best-fittingellipsoidand an earth-centered orientation for each initially selected datum. (Every datum is relatively oriented with respect to different portions of the geoid by the astro-geodetic methods already described.) The sole contribution ofsatellitedata to the development of WGS 60 was a value for theellipsoidflattening which was obtained from the nodal motion of a satellite.

Prior to WGS 60, the U.S. Army andU.S. Air Forcehad each developed a world system by using different approaches to the gravimetric datum orientation method. To determine their gravimetric orientation parameters, the Air Force used the mean of the differences between the gravimetric and astro-geodeticdeflectionsand geoid heights (undulations) at specifically selected stations in the areas of the major datums. The Army performed an adjustment to minimize the difference between astro-geodetic andgravimetric geoids.By matching the relative astro-geodetic geoids of the selected datums with an earth-centered gravimetric geoid, the selected datums were reduced to an earth-centered orientation. Since the Army and Air Force systems agreed remarkably well for the NAD, ED and TD areas, they were consolidated and became WGS 60.

WGS 66

Improvements to the global system included the Astrogeoid ofIrene Fischerand the astronautic Mercury datum. In January 1966, a World Geodetic System Committee composed of representatives from the United States Army, Navy and Air Force was charged with developing an improved WGS, needed to satisfymapping,charting and geodetic requirements. Additional surfacegravityobservations, results from the extension oftriangulationandtrilaterationnetworks, and large amounts ofDopplerandopticalsatellite data had become available since the development of WGS 60. Using the additional data and improved techniques, WGS 66 was produced which served DoD needs for about five years after its implementation in 1967. The defining parameters of the WGS 66 Ellipsoid were the flattening (1⁄298.25determined from satellite data) and the semimajor axis (6378145mdetermined from a combination of Doppler satellite and astro-geodetic data). A worldwide 5° × 5° mean free airgravity anomalyfield provided the basic data for producing the WGS 66 gravimetric geoid. Also, a geoid referenced to the WGS 66 Ellipsoid was derived from available astrogeodetic data to provide a detailed representation of limited land areas.

WGS 72

After an extensive effort over a period of approximately three years, the Department of Defense World Geodetic System 1972 was completed. Selected satellite, surface gravity and astrogeodetic data available through 1972 from both DoD and non-DoD sources were used in a Unified WGS Solution (a large scaleleast squaresadjustment). The results of the adjustment consisted of corrections to initial station coordinates and coefficients of the gravitational field.^[3]

The largest collection of data ever used for WGS purposes was assembled, processed and applied in the development of WGS 72. Both optical and electronic satellite data were used. The electronic satellite data consisted, in part, of Doppler data provided by the U.S. Navy and cooperating non-DoD satellite tracking stations established in support of the Navy's Navigational Satellite System (NNSS). Doppler data was also available from the numerous sites established by GEOCEIVERS during 1971 and 1972. Doppler data was the primary data source for WGS 72 (see image). Additional electronic satellite data was provided by the SECOR (Sequential Collation of Range) Equatorial Network completed by the U.S. Army in 1970. Optical satellite data from the Worldwide Geometric Satellite Triangulation Program was provided by the BC-4 camera system (see image). Data from theSmithsonian Astrophysical Observatorywas also used which included camera (Baker–Nunn) and some laser ranging.^[3]

The surface gravity field used in the Unified WGS Solution consisted of a set of 410 10° × 10° equal area mean free air gravity anomalies determined solely from terrestrial data. This gravity field includes mean anomaly values compiled directly from observed gravity data wherever the latter was available in sufficient quantity. The value for areas of sparse or no observational data were developed from geophysically compatible gravity approximations using gravity-geophysical correlation techniques. Approximately 45 percent of the 410 mean free air gravity anomaly values were determined directly from observed gravity data.^[3]

The astrogeodetic data in its basic form consists of deflection of the vertical components referred to the various national geodetic datums. These deflection values were integrated into astrogeodetic geoid charts referred to these national datums. The geoid heights contributed to the Unified WGS Solution by providing additional and more detailed data for land areas. Conventional ground survey data was included in the solution to enforce a consistent adjustment of the coordinates of neighboring observation sites of the BC-4, SECOR, Doppler and Baker–Nunn systems. Also, eightgeodimeterlong line precise traverses were included for the purpose of controlling the scale of the solution.^[3]

The Unified WGS Solution, as stated above, was a solution for geodetic positions and associated parameters of the gravitational field based on an optimum combination of available data. The WGS 72 ellipsoid parameters, datum shifts and other associated constants were derived separately. For the unified solution, a normal equation matrix was formed based on each of the mentioned data sets. Then, the individual normal equation matrices were combined and the resultant matrix solved to obtain the positions and the parameters.^[3]

The value for the semimajor axis ( $a$ ) of the WGS 72 Ellipsoid is6378135m.The adoption of an $a$ -value 10 meters smaller than that for the WGS 66 Ellipsoid was based on several calculations and indicators including a combination of satellite and surface gravity data for position and gravitational field determinations. Sets of satellite derived station coordinates and gravimetric deflection of the vertical and geoid height data were used to determine local-to-geocentric datum shifts, datum rotation parameters, a datum scale parameter and a value for the semimajor axis of the WGS Ellipsoid. Eight solutions were made with the various sets of input data, both from an investigative point of view and also because of the limited number of unknowns which could be solved for in any individual solution due to computer limitations. Selected Doppler satellite tracking and astro-geodetic datum orientation stations were included in the various solutions. Based on these results and other related studies accomplished by the committee, an $a$ -value of6378135mand a flattening of 1/298.26 were adopted.^[3]

In the development of local-to WGS 72 datum shifts, results from different geodetic disciplines were investigated, analyzed and compared. Those shifts adopted were based primarily on a large number of Doppler TRANET and GEOCEIVER station coordinates which were available worldwide. These coordinates had been determined using the Doppler point positioning method.^[3]

WGS 84

In the early 1980s, the need for a new world geodetic system was generally recognized by the geodetic community as well as within the US Department of Defense. WGS 72 no longer provided sufficient data, information, geographic coverage, or product accuracy for all then-current and anticipated applications. The means for producing a new WGS were available in the form of improved data, increased data coverage, new data types and improved techniques. Observations from Doppler, satellite laser ranging andvery-long-baseline interferometry(VLBI) constituted significant new information. An outstanding new source of data had become available from satellite radar altimetry. Also available was an advancedleast squaresmethod calledcollocationthat allowed for a consistent combination solution from different types of measurements all relative to the Earth's gravity field, measurements such as the geoid, gravity anomalies, deflections, and dynamic Doppler.

The new world geodetic system was called WGS 84. It is the reference system used by theGlobal Positioning System.It is geocentric and globally consistent within1m.Current geodetic realizations of the geocentric reference system familyInternational Terrestrial Reference System(ITRS) maintained by theIERSare geocentric, and internally consistent, at the few-cm level, while still being metre-level consistent with WGS 84.

The WGS 84reference ellipsoidwas based onGRS 80,but it contains a very slight variation in the inverse flattening, as it was derived independently and the result was rounded to a different number of significant digits.^[4]This resulted in a tiny difference of0.105 mmin the semi-minor axis.^[5] The following table compares the primary ellipsoid parameters.

Ellipsoid reference	Semi-major axis $a$	Semi-minor axis $b$	Inverseflattening1⁄ $f$
GRS 80	6378137.0 m	≈6356752.314140m	298.257222100882711...
WGS 84^[6]	6378137.0 m	≈6356752.314245m	298.257223563

Definition

The coordinate origin of WGS 84 is meant to be located at the Earth'scenter of mass;the uncertainty is believed to be less than2 cm.^[7]

The WGS 84 meridian of zero longitude is theIERS Reference Meridian,^[8]5.3arc secondsor 102 metres (335 ft) east of theGreenwich meridianat the latitude of theRoyal Observatory.^[9]^[10](This is related to the fact that the local gravity field at Greenwichdoes not point exactlythrough the Earth's center of mass, but rather "misses west" of the center of mass by about 102 meters.) The longitude positions on WGS 84 agree with those on the olderNorth American Datum 1927at roughly85° longitude west,in the east-central United States.

The WGS 84 datum surface is anoblate spheroidwith equatorial radius $a$ =6378137mat theequatorandflattening $f$ =1⁄298.257223563.The refined value of the WGS 84gravitational constant(mass of Earth's atmosphere included) is $GM$ =3.986004418×10¹⁴m³/s².The angular velocity of the Earth is defined to be $ω$ =72.92115×10⁻⁶rad/s.^[11]

This leads to several computed parameters such as the polar semi-minor axis $b$ which equals $a \times (1 - f)$ =6356752.3142 m,and the first eccentricity squared, $e 2$ =6.69437999014×10⁻³.^[11]

Updates and new standards

The original standardization document for WGS 84 was Technical Report 8350.2, published in September 1987 by the Defense Mapping Agency (which later became the National Imagery and Mapping Agency). New editions were published in September 1991 and July 1997; the latter edition was amended twice, in January 2000 and June 2004.^[12]The standardization document was revised again and published in July 2014 by theNational Geospatial-Intelligence Agencyas NGA.STND.0036.^[13]These updates provide refined descriptions of the Earth and realizations of the system for higher precision.

The original WGS84 model had an absolute accuracy of 1–2 meters. WGS84 (G730) first incorporated GPS observations, taking the accuracy down to 10 cm/component rms.^[14]All following revisions including WGS84 (G873) and WGS84 (G1150) also used GPS.^[15]

WGS 84 (G1762) is the sixth update to the WGS reference frame.^[14]

WGS 84 has most recently been updated to use the reference frameG2296,which was released on 7 January 2024 as an update to G2139, now aligned to both the ITRF2020, the most recent ITRF realization, and the IGS20, the frame used by the International GNSS Service (IGS).^[16]G2139 was aligned with the IGb14 realization of theInternational Terrestrial Reference Frame(ITRF) 2014 and uses the newIGSAntex standard.^[17]

Updates to the originalgeoidfor WGS 84 are now published as a separateEarth Gravitational Model(EGM), with improved resolution and accuracy. Likewise, theWorld Magnetic Model(WMM) is updated separately. The current version of WGS 84 uses EGM2008 and WMM2020.^[18]^[19]

Solution for Earth orientation parameters consistent with ITRF2014 is also needed (IERS EOP 14C04).^[20]

Identifiers

Components of WGS 84 are identified by codes in theEPSG Geodetic Parameter Dataset:^[21]

EPSG:4326 – 2Dcoordinate reference system(CRS)
EPSG:4979 – 3D CRS
EPSG:4978 –geocentric3D CRS
EPSG:7030 –reference ellipsoid
EPSG:6326 –horizontal datum

References

^"World Geodetic System 1984 (WGS 84)".Office of Geomatics, National Geospatial-Intelligence Agency.Retrieved21 December2022.
^"NOAA History - Stories and Tales of the Coast & Geodetic Survey - Personal Tales/Earth Measurer/Aslakson Bio".History.noaa.gov.Retrieved24 May2017.
^^a ^b ^c ^d ^e ^f ^g"THE WORLD GEODETIC SYSTEM".Geodesy for the Layman.United States Air Force. 1984.
^Hooijberg, Maarten (18 December 2007).Geometrical Geodesy: Using Information and Computer Technology.Germany: Springer Berlin Heidelberg. p. 20.ISBN 9783540682257.
^"USER DOCUMENTATION Programs: INVERSE, FORWARD, INVERS3D, FORWRD3D Versions 2.0".geodesy.noaa.gov.Retrieved23 May2022.
^"WGS 84: Ellipsoid Details".EPSG Geodetic Parameter Dataset.Retrieved21 December2022.
^"The EGM96 Geoid Undulation with Respect to the WGS84 Ellipsoid".NASA.
^European Organisation for the Safety of Air NavigationandIfEN:WGS 84 Implementation Manual, p. 13. 1998
^"Greenwich Meridan, Tracing its History".Gpsinformation.net.Retrieved24 May2017.
^Malys, Stephen; Seago, John H.; Palvis, Nikolaos K.; Seidelmann, P. Kenneth; Kaplan, George H. (1 August 2015)."Why the Greenwich meridian moved".Journal of Geodesy.89(12): 1263–1272.Bibcode:2015JGeod..89.1263M.doi:10.1007/s00190-015-0844-y.
^^a ^b"Department of Defense World Geodetic System 1984"(PDF)(2nd ed.). Defense Mapping Agency. 1 September 1991.Archived(PDF)from the original on 3 August 2021.
^"DMA TR 8350.2 WGS".IHS Markit Standards Store.Retrieved26 December2022.
^"Data collection of WGS 84 information — or is it?".GPS World.2 November 2016.
^^a ^bDepartment of Defense World Geodetic System 1984 - NGA.STND.0036_1.0.0_WGS84(Report).
^"Modern Geocentric Datum | GEOG 862: GPS and GNSS for Geospatial Professionals".www.e-education.psu.edu.Retrieved31 December2023.
^"Global Navigation Satellite System (GNSS)".Office of Geomantics.January 2024.Retrieved20 January2024.
^Australian Government - Geoscience Australia (20 March 2017)."What are the limitations of using World Geodetic System 1984 in Australia?".www.ga.gov.au.Retrieved16 May2022.
^"NGA Geomatics - WGS 84".earth-info.nga.mil.Retrieved19 March2019.
^"World Magnetic Model".NCEI.Retrieved23 January2020.
^"Evolution of the World Geodetic System 1984 (WGS 84) Terrestrial Reference Frame"(PDF).Retrieved15 January2023.
^"World Geodetic System 1984 ensemble".EPSG Geodetic Parameter Dataset.Retrieved21 December2022.

This article incorporatespublic domain materialfrom websites or documents of theNational Geodetic Survey.

External links

NGA Standardization DocumentDepartment of Defense World Geodetic System 1984, Its Definition and Relationships With Local Geodetic Systems(2014-07-08)
DMA Technical Report 8350.2Department of Defense World Geodetic System 1984, Its Definition and Relationships With Local Geodetic Systems(1991-09-01). This edition documents the original Earth Gravitational Model.
NGA webpage for WGS 84
Geodesy for the Layman,Chapter VIII, "The World Geodetic System"
Spatial reference for EPSG:4326
ANTEX (.atx) files that define IGS20

[homepage-1] "World Geodetic System 1984 (WGS 84)".Office of Geomatics, National Geospatial-Intelligence Agency.Retrieved21 December2022.

[2] "NOAA History - Stories and Tales of the Coast & Geodetic Survey - Personal Tales/Earth Measurer/Aslakson Bio".History.noaa.gov.Retrieved24 May2017.

[:0-3] ^^a ^b ^c ^d ^e ^f ^g"THE WORLD GEODETIC SYSTEM".Geodesy for the Layman.United States Air Force. 1984.

[4] Hooijberg, Maarten (18 December 2007).Geometrical Geodesy: Using Information and Computer Technology.Germany: Springer Berlin Heidelberg. p. 20.ISBN 9783540682257.

[5] "USER DOCUMENTATION Programs: INVERSE, FORWARD, INVERS3D, FORWRD3D Versions 2.0".geodesy.noaa.gov.Retrieved23 May2022.

[6] "WGS 84: Ellipsoid Details".EPSG Geodetic Parameter Dataset.Retrieved21 December2022.

[7] "The EGM96 Geoid Undulation with Respect to the WGS84 Ellipsoid".NASA.

[Manual-8] European Organisation for the Safety of Air NavigationandIfEN:WGS 84 Implementation Manual, p. 13. 1998

[9] "Greenwich Meridan, Tracing its History".Gpsinformation.net.Retrieved24 May2017.

[Malys_et_al._2015-10] Malys, Stephen; Seago, John H.; Palvis, Nikolaos K.; Seidelmann, P. Kenneth; Kaplan, George H. (1 August 2015)."Why the Greenwich meridian moved".Journal of Geodesy.89(12): 1263–1272.Bibcode:2015JGeod..89.1263M.doi:10.1007/s00190-015-0844-y.

[Second_Edition-11] "Department of Defense World Geodetic System 1984"(PDF)(2nd ed.). Defense Mapping Agency. 1 September 1991.Archived(PDF)from the original on 3 August 2021.

[12] "DMA TR 8350.2 WGS".IHS Markit Standards Store.Retrieved26 December2022.

[13] "Data collection of WGS 84 information — or is it?".GPS World.2 November 2016.

[Standard_0036-14] Department of Defense World Geodetic System 1984 - NGA.STND.0036_1.0.0_WGS84(Report).

[15] "Modern Geocentric Datum | GEOG 862: GPS and GNSS for Geospatial Professionals".www.e-education.psu.edu.Retrieved31 December2023.

[16] "Global Navigation Satellite System (GNSS)".Office of Geomantics.January 2024.Retrieved20 January2024.

[17] Australian Government - Geoscience Australia (20 March 2017)."What are the limitations of using World Geodetic System 1984 in Australia?".www.ga.gov.au.Retrieved16 May2022.

[18] "NGA Geomatics - WGS 84".earth-info.nga.mil.Retrieved19 March2019.

[19] "World Magnetic Model".NCEI.Retrieved23 January2020.

[20] "Evolution of the World Geodetic System 1984 (WGS 84) Terrestrial Reference Frame"(PDF).Retrieved15 January2023.

[21] "World Geodetic System 1984 ensemble".EPSG Geodetic Parameter Dataset.Retrieved21 December2022.

[1]

[2]

[3]

[4]

[5]

[6]

[7]

[8]

[9]

[10]

[11]

[12]

[13]

[14]

[15]

[16]

[17]

[18]

[19]

[20]

[21]

v t e Physical oceanography
Waves	Airy wave theory Ballantine scale Benjamin–Feir instability Boussinesq approximation Breaking wave Clapotis Cnoidal wave Cross sea Dispersion Edge wave Equatorial waves Fetch Gravity wave Green's law Infragravity wave Internal wave Iribarren number Kelvin wave Kinematic wave Longshore drift Luke's variational principle Mild-slope equation Radiation stress Rogue wave Rossby wave Rossby-gravity waves Sea state Seiche Significant wave height Soliton Stokes boundary layer Stokes drift Stokes wave Swell Trochoidal wave Tsunami megatsunami Undertow Ursell number Wave action Wave base Wave height Wave nonlinearity Wave power Wave radar Wave setup Wave shoaling Wave turbulence Wave–current interaction Waves and shallow water one-dimensional Saint-Venant equations shallow water equations Wind setup Wind wave model
Circulation	Atmospheric circulation Baroclinity Boundary current Coriolis force Coriolis–Stokes force Craik–Leibovich vortex force Downwelling Eddy Ekman layer Ekman spiral Ekman transport El Niño–Southern Oscillation General circulation model Geochemical Ocean Sections Study Geostrophic current Global Ocean Data Analysis Project Gulf Stream Halothermal circulation Humboldt Current Hydrothermal circulation Langmuir circulation Longshore drift Loop Current Modular Ocean Model Ocean current Ocean dynamics Ocean dynamical thermostat Ocean gyre Overflow Princeton ocean model Rip current Subsurface currents Sverdrup balance Thermohaline circulation shutdown Upwelling Wind generated current Whirlpool World Ocean Circulation Experiment
Tides	Amphidromic point Earth tide Head of tide Internal tide Lunitidal interval Perigean spring tide Rip tide Rule of twelfths Slack tide Tidal bore Tidal force Tidal power Tidal race Tidal range Tidal resonance Tide gauge Tideline Theory of tides
Landforms	Abyssal fan Abyssal plain Atoll Bathymetric chart Coastal geography Cold seep Continental margin Continental rise Continental shelf Contourite Guyot Hydrography Knoll Oceanic basin Oceanic plateau Oceanic trench Passive margin Seabed Seamount Submarine canyon Submarine volcano
Plate tectonics	Convergent boundary Divergent boundary Fracture zone Hydrothermal vent Marine geology Mid-ocean ridge Mohorovičić discontinuity Vine–Matthews–Morley hypothesis Oceanic crust Outer trench swell Ridge push Seafloor spreading Slab pull Slab suction Slab window Subduction Transform fault Volcanic arc
Ocean zones	Benthic Deep ocean water Deep sea Littoral Mesopelagic Oceanic Pelagic Photic Surf Swash
Sea level	Deep-ocean Assessment and Reporting of Tsunamis Future sea level Global Sea Level Observing System North West Shelf Operational Oceanographic System Sea-level curve Sea level rise Sea level drop World Geodetic System
Acoustics	Deep scattering layer Hydroacoustics Ocean acoustic tomography Sofar bomb SOFAR channel Underwater acoustics
Satellites	Jason-1 Jason-2 (Ocean Surface Topography Mission) Jason-3
Related	Acidification Argo Benthic lander Color of water DSVAlvin Marginal sea Marine energy Marine pollution Mooring National Oceanographic Data Center Ocean Explorations Observations Reanalysis Ocean surface topography Ocean temperature Ocean thermal energy conversion Oceanography Outline of oceanography Pelagic sediment Sea surface microlayer Sea surface temperature Seawater Science On a Sphere Stratification Thermocline Underwater glider Water column World Ocean Atlas
Oceans portal Category Commons