Graticule

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Geographic coordinate system - Wikipedia, the free encyclopedia
This latitude/longitude "webbing" is known as the conjugate graticule. ... The graticule perspective is based on this designation: As the longitudinal ...
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Graticule - Geo Hashing
A graticule is a network of ... shape and size of a graticule as measured over the ground ... A graticule near the equator (latitude 0) is almost exactly ...
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Graticule
Graticule is a geocoding API for looking up address coordinates and performing ... Graticule supports several services with international support. ...
graticule.rubyforge.org

graticule - Definition from the Merriam-Webster Online Dictionary
Definition of graticule from the Merriam-Webster Online Dictionary with audio pronunciations, thesaurus, Word of the Day, and word games.
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View - Graticule
Graticule lines will be curved in geographic projections. ... The default graticule color is set by an option in Tools - Options. ...
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Definition of graticule - WordReference.com Dictionary
graticule Definition from dictionary ... No titles with the word(s) 'graticule'.For any questions about this word or definition: ...
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graticule - Definitions from Dictionary.com
Definitions of graticule at Dictionary.com. ... Graticule ... Perform a new search, or try your search for "graticule" at: ...
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Creating a Graticule Page - Geo Hashing
Someone might have named it after another city in the graticule or with a different spelling. ... If your graticule is not listed on the All Graticules page, ...
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graticule-0.2.8 Documentation
lib/graticule/distance/haversine.rb. lib/graticule/distance/spherical.rb ... lib/graticule/geocoder/multi.rb. lib/graticule/geocoder/multimap.rb ...
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showing lines of latitude (horizontally) and longitude (vertically), Eckert VI projection; large version (pdf, 1.8MB)

A geographic coordinate system enables every location on the earth to be specified by the three coordinates of a Spherical coordinates#Spherical coordinates aligned with the spin axis of the Earth.

First and second dimensions: latitude and longitude

Borrowing from theories of the ancient Babylonians, later expanded by the famous History of Ancient Greece thinker and geographer Ptolemy, a full circle is divided into 360 degree (angle) (360°).

By combining these two angles, the horizontal position of any location on Earth can be specified.

For example, Baltimore, Maryland (in the United States) has a latitude of 39.3° North, and a longitude of 76.6° West (). So, a vector drawn from the center of the earth to a point 39.3° north of the equator and 76.6° west of Greenwich will pass through Baltimore.

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.

Traditionally, degrees have been divided into Minute of arc (1/60th of a degree, designated by ′ or "m") and Arcsecond (1/60th of a minute, designated by ″ or "s"). There are several formats for degrees, all of them appearing in the same Lat-Long order:

To convert from DM or DMS to DD, decimal degrees = whole number of degrees, plus minutes divided by 60, plus seconds divided by 3600. DMS is the most common format, and is standard on all charts and maps, as well as global positioning systems and geographic information systems.

On a spherical surface at sea level, one latitudinal second measures 30.82 metres and one latitudinal minute 1849 metres. Circle of latitude are each 110.9 kilometres away. The circles of longitude, the meridian (geography), meet at the geographical poles, with the west-east width of a second being dependent on the latitude. On a spherical surface at sea level, one longitudinal second measures 30.92 metres on the equator, 26.76 metres on the 30th parallel, 19.22 metres in Greenwich (51° 28' 38" N) and 15.42 metres on the 60th parallel.

The width of one longitudinal degree on latitude \scriptstyle{\phi}\,\! can be calculated by this formula (to get the width per minute and second, divide by 60 and 3600, respectively):

::::\frac{\pi}{180^{\circ-->\cos(\phi)M_r,\,\! where Earth radius#Meridional Earth radius \scriptstyle{M_r}\,\! approximately equals 6,367,449 m. Due to the average radius value used, this formula is of course not precise due to Figure of the Earth. You can get real width of a longitudinal degree on latitude \scriptstyle{\phi}\,\! by:

:\frac{\pi}{180^{\circ-->\cos(\phi)\sqrt{\frac{a^4\cos(\phi)^2+b^4\sin(\phi)^2}{(a\cos(\phi))^2+(b\sin(\phi))^2-->,\,\! where Earth's equatorial and polar radii, \scriptstyle{a,b}\,\! equal 6,378,137 m, 6,356,752.3 m, respectively.

The equator is the fundamental plane (spherical coordinates) of all geographic coordinate systems. All spherical coordinate systems define such a fundamental plane.

Latitude and longitude values can be based on several different geodetic systems or datums, the most common being the World Geodetic System used by all GPS equipment. In other words, the same point on the earth’s surface can be described by different latitude and longitude values depending on the reference datum.

In popular GIS software, data projected in latitude/longitude is often specified via a 'Geographic Coordinate System'. For example, data in latitude/longitude with the datum as the North American Datum of 1983 is denoted by 'GCS_North_American_1983'.

Third dimension: altitude, height, depth To completely specify a location on, in, or above the earth, one has to also specify the elevation, defined as the vertical position of the location relative to the centre of the reference system or some definition of the earth's surface. This is expressed in terms of the vertical distance to the earth below, but, because of the ambiguity of "surface" and "vertical", is more commonly expressed relative to a more precisely defined datum such as mean sea level (more precisely named geoid, a surface of constant gravity potential). The distance to the earth's center can be used both for very deep positions and for positions in space.

Other terms used with respect to the distance of a point from the earth's surface or some other datum are altitude, height, and depth.

Geostationary coordinates Geostationary satellites (e.g., television satellites ) are over the equator. So, their position related to Earth is expressed in longitude degrees. Their latitude does not change, and is always zero over the equator.

See also

References

External links







 
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