Information about Earth Radius
Because the Earth, like all planets, is not a perfect sphere, the radius of Earth can vary at different places on the surface. The radius of the Earth at a point on the surface is the distance from the center of the Earth to the mean sea level at that point. This value varies from about 6,356.750 km — 6,378.135 km (≈3,949.901 — 3,963.189 mi), values between the polar radius and the equatorial radius (with few exceptions). The radius of the Earth can also refer to other fixed radii as well as to various mean radii, outlined below. For all planets the sources of the distortion from spherical are rotation, variation of mass density within the planet, and tidal forces. [1]
is larger than the polar radius 
by approximately 
where the oblateness constant 
is
is the angular frequency, 
is the gravitational constant, and 
is the mass of the planet.
[2]
For the Earth 
, which is close to the measured inverse flattening
.
Additionally, the bulge at the equator shows slow variations. The bulge had been declining, but since 1998 the bulge has increased, possibly due to redistribution of ocean mass via currents.
[3]
The variation in density and crustal thickness causes gravity to vary on the surface, so that the mean sea level will differ from the ellipsoid. This difference is the geoid height, positive above or outside the ellipsoid, negative below or inside. The geoid height variation is under 110 m on Earth. The geoid height can have abrupt changes due to earthquakes (such as the Sumatra-Andaman earthquake) or reduction in ice masses (such as Greenland).
[4]
The tides from the gravity of the Moon and Sun cause the surface of the Earth to rise and fall by tenths of meters at a point over a nearly 12 hr period.
Therefore, the values defined below are based on a "general purpose" model, refined as globally precisely as possible within 5 m of reference ellipsoid height, and to within 100 m of mean sea level (neglecting geoid height).
Additionally, the radius can be estimated from the curvature of the Earth at a point. Like a torus the curvature at a point will be largest (tightest) in one direction (North-South on Earth) and smallest (flattest) perpendicularly (East-West). The corresponding radius of curvature depends on location and direction of measurement from that point. A consequence is that a distance to the true horizon at the equator is slightly shorter in the north/south direction than in the east-west direction.
In summary, Local variations in terrain prevent the definition of a single absolutely "precise" radius. One can only find mathematically precise values based on a given model. Since the estimate by Eratosthenes, a plethora of models have been created, some accommodating or based on regional topography. The advancements in measuring technology, now including satellites, mean that different reference ellipsoid models have made their way into general usage over the years, providing slightly different values.Equatorial radius:
The Earth's equatorial radius, or semi-major axis, is the distance from its center to the equator and equals 6,378.135 km (≈3,963.189 mi; ≈3,443.917 nmi). At , the geoid height rises to 63.42 m above the reference ellipsoid (), giving a total radius of 6,378.200 km.
The equatorial radius is often used to compare Earth with other planets.
Polar radius:
The Earth's polar radius, or semi-minor axis, is the distance from its center to the North and South Poles, and equals 6,356.750 km (≈3,949.901 mi; ≈3,432.370 nmi). The geoid height (WGS-84) at the North Pole is 13.6 m above the reference ellipsoid, and at the South Pole 29.5 m below the reference, giving the more exact 6,356.766 km and 6,356.723 km, respectively.
, is:
Eratosthenes used two points, one exactly north of the other. The points are separated by distance
, and the vertical directions at the two points are known to differ by angle of 
, in radians.
A formula based on Eratosthenes method is
Introduction
Rotation of a planet causes it to approximate an oblate ellipsoid/spheroid with a bulge at the equator and flattening at the North and South Poles, so that the equatorial radius is larger than the polar radius by approximately where the oblateness constant is
- ::
is the angular frequency, is the gravitational constant, and is the mass of the planet.
[2]
For the Earth , which is close to the measured inverse flattening
.
Additionally, the bulge at the equator shows slow variations. The bulge had been declining, but since 1998 the bulge has increased, possibly due to redistribution of ocean mass via currents.
[3]
)
The variation in density and crustal thickness causes gravity to vary on the surface, so that the mean sea level will differ from the ellipsoid. This difference is the geoid height, positive above or outside the ellipsoid, negative below or inside. The geoid height variation is under 110 m on Earth. The geoid height can have abrupt changes due to earthquakes (such as the Sumatra-Andaman earthquake) or reduction in ice masses (such as Greenland).
[4]
The tides from the gravity of the Moon and Sun cause the surface of the Earth to rise and fall by tenths of meters at a point over a nearly 12 hr period.
Therefore, the values defined below are based on a "general purpose" model, refined as globally precisely as possible within 5 m of reference ellipsoid height, and to within 100 m of mean sea level (neglecting geoid height).
Additionally, the radius can be estimated from the curvature of the Earth at a point. Like a torus the curvature at a point will be largest (tightest) in one direction (North-South on Earth) and smallest (flattest) perpendicularly (East-West). The corresponding radius of curvature depends on location and direction of measurement from that point. A consequence is that a distance to the true horizon at the equator is slightly shorter in the north/south direction than in the east-west direction.
In summary, Local variations in terrain prevent the definition of a single absolutely "precise" radius. One can only find mathematically precise values based on a given model. Since the estimate by Eratosthenes, a plethora of models have been created, some accommodating or based on regional topography. The advancements in measuring technology, now including satellites, mean that different reference ellipsoid models have made their way into general usage over the years, providing slightly different values.
- (''Note: Earth radius is sometimes used as a unit of distance, especially in astronomy and geology. It is usually denoted by
.)
Fixed radii
The following radii are fixed, and do not include a variable location dependence.Equatorial radius:
The Earth's equatorial radius, or semi-major axis, is the distance from its center to the equator and equals 6,378.135 km (≈3,963.189 mi; ≈3,443.917 nmi). At , the geoid height rises to 63.42 m above the reference ellipsoid (), giving a total radius of 6,378.200 km.
The equatorial radius is often used to compare Earth with other planets.
Polar radius:
The Earth's polar radius, or semi-minor axis, is the distance from its center to the North and South Poles, and equals 6,356.750 km (≈3,949.901 mi; ≈3,432.370 nmi). The geoid height (WGS-84) at the North Pole is 13.6 m above the reference ellipsoid, and at the South Pole 29.5 m below the reference, giving the more exact 6,356.766 km and 6,356.723 km, respectively.
Radii with location dependence
Radius at a given geodetic latitude
The Earth's radius at geodetic latitude,, is:
Radius of curvature
These are based on a oblate ellipsoid.Eratosthenes used two points, one exactly north of the other. The points are separated by distance
, and the vertical directions at the two points are known to differ by angle of , in radians.
A formula based on Eratosthenes method is
- ::
Meridional
- In particular the Earth's radius of curvature in the (north-south) meridian at is:
- ::
Normal
- If one point had appeared due east of the other, one finds the approximate curvature in east-west direction. [5]
- This radius of curvature in the prime vertical, which is perpendicular, or normal, to M at geodetic latitude is: [6]
- ::
Radius at geodetic latitude in black.
The Earth's mean radius of curvature (averaging over all directions) at latitude is:
- ::
The Earth's radius of curvature along a course at geodetic bearing (measured clockwise from north)
, at is:
[7]
- ::
The Earth's equatorial radius of curvature in the meridian is:- ::
= 6335.437 km
The Earth's polar radius of curvature is:- ::
= 6399.592 km
Mean radii
Quadratic mean radius:
The ellipsoidal quadratic mean radius provides the best approximation of Earth's average transverse meridional radius and radius of curvature:
- ::
It is this radius that would be used to approximate the ellipsoid's average great ellipse (i.e., this is the equivalent spherical "great-circle" radius of the ellipsoid). For Earth, equals 6,372.795477598 km (≈3,959.871 mi; ≈3,441.034 nmi).
Authalic mean radius:
Earth's authalic ("equal area") mean radius is 6,371.005076123 km (≈3,958.759 mi; ≈3,440.067 nmi). This number is derived by square rooting the average (latitudinally cosine corrected) geometric mean of the meridional and transverse equatorial, or "normal" (i.e., perpendicular), arcradii of all surface points on the spheroid, which can be reduced to a closed-form solution:
- ::
is the authalic surface area of Earth. This would be the radius of a hypothetical perfect sphere which has the same, geometric mean oriented surface area as the spheroid.
Volumetric radius:
Another, less utilized, sphericalization is that of the volumetric radius, which is the radius of a sphere of equal volume:
- ::
Meridional Earth radius
Another radius mean is the meridional mean, which equals the radius used in finding the perimeter of an ellipse. It can also be found by just finding the average value of M:- ::
For Earth, this works out to 6367.446988834 km (≈3,956.548 mi; ≈3,438.146 nmi).See also
Notes and references
1. ^ The center of the Earth is somewhat model dependent. Exceptions to the cited range will occur near the South Pole and along the equator. Also, differences due to variation of mass density within the planet and tidal forces require data for the entire surface of the Earth and are not included here. For detail see Figure of the Earth, Geoid, and Earth tide.
2. ^ This follows from the International Astronomical Union definition rule (2): a planet assumes a shape due to hydrostatic equilibrium where gravity and centrifugal forces are nearly balanced. IAU 2006 General Assembly: Result of the IAU Resolution votes
3. ^ Satellites Reveal A Mystery Of Large Change In Earth's Gravity Field, Aug. 1, 2002, Goddard Space Flight Center.
4. ^ NASA's Grace Finds Greenland Melting Faster, 'Sees' Sumatra Quake, December 20, 2005, Goddard Space Flight Center.
5. ^ East-west directions can be misleading. Point B which appears due East from A will be closer to the equator than A. Thus the curvature found this way is smaller than the curvature of a circle of constant latitude, except at the equator. West can exchanged for east in this discussion.
6. ^ N is defined as the radius of curvature in the plane which is normal to both the surface of the ellipsoid at, and the meridian passing through, the specific point of interest.
7. ^ A related application of M and N: if two nearby points have the difference in latitude of
and longitude of 
(in radians) with mean latitude , then the distance D between them is - ::
and 
, respectively. Thus 
and 
be estimated from D, M, and N.
EARTH was a short-lived Japanese vocal trio which released 6 singles and 1 album between 2000 and 2001. Their greatest hit, their debut single "time after time", peaked at #13 in the Oricon singles chart.
..... Click the link for more information.planet, as defined by the International Astronomical Union (IAU), is a celestial body orbiting a star or stellar remnant that is massive enough to be rounded by its own gravity, not massive enough to cause thermonuclear fusion in its core, and has cleared its neighbouring region of
..... Click the link for more information.A sphere is a symmetrical geometrical object. In non-mathematical usage, the term is used to refer either to a round ball or to its two-dimensional surface. In mathematics, a sphere is the set of all points in three-dimensional space (R3
..... Click the link for more information.In classical geometry, a radius (plural: radii) of a circle or sphere is any line segment from its center to its perimeter. By extension, the radius of a circle or sphere is the length of any such segment. The radius is half the diameter.
..... Click the link for more information.EARTH was a short-lived Japanese vocal trio which released 6 singles and 1 album between 2000 and 2001. Their greatest hit, their debut single "time after time", peaked at #13 in the Oricon singles chart.
..... Click the link for more information.This article or section relies largely or entirely upon a .
Please help [ improve this article] by introducing appropriate of additional sources. ()
This article has been tagged since December 2006.
..... Click the link for more information.equator is an imaginary line on the Earth's surface equidistant from the North Pole and South Pole. It thus divides the Earth into a Northern Hemisphere and a Southern Hemisphere. The equators of other planets and astronomical bodies are defined analogously.
..... Click the link for more information.North Pole, also known as the Geographic North Pole or Terrestrial North Pole, is, subject to the caveats explained below, defined as the point in the northern hemisphere where the Earth's axis of rotation meets the Earth's surface.
..... Click the link for more information.South Pole, also known as the Geographic South Pole or Terrestrial South Pole, is the southernmost point on the surface of the Earth. It lies on the continent of Antarctica, on the opposite side of the Earth from the North Pole.
..... Click the link for more information.angular frequency ω (also referred to by the terms angular speed, radial frequency, and radian frequency) is a scalar measure of rotation rate. Angular frequency is the magnitude of the vector quantity angular velocity.
..... Click the link for more information.gravitational constant, the universal gravitational constant, Newton's constant, and colloquially Big G. The gravitational constant is a physical constant which appears in Newton's law of universal gravitation and in Einstein's theory of general
..... Click the link for more information.flattening, ellipticity, or oblateness of an oblate spheroid is the "squashing" of the spheroid's pole, down towards its equator.First and second flattening
The first, primary flattening, f, is the versine of the spheroid's
..... Click the link for more information.In physics, density is mass m per unit volume V—how heavy something is compared to its size. A small, heavy object, such as a rock or a lump of lead, is denser than a lighter object of the same size or a larger object of the same weight, such as pieces of
..... Click the link for more information.crust is the outermost layer of a planet.
The crust of the Earth is composed of a great variety of igneous, metamorphic, and sedimentary rocks. The crust is underlain by the mantle.
..... Click the link for more information.geoid is that equipotential surface which would coincide exactly with the mean ocean surface of the Earth, if the oceans were to be extended through the continents (such as with very narrow canals). According to C.F.
..... Click the link for more information.2004 Indian Ocean earthquake, known by the scientific community as the great Sumatra-Andaman earthquake,[1] was an undersea earthquake that occurred at 00:58:53 UTC (07:58:53 local time) December 26, 2004, with an epicentre off the west coast of Sumatra, Indonesia.
..... Click the link for more information.Anthem
Nunarput utoqqarsuanngoravit
Nuna asiilasooq
Capital
(and largest city) Nuuk (Godthåb)
..... Click the link for more information.Earth tide is the sub-meter motion of the Earth of about 12 hours or longer caused by Moon and Sun gravitation, also called body tide which is the largest contribution globally.
..... Click the link for more information.In geometry, a torus (pl. tori) is a surface of revolution generated by revolving a circle in three dimensional space about an axis coplanar with the circle, which does not touch the circle. Examples of tori include the surfaces of doughnuts and inner tubes.
..... Click the link for more information.radius of curvature (more formally, the radius of curvature of a curve at a point is the radius of the osculating circle at that point). With a sphere, the radius of curvature equals the radius.
..... Click the link for more information.horizon (Ancient Greek ὁ ὁρίζων, /ho horÃdzôn/, from ὁρίζειν, "to limit") is the line that separates earth from sky.
..... Click the link for more information.Eratosthenes of Cyrene (Greek Eρατοσθένης; 276 BC - 194 BC) was a Greek mathematician, poet, athlete, geographer and astronomer.
..... Click the link for more information.semi-major axis (also semimajor axis) is used to describe the dimensions of ellipses and hyperbolae.Ellipse
The major axis of an ellipse is its longest diameter, a line that runs through the centre and both foci, its ends being at the widest points of the shape.
..... Click the link for more information.equator is an imaginary line on the Earth's surface equidistant from the North Pole and South Pole. It thus divides the Earth into a Northern Hemisphere and a Southern Hemisphere. The equators of other planets and astronomical bodies are defined analogously.
..... Click the link for more information.1 kilometre =A kilometre (American spelling: kilometer, symbol km
SI units
0 m 0106 mm
US customary / Imperial units
0 ft 0 mi
..... Click the link for more information.1 mile =
SI units
0 m 0 km
US customary / Imperial units
0 ft 0 yd“Miles” redirects here. For other uses, see Miles (disambiguation).
..... Click the link for more information.1 nautical mile =A nautical mile or sea mile is a unit of length.
SI units
0 m 0 km
US customary / Imperial units
0 ft 0 mi
..... Click the link for more information.In geometry, the semi-minor axis (also semiminor axis) is a line segment associated with most conic sections (that is, with ellipses and hyperbolas). One end of the segment is the center of the conic section, and it is at right angles with the semi-major axis.
..... Click the link for more information.spheroid is a quadric surface in three dimensions obtained by rotating an ellipse about one of its principal axes. Three particular cases of a spheroid are:- If the ellipse is rotated about its major axis, the surface is a prolate spheroid
..... Click the link for more information.In astronomy, geography, geometry and related sciences and contexts, a direction passing by a given point is said to be vertical if it is locally aligned with the gradient of the gravity field, i.e., with the direction of the gravitational force (per unit mass) at that point.
..... Click the link for more information. - This radius of curvature in the prime vertical, which is perpendicular, or normal, to M at geodetic latitude
)
This article is copied from an article on Wikipedia.org - the free encyclopedia created and edited by online user community. The text was not checked or edited by anyone on our staff. Although the vast majority of the wikipedia encyclopedia articles provide accurate and timely information please do not assume the accuracy of any particular article. This article is distributed under the terms of GNU Free Documentation License.
Herod_Archelaus
