# Spheroid

(Redirected from Oblate spheroid)

A spheroid, or ellipsoid of revolution, is a quadric surface obtained by rotating an ellipse about one of its principal axes; in other words, an ellipsoid with two equal semi-diameters.

If the ellipse is rotated about its major axis, the result is a prolate (elongated) spheroid, shaped like an American football or rugby ball. If the ellipse is rotated about its minor axis, the result is an oblate (flattened) spheroid, shaped like a lentil. If the generating ellipse is a circle, the result is a sphere. A spheroid has circular symmetry.

Because of the combined effects of gravity and rotation, the shape of the Earth, and of all planets, is not quite a sphere but instead is slightly flattened in the direction of its axis of rotation. For that reason, in cartography the Earth is often approximated by an oblate spheroid instead of a sphere. The current World Geodetic System model uses a spheroid whose radius is 6,378.137 km (3,963.191 mi) at the equator and 6,356.752 km (3,949.903 mi) at the poles.

The word "spheroid" originally meant "an approximately spherical body", admitting irregularities even beyond the bi- or tri-axial ellipsoidal shape, and that is how the term is used in some older papers on geodesy (for example, referring to truncated spherical harmonic expansions of the Earth[1]).

## Equation

The assignment of semi-axes on a spheroid. It is oblate if c < a (left) and prolate if c > a (right).

The equation of a tri-axial ellipsoid centred at the origin with semi-axes a, b and c aligned along the coordinate axes is

${\displaystyle {\frac {x^{2}}{a^{2}}}+{\frac {y^{2}}{b^{2}}}+{\frac {z^{2}}{c^{2}}}=1.}$

The equation of a spheroid with z as the symmetry axis is given by setting a = b:

${\displaystyle {\frac {x^{2}+y^{2}}{a^{2}}}+{\frac {z^{2}}{c^{2}}}=1.}$

The semi-axis a is the equatorial radius of the spheroid, and c is the distance from centre to pole along the symmetry axis. There are two possible cases:

• c < a: oblate spheroid
• c > a: prolate spheroid

The case of a = c reduces to a sphere.

## Properties

### Area

An oblate spheroid with c < a has surface area

${\displaystyle S_{\rm {oblate}}=2\pi a^{2}\left(1+{\frac {1-e^{2}}{e}}{\text{artanh}}\,e\right)=2\pi a^{2}+\pi {\frac {c^{2}}{e}}\ln \left({\frac {1+e}{1-e}}\right)\quad {\mbox{where}}\quad e^{2}=1-{\frac {c^{2}}{a^{2}}}.}$

The oblate spheroid is generated by rotation about the z-axis of an ellipse with semi-major axis a and semi-minor axis c, therefore e may be identified as the eccentricity. (See ellipse.)[2]

A prolate spheroid with c > a has surface area

${\displaystyle S_{\rm {prolate}}=2\pi a^{2}\left(1+{\frac {c}{ae}}\arcsin \,e\right)\qquad {\mbox{where}}\qquad e^{2}=1-{\frac {a^{2}}{c^{2}}}.}$

The prolate spheroid is generated by rotation about the z-axis of an ellipse with semi-major axis c and semi-minor axis a; therefore, e may again be identified as the eccentricity. (See ellipse.) [3]

These formulas are identical in the sense that the formula for Soblate can be used to calculate the surface area of a prolate spheroid and vice versa. However, e then becomes imaginary and can no longer directly be identified with the eccentricity. Both of these results may be cast into many other forms using standard mathematical identities and relations between parameters of the ellipse.

### Volume

The volume inside a spheroid (of any kind) is ${\displaystyle {\frac {4\pi }{3}}a^{2}c\approx 4.19a^{2}c}$. If ${\displaystyle A=2a}$ is the equatorial diameter, and ${\displaystyle C=2c}$ is the polar diameter, the volume is ${\displaystyle {\frac {\pi }{6}}A^{2}C\approx 0.523A^{2}C}$.

### Curvature

If a spheroid is parameterized as

${\displaystyle {\vec {\sigma }}(\beta ,\lambda )=(a\cos \beta \cos \lambda ,a\cos \beta \sin \lambda ,c\sin \beta );\,\!}$

where β is the reduced or parametric latitude, λ is the longitude, and π/2 < β < +π/2 and −π < λ < +π, then its Gaussian curvature is

${\displaystyle K(\beta ,\lambda )={c^{2} \over (a^{2}+(c^{2}-a^{2})\cos ^{2}\beta )^{2}};\,\!}$

and its mean curvature is

${\displaystyle H(\beta ,\lambda )={c(2a^{2}+(c^{2}-a^{2})\cos ^{2}\beta ) \over 2a(a^{2}+(c^{2}-a^{2})\cos ^{2}\beta )^{3/2}}.\,\!}$

Both of these curvatures are always positive, so that every point on a spheroid is elliptic.

### Aspect ratio

The aspect ratio of an oblate spheroid/ellipse, b : a, is the ratio of the polar to equatorial lengths, while the flattening (also called oblateness) f, is the ratio of the equatorial-polar length difference to the equatorial length:

${\displaystyle f={\frac {a-b}{a}}=1-{\frac {b}{a}}.}$

The first eccentricity (usually simply eccentricity, as above) is often used instead of flattening.[4] It is defined by:

${\displaystyle e={\sqrt {1-{\frac {b^{2}}{a^{2}}}}}}$

The relations between eccentricity and flattening are:

${\displaystyle e={\sqrt {2f-f^{2}}}}$,
${\displaystyle f=1-{\sqrt {1-e^{2}}}}$

All modern geodetic ellipsoids are defined by the semi-major axis plus either the semi-minor axis (giving the aspect ratio), the flattening, or the first eccentricity. While these definitions are mathematically interchangeable, real-world calculations must lose some precision. To avoid confusion, an ellipsoidal definition considers its own values to be exact in the form it gives.

## Applications

The most common shapes for the density distribution of protons and neutrons in an atomic nucleus are spherical, prolate and oblate spheroidal, where the polar axis is assumed to be the spin axis (or direction of the spin angular momentum vector). Deformed nuclear shapes occur as a result of the competition between electromagnetic repulsion between protons, surface tension and quantum shell effects.

### Oblate spheroids

The planet Jupiter is an oblate spheroid with flattening ratio 0.06487

The oblate spheroid is the approximate shape of many planets and celestial bodies, including Saturn, Jupiter and the quickly-spinning star, Altair; in particular, cartographic and geodetic systems for the Earth are based on a reference ellipsoid. An extreme example of an oblate planet in science fiction is Mesklin, in Hal Clement's novel Mission of Gravity.

### Prolate spheroids

An Australian rules football.

The prolate spheroid is the shape of the ball in several sports, such as in rugby football.

Several moons of the Solar system approximate prolate spheroids in shape, though they are actually triaxial ellipsoids. Examples are Mimas, Enceladus, and Tethys (satellites of Saturn) and Miranda (a satellite of Uranus).

In contrast to being distorted into oblate spheroids via rapid rotation, celestial objects distort slightly into prolate spheroids via tidal forces when they orbit a massive body in a close orbit. The most extreme example is Jupiter's moon Io, which becomes slightly more or less prolate in its orbit due to a slight eccentricity, causing spectacular volcanism. The major axis of the prolate spheroid does not run through the satellite's poles in this case, but through the two points on its equator directly facing toward and away from the primary. A famous example in science fiction is Jinx in Larry Niven's Known Space.

The term is also used to describe the shape of some nebulae (nebulas) such as the Crab Nebula.[5]

The atomic nuclei of the actinide elements are shaped like prolate spheroids.[citation needed]

Fresnel zones, used to analyze wave propagation and interference in space, are a series of concentric prolate spheroids with principal axes aligned along the direct line-of-sight between a transmitter and a receiver.

Many submarines have a shape which can be described as prolate spheroid.[6]

In anatomy, near-spheroid organs such a testes may be measured by their long and short axes.[7]

### Dynamical properties

The moment of inertia of a spheroid is that of an ellipsoid with an additional axis of symmetry. Given a description of a spheroid as having a major axis c, and minor axes a and b, the moments of inertia along these principle axis are C, A, and B. However, in a spheroid the minor axes are symmetrical. Therefore, our inertial terms along the major axes are[8]:

${\displaystyle A=B={\frac {1}{5}}M(a^{2}+c^{2})}$
${\displaystyle C={\frac {2}{5}}M(c^{2})}$

Where M is the mass of the body defined as,

${\displaystyle M={\frac {4}{3}}\pi \rho ca^{2}}$

## References

1. ^ Torge, Geodesy, p.104
2. ^ A derivation of this result may be found at "Oblate Spheroid - from Wolfram MathWorld". Mathworld.wolfram.com. Retrieved 24 June 2014.
3. ^ A derivation of this result may be found at "Prolate Spheroid - from Wolfram MathWorld". Mathworld.wolfram.com. 7 October 2003. Retrieved 24 June 2014.
4. ^ Brial P., Shaalan C.(2009), Introduction à la Géodésie et au geopositionnement par satellites, p.8
5. ^ Trimble, Virginia Louise (October 1973), "The Distance to the Crab Nebula and NP 0532", Publications of the Astronomical Society of the Pacific, 85 (507): 579, Bibcode:1973PASP...85..579T, doi:10.1086/129507
6. ^ "What Do a Submarine, a Rocket and a Football Have in Common?". Scientific American. 8 November 2010. Retrieved 13 June 2015.
7. ^ Page 559 in: John Pellerito, Joseph F Polak (2012). Introduction to Vascular Ultrasonography (6 ed.). Elsevier Health Sciences. ISBN 9781455737666.
8. ^ Weisstein, Eric W. ""Spheroid."". MathWorld--A Wolfram Web Resource. Retrieved 16 May 2018.