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Spherical coordinates, also called spherical polar coordinates (Walton 1967, Arfken 1985), are a system of curvilinear coordinates that are natural for describing positions on a sphere or spheroid. Define 
to be the azimuthal angle in the 
-plane from the x-axis with 
(denoted 
when referred to as the longitude), 
to be the polar angle (also known as the zenith angle and colatitude, with 
where 
is the latitude) from the positive z-axis with 
, and 
to be distance (radius) from a point to the origin. This is the convention commonly used in mathematics.
In this work, following the mathematics convention, the symbols for the radial, azimuth, and zenith angle coordinates are taken as 
, 
, and 
, respectively. Note that this definition provides a logical extension of the usual polar coordinates notation, with 
remaining the angle in the 
-plane and 
becoming the angle out of that plane. The sole exception to this convention in this work is in spherical harmonics, where the convention used in the physics literature is retained (resulting, it is hoped, in a bit less confusion than a foolish rigorous consistency might engender).
Unfortunately, the convention in which the symbols 
and 
are reversed (both in meaning and in order listed) is also frequently used, especially in physics. This is especially confusing since the identical notation 
typically means (radial, azimuthal, polar) to a mathematician but (radial, polar, azimuthal) to a physicist. The symbol 
is sometimes also used in place of 
, 
instead of 
, and 
and 
instead of 
. The following table summarizes a number of conventions used by various authors. Extreme care is therefore needed when consulting the literature.
| order | notation | reference |
| (radial, azimuthal, polar) |  | this work |
| (radial, azimuthal, polar) |  | Apostol (1969, p.95), Anton (1984, p.859), Beyer (1987, p.212) |
| (radial, polar, azimuthal) |  | SphericalPlot3D in the Wolfram Language |
| (radial, polar, azimuthal) |  | ISO 31-11, Misner et al. (1973, p.205) |
| (radial, polar, azimuthal) |  | Arfken (1985, p.102) |
| (radial, polar, azimuthal) |  | Moon and Spencer (1988, p.24) |
| (radial, polar, azimuthal) |  | Korn and Korn (1968, p.60), Bronshtein et al. (2004, pp.209-210) |
| (radial, polar, azimuthal) |  | Zwillinger (1996, pp.297-299) |
The spherical coordinates 
are related to the Cartesian coordinates 
by
 |  |  | (1) |
 |  |  | (2) |
 |  |  | (3) |
where 
, 
, and 
, and the inverse tangent must be suitably defined to take the correct quadrant of 
into account.
In terms of Cartesian coordinates,
 |  |  | (4) |
 |  |  | (5) |
 |  |  | (6) |
The scale factors are
 |  |  | (7) |
 |  |  | (8) |
 |  |  | (9) |
so the metric coefficientsare
 |  |  | (10) |
 |  |  | (11) |
 |  |  | (12) |
The line element is
 | (13) |
the area element
 | (14) |
and the volume element
 | (15) |
The Jacobian is
 | (16) |
The radius vector is
 | (17) |
so the unit vectors are
 |  |  | (18) |
 |  |  | (19) |
 |  |  | (20) |
 |  |  | (21) |
 |  |  | (22) |
 |  |  | (23) |
Derivatives of the unit vectors are
 |  |  | (24) |
 |  |  | (25) |
 |  |  | (26) |
 |  |  | (27) |
 |  |  | (28) |
 |  |  | (29) |
 |  |  | (30) |
 |  |  | (31) |
 |  |  | (32) |
The gradient is
 | (33) |
and its components are
 |  |  | (34) |
 |  |  | (35) |
 |  |  | (36) |
 |  |  | (37) |
 |  |  | (38) |
 |  |  | (39) |
 |  |  | (40) |
 |  |  | (41) |
 |  |  | (42) |
(Misner et al. 1973, p.213, who however use the notation convention 
).
The Christoffel symbols of the second kind in the definition of Misner et al. (1973, p.209) are given by
 |  |  | (43) |
 |  |  | (44) |
 |  |  | (45) |
(Misner et al. 1973, p.213, who however use the notation convention 
). The Christoffel symbols of the second kind in the definition of Arfken (1985) are given by
 |  |  | (46) |
 |  |  | (47) |
 |  |  | (48) |
(Walton 1967; Moon and Spencer 1988, p.25a; both of whom however use the notation convention 
).
The divergence is
 | (49) |
or, in vector notation,
 |  |  | (50) |
 |  |  | (51) |
The covariant derivatives are given by
 | (52) |
so
 |  |  | (53) |
 |  |  | (54) |
 |  |  | (55) |
 |  |  | (56) |
 |  |  | (57) |
 |  |  | (58) |
 |  |  | (59) |
 |  |  | (60) |
 |  |  | (61) |
The commutation coefficients are givenby
 | (62) |
 | (63) |
so 
, where 
.
 | (64) |
so 
, 
.
 | (65) |
so 
.
 | (66) |
so
 | (67) |
Summarizing,
 |  |  | (68) |
 |  |  | (69) |
 |  |  | (70) |
Time derivatives of the radius vector are
 |  |  | (71) |
 |  |  | (72) |
 |  |  | (73) |
The speed is therefore given by
 | (74) |
The acceleration is
 |  |  | (75) |
 |  |  | (76) |
 |  |  | (77) |
 |  |  | (78) |
 |  |  | (79) |
 |  |  | (80) |
Plugging these in gives
 |  |  | (81) |
but
 |  |  | (82) |
 |  |  | (83) |
so
 |  |  | (84) |
 |  |  | (85) |
Time derivatives of the unitvectors are
 |  |  | (86) |
 |  |  | (87) |
 |  |  | (88) |
The curl is
 | (89) |
The Laplacian is
 |  |  | (90) |
 |  |  | (91) |
 |  |  | (92) |
The vector Laplacian in spherical coordinatesis given by
 | (93) |
To express partial derivatives with respect to Cartesian axes in terms of partial derivatives of the spherical coordinates,
 |  |  | (94) |
 |  |  | (95) |
 |  |  | (96) |
Upon inversion, the result is
 | (97) |
The Cartesian partial derivatives in sphericalcoordinates are therefore
 |  |  | (98) |
 |  |  | (99) |
 |  |  | (100) |
(Gasiorowicz 1974, pp.167-168; Arfken 1985, p.108).
The Helmholtz differential equationis separable in spherical coordinates.
See also
Azimuth, Colatitude, Great Circle, Helmholtz Differential Equation--Spherical Coordinates, Latitude, Longitude, Oblate Spheroidal Coordinates, Polar Angle, Polar Coordinates, Polar Plot, Polar Vector, Prolate Spheroidal Coordinates, Zenith Angle Explore this topic in the MathWorld classroom
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References
Anton, H. Calculus with Analytic Geometry, 2nd ed. New York: Wiley, 1984.Apostol, T.M. Calculus, 2nd ed., Vol.2: Multi-Variable Calculus and Linear Algebra, with Applications to Differential Equations and Probability. Waltham, MA: Blaisdell, 1969.Arfken, G. "Spherical Polar Coordinates." §2.5 in Mathematical Methods for Physicists, 3rd ed. Orlando, FL: Academic Press, pp.102-111, 1985.Beyer, W.H. CRC Standard Mathematical Tables, 28th ed. Boca Raton, FL: CRC Press, 1987.Bronshtein, I.N.; sem*ndyayev, K.A.; Musiol, G.; and Muehlig, H. Handbook of Mathematics, 4th ed. New York: Springer-Verlag, 2004.Gasiorowicz, S. Quantum Physics. New York: Wiley, 1974.Korn, G.A. and Korn, T.M. Mathematical Handbook for Scientists and Engineers. New York: McGraw-Hill, 1968.Misner, C.W.; Thorne, K.S.; and Wheeler, J.A. Gravitation. San Francisco, CA: W.H.Freeman, 1973.Moon, P. and Spencer, D.E. "Spherical Coordinates 
." Table 1.05 in Field Theory Handbook, Including Coordinate Systems, Differential Equations, and Their Solutions, 2nd ed. New York: Springer-Verlag, pp.24-27, 1988.Morse, P.M. and Feshbach, H. Methods of Theoretical Physics, Part I. New York: McGraw-Hill, p.658, 1953.Walton, J.J. "Tensor Calculations on Computer: Appendix." Comm. ACM 10, 183-186, 1967.Zwillinger, D. (Ed.). "Spherical Coordinates in Space." §4.9.3 in CRC Standard Mathematical Tables and Formulae. Boca Raton, FL: CRC Press, pp.297-298, 1995.
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Cite this as:
Weisstein, Eric W. "Spherical Coordinates."From MathWorld--A Wolfram Web Resource. https://mathworld.wolfram.com/SphericalCoordinates.html
