Double Fourier Sphere Method
   HOME

TheInfoList



Click Here for Items Related To - Double Fourier Sphere Method
OR:
Double Fourier Sphere Method on:   [Wikipedia]   [Google]   [Amazon]

In mathematics, the double Fourier sphere (DFS) method is a simple technique that transforms a function defined on the surface of the
sphere A sphere () is a Geometry, geometrical object that is a solid geometry, three-dimensional analogue to a two-dimensional circle. A sphere is the Locus (mathematics), set of points that are all at the same distance from a given point in three ...
to a function defined on a rectangular domain while preserving
periodicity Periodicity or periodic may refer to: Mathematics * Bott periodicity theorem, addresses Bott periodicity: a modulo-8 recurrence relation in the homotopy groups of classical groups * Periodic function, a function whose output contains values tha ...
in both the longitude and latitude directions.


Introduction

First, a function f(x, y, z) on the sphere is written as f(\lambda,\theta) using
spherical coordinates In mathematics, a spherical coordinate system is a coordinate system for three-dimensional space where the position of a point is specified by three numbers: the ''radial distance'' of that point from a fixed origin, its ''polar angle'' meas ...
, i.e., : f(\lambda,\theta) = f(\cos\lambda\sin\theta,\sin\lambda\sin\theta, \cos\theta), (\lambda,\theta)\in \pi,\pitimes ,\pi The function f(\lambda, \theta) is 2\pi-periodic in \lambda, but not periodic in \theta. The periodicity in the latitude direction has been lost. To recover it, the function is "doubled up” and a related function on \pi,\pitimes \pi,\pi/math> is defined as : \tilde(\lambda,\theta) = \begin g(\lambda + \pi, \theta), & (\lambda, \theta) \in \pi, 0\times , \pi\\ h(\lambda, \theta), &(\lambda, \theta) \in , \pi\times , \pi\\ g(\lambda, -\theta), &(\lambda, \theta) \in , \pi\times \pi, 0\\ h(\lambda + \pi, -\theta), & (\lambda, \theta) \in \pi, 0\times \pi, 0\\ \end where g(\lambda, \theta) = f(\lambda- \pi, \theta) and h(\lambda, \theta) = f(\lambda, \theta) for (\lambda, \theta) \in , \pi\times , \pi/math>. The new function \tilde is 2\pi-periodic in \lambda and \theta, and is constant along the lines \theta = 0 and \theta = \pm\pi, corresponding to the poles. The function \tilde can be expanded into a double Fourier series : \tilde \approx \sum_^n \sum_^n a_ e^e^


History

The DFS method was proposed by Merilees and developed further by Steven Orszag. The DFS method has been the subject of relatively few investigations since (a notable exception is Fornberg's work), perhaps due to the dominance of
spherical harmonics In mathematics and physical science, spherical harmonics are special functions defined on the surface of a sphere. They are often employed in solving partial differential equations in many scientific fields. Since the spherical harmonics form ...
expansions. Over the last fifteen years it has begun to be used for the computation of gravitational fields near black holes and to novel space-time spectral analysis.C. Sun, J. Li, F.-F. Jin, and F. Xie, Contrasting meridional structures of stratospheric and tropospheric planetary wave variability in the northern hemisphere, Tellus A, 66 (2014)


References

{{Reflist Black holes Boundary value problems Coordinate systems Variants of random walks Equations of astronomy