长球波函数

在数学中，长球波函数由一个限时、限频、与第二个限时的函数相乘而成。假定 $Q_{T}$ 表示一个切截时间的运算器，且 $x=Q_{T}x$ ，则x必为有限时间区间的函数，当x在 $[-T/2;T/2]$ 的区间内。同理，假定 $P_{W}$ 表示一个理想的低频滤波器，且 $x=P_{W}x$ ，则x必为有限带宽区间的函数，当x在 $[-W;W]$ 的区间内。透过组合上述运算子，使得 $Q_{T}P_{W}Q_{T}$ 转变成线性、有界且自伴的运算式。对于 $n=1,2,\ldots$ ，我们假设 $\psi _{n}$ 为第n项的本征函数，定义下列函式

\ Q_{T}P_{W}Q_{T}\psi _{n}=\lambda _{n}\psi _{n},

其中 $\{\lambda _{n}\}_{n}$ 为对应的本征值。此时限函数 $\{\psi _{n}\}_{n}$ 即为长球波函数(PSWFs).在此领域中，几个非常重要的先驱文章由Slepian and Pollak,^[1] Landau and Pollak,^[2]^[3] and Slepian.^[4]^[5]所提出。

这些函数有些不同的意涵，当在解亥姆霍兹方程 $\Delta \Phi +k^{2}\Phi =0$ ，透过在长球面坐标系做变数分离，使得 $(\xi ,\eta ,\phi )$ 各代表：

\ x=(d/2)\xi \eta ,

\ y=(d/2){\sqrt {(\xi ^{2}-1)(1-\eta ^{2})}}\cos \phi ,

\ z=(d/2){\sqrt {(\xi ^{2}-1)(1-\eta ^{2})}}\sin \phi ,

\ \xi >=1

and

|\eta |<=1

.

得到解 $\Phi (\xi ,\eta ,\phi )$ 为长球波函数 $R_{mn}(c,\xi )$ 与角球波函数 $S_{mn}(c,\eta )$ 的成积乘上 $e^{im\phi }$ . 这里的变数c可定义为 $c=kd/2$ , with $d$ 为长球的椭圆截面的两焦点的距离。

径向波(The radial wave function) $R_{mn}(c,\xi )$ 满足线性常微分方程:

\ (\xi ^{2}-1){\frac {d^{2}R_{mn}(c,\xi )}{d\xi ^{2}}}+2\xi {\frac {dR_{mn}(c,\xi )}{d\xi }}-\left(\lambda _{mn}(c)-c^{2}\xi ^{2}+{\frac {m^{2}}{\xi ^{2}-1}}\right){R_{mn}(c,\xi )}=0

此本征值 $\lambda _{mn}(c)$ 在Sturm-Liouville 微分方程中已被固定，透过设定 ${R_{mn}(c,\xi )}$ 为有限函数，当 $|\xi |\to 1_{+}$ .

角波函数满足下列微分方程：

\ (\eta ^{2}-1){\frac {d^{2}S_{mn}(c,\eta )}{d\eta ^{2}}}+2\eta {\frac {dS_{mn}(c,\eta )}{d\eta }}-\left(\lambda _{mn}(c)-c^{2}\eta ^{2}+{\frac {m^{2}}{\eta ^{2}-1}}\right){S_{mn}(c,\eta )}=0

这跟径向波函数式为同样的微分方程。然而，这两式的变数的范围是不同的(在径向波函数中 $\xi >=1$ )，在角波函数中 $|\eta |<=1$ )。

当给定 $c=0$ ，这两个微分方程可以简化成满足伴随勒让德多项式的式子。当给定 $c\neq 0$ ，角波函数可被展开成勒让德级数。

注意，如果我们将角波函数写成 $S_{mn}(c,\eta )=(1-\eta ^{2})^{m/2}Y_{mn}(c,\eta )$ ，函数 $Y_{mn}(c,\eta )$ 将满足以下线性微分方程：

$\ (1-\eta ^{2}){\frac {d^{2}Y_{mn}(c,\eta )}{d\eta ^{2}}}-2(m+1)\eta {\frac {dY_{mn}(c,\eta )}{d\eta }}+\left(c^{2}\eta ^{2}+m(m+1)-\lambda _{mn}(c)\right){Y_{mn}(c,\eta )}=0,$

此函数为球波函数。这个辅助方程式在Stratton^[6] 1935年的文章被当作例子。

现存不少不同的球函数标准化的方法，在Abramowitz and Stegun.^[7]的文章中有整理的表格。Abramowitz跟Stegun(以及现在的相关文章)都沿用Flammer当初提出来的符号^[8]。

一开始，球波函数是由C. Niven,^[9]提出，他在球座标上引入Helmholtz方程式。许多专题论文已经探讨出球波函数的很多面向，例如Strutt,^[10] Stratton et al.,^[11] Meixner and Schafke,^[12] and Flammer.^[8]等人的作品。

Flammer^[8]提供了一个完整的讨论，计算出长球与扁球的本征值、角波函数与径函数。许多计算机程序已经因应发展出来，其中包含King与其团队,^[13] Patz和Van Buren,^[14] Baier与其团队,^[15] Zhang和Jin,^[16] Thompson,^[17]、Falloon.^[18] Van Buren和Boisvert^[19]^[20]最近发展出新的方法去计算出长球波函数，延伸了数值解的能力，能运算极广的变数范围。Fortran源代码结合了新的结果与传统的方法，可见于http://www.mathieuandspheroidalwavefunctions.com.。（页面存档备份，存于互联网档案馆）

Flammer,^[8] Hunter,^[21]^[22] Hanish et al.,^[23]^[24]^[25] and Van Buren et al.^[26]等人也提出了数值解的整理表格。

NIST提供的DLMF(Digital Library of Mathematical Functions)(http://dlmf.nist.gov)是個了解球波函數的良好資源。^{[永久失效链接]}

关于值域落在单位球的表面的长球波函数，我们通称为"Slepian functions"^[27] (另见“频谱集中问题”)。这函数存在非常多的应用，像是大地测量^[28]以及宇宙学.^[29]

参考文献

^ D. Slepian and H. O. Pollak. Prolate Spheroidal Wave Functions, Fourier Analysis and Uncertainty - I^{[永久失效链接]} Bell System Technical Journal 40 (1961)
^ H. J. Landau and H. O. Pollak. Prolate Spheroidal Wave Functions, Fourier Analysis and Uncertainty - II^{[永久失效链接]} Bell System Technical Journal 40 (1961)
^ H. J. Landau and H. O. Pollak. Prolate Spheroidal Wave Functions, Fourier Analysis and Uncertainty -- III: The Dimension of the Space of Essentially Time- and Band-Limited Signals^{[永久失效链接]} Bell System Technical Journal 41 (1962)
^ D. Slepian Prolate Spheroidal Wave Functions, Fourier Analysis and Uncertainty - IV: Extensions to Many Dimensions; Generalized Prolate Spheroidal Functions^{[永久失效链接]} Bell System Technical Journal 43 (1964)
^ D. Slepian. Prolate Spheroidal Wave Functions, Fourier Analysis, and Uncertainty - V: The Discrete Case^{[永久失效链接]} Bell System Technical Journal 57 (1978)
^ J. A. Stratton Spheroidal functions （页面存档备份，存于互联网档案馆） Proceedings of the National Academy of Sciences (USA) 21, 51 (1935)
^ . M. Abramowitz and I. Stegun. Handbook of Mathematical Functions pp. 751-759 （页面存档备份，存于互联网档案馆） (Dover, New York, 1972)
^ ^8.0 ^8.1 ^8.2 ^8.3 C. Flammer. Spheroidal Wave Functions Stanford University Press, Stanford, CA, 1957
^ C. Niven )On the conduction of heat in ellipsoids of revolution. （页面存档备份，存于互联网档案馆） Philosophical transactions of the Royal Society of London, 171 p. 117 (1880)
^ M. J. O. Strutt. Lamesche, Mathieusche and Verdandte Funktionen in Physik und Technik Ergebn. Math. u. Grenzeb, 1, pp. 199-323, 1932
^ J. A. Stratton, P. M. Morse, J. L. Chu, and F. J. Corbato. Spheroidal Wave Functions Wiley, New York, 1956
^ J. Meixner and F. W. Schafke. Mathieusche Funktionen und Sphäroidfunktionen Springer-Verlag, Berlin, 1954
^ B. J. King, R. V. Baier, and S Hanish A Fortran computer program for calculating the prolate spheroidal radial functions of the first and second kind and their first derivatives. （页面存档备份，存于互联网档案馆） (1970)
^ B. J. Patz and A. L. Van Buren A Fortran computer program for calculating the prolate spheroidal angular functions of the first kind. （页面存档备份，存于互联网档案馆） (1981)
^ R. V. Baier, A. L. Van Buren, S. Hanish, B. J. King - Spheroidal wave functions: their use and evaluation （页面存档备份，存于互联网档案馆） The Journal of the Acoustical Society of America, 48, pp. 102–102 (1970)
^ S. Zhang and J. Jin. Computation of Special Functions, Wiley, New York, 1996
^ W. J. Thomson Spheroidal Wave functions 互联网档案馆的存档，存档日期2010-02-16. Computing in Science & Engineering p. 84, May–June 1999
^ P. E. Falloon Thesis on numerical computation of spheroidal functions 互联网档案馆的存档，存档日期2011-04-11. University of Western Australia, 2002
^ A. L. Van Buren and J. E. Boisvert. Accurate calculation of prolate spheroidal radial functions of the first kind and their first derivatives, Quarterly of Applied Mathemathics 60, pp. 589-599, 2002
^ A. L. Van Buren和J. E. Boisvert. Improved calculation of prolate spheroidal radial functions of the second kind and their first derivatives, Quarterly of Applied Mathematics 62, pp. 493-507, 2004
^ H. E. Hunter Tables of prolate spheroidal functions for m=0: Volume I. （页面存档备份，存于互联网档案馆） (1965)
^ H. E. Hunter Tables of prolate spheroidal functions for m=0 : Volume II. （页面存档备份，存于互联网档案馆） (1965)
^ S. Hanish, R. V. Baier, A. L. Van Buren, and B. J. King Tables of radial spheroidal wave functions, volume 1, prolate, m = 0 (1970)
^ S. Hanish, R. V. Baier, A. L. Van Buren, and B. J. King Tables of radial spheroidal wave functions, volume 2, prolate, m = 1 （页面存档备份，存于互联网档案馆） (1970)
^ S. Hanish, R. V. Baier, A. L. Van Buren, and B. J. King Tables of radial spheroidal wave functions, volume 3, prolate, m = 2 （页面存档备份，存于互联网档案馆） (1970)
^ A. L. Van Buren, B. J. King, R. V. Baier, and S. Hanish. Tables of angular spheroidal wave functions, vol. 1, prolate, m = 0, Naval Research Lab. Publication, U. S. Govt. Printing Office, 1975
^ F. J. Simons, M. A. Wieczorek and F. A. Dahlen. Spatiospectral concentration on a sphere. SIAM Review, 2006, doi:10.1137/S0036144504445765
^ F. J. Simons and Dahlen, F. A. Spherical Slepian functions and the polar gap in Geodesy. Geophysical Journal International, 2006, doi:10.1111/j.1365-246X.2006.03065.x
^ F. A. Dahlen和F. J. Simons. Spectral estimation on a sphere in geophysics and cosmology. Geophysical Journal International, 2008, doi:10.1111/j.1365-246X.2008.03854.x

外部链接

MathWorld Spheroidal Wave functions （页面存档备份，存于互联网档案馆）
MathWorld Prolate Spheroidal Wave Function （页面存档备份，存于互联网档案馆）
MathWorld Oblate Spheroidal Wave function （页面存档备份，存于互联网档案馆）

[1] D. Slepian and H. O. Pollak. Prolate Spheroidal Wave Functions, Fourier Analysis and Uncertainty - I^{[永久失效链接]} Bell System Technical Journal 40 (1961)

[2] H. J. Landau and H. O. Pollak. Prolate Spheroidal Wave Functions, Fourier Analysis and Uncertainty - II^{[永久失效链接]} Bell System Technical Journal 40 (1961)

[3] H. J. Landau and H. O. Pollak. Prolate Spheroidal Wave Functions, Fourier Analysis and Uncertainty -- III: The Dimension of the Space of Essentially Time- and Band-Limited Signals^{[永久失效链接]} Bell System Technical Journal 41 (1962)

[4] D. Slepian Prolate Spheroidal Wave Functions, Fourier Analysis and Uncertainty - IV: Extensions to Many Dimensions; Generalized Prolate Spheroidal Functions^{[永久失效链接]} Bell System Technical Journal 43 (1964)

[5] D. Slepian. Prolate Spheroidal Wave Functions, Fourier Analysis, and Uncertainty - V: The Discrete Case^{[永久失效链接]} Bell System Technical Journal 57 (1978)

[6] J. A. Stratton Spheroidal functions （页面存档备份，存于互联网档案馆） Proceedings of the National Academy of Sciences (USA) 21, 51 (1935)

[7] . M. Abramowitz and I. Stegun. Handbook of Mathematical Functions pp. 751-759 （页面存档备份，存于互联网档案馆） (Dover, New York, 1972)

[Flammer-8] 8.0 ^8.1 ^8.2 ^8.3 C. Flammer. Spheroidal Wave Functions Stanford University Press, Stanford, CA, 1957

[9] C. Niven )On the conduction of heat in ellipsoids of revolution. （页面存档备份，存于互联网档案馆） Philosophical transactions of the Royal Society of London, 171 p. 117 (1880)

[10] M. J. O. Strutt. Lamesche, Mathieusche and Verdandte Funktionen in Physik und Technik Ergebn. Math. u. Grenzeb, 1, pp. 199-323, 1932

[11] J. A. Stratton, P. M. Morse, J. L. Chu, and F. J. Corbato. Spheroidal Wave Functions Wiley, New York, 1956

[12] J. Meixner and F. W. Schafke. Mathieusche Funktionen und Sphäroidfunktionen Springer-Verlag, Berlin, 1954

[13] B. J. King, R. V. Baier, and S Hanish A Fortran computer program for calculating the prolate spheroidal radial functions of the first and second kind and their first derivatives. （页面存档备份，存于互联网档案馆） (1970)

[14] B. J. Patz and A. L. Van Buren A Fortran computer program for calculating the prolate spheroidal angular functions of the first kind. （页面存档备份，存于互联网档案馆） (1981)

[15] R. V. Baier, A. L. Van Buren, S. Hanish, B. J. King - Spheroidal wave functions: their use and evaluation （页面存档备份，存于互联网档案馆） The Journal of the Acoustical Society of America, 48, pp. 102–102 (1970)

[16] S. Zhang and J. Jin. Computation of Special Functions, Wiley, New York, 1996

[17] W. J. Thomson Spheroidal Wave functions 互联网档案馆的存档，存档日期2010-02-16. Computing in Science & Engineering p. 84, May–June 1999

[18] P. E. Falloon Thesis on numerical computation of spheroidal functions 互联网档案馆的存档，存档日期2011-04-11. University of Western Australia, 2002

[19] A. L. Van Buren and J. E. Boisvert. Accurate calculation of prolate spheroidal radial functions of the first kind and their first derivatives, Quarterly of Applied Mathemathics 60, pp. 589-599, 2002

[20] A. L. Van Buren和J. E. Boisvert. Improved calculation of prolate spheroidal radial functions of the second kind and their first derivatives, Quarterly of Applied Mathematics 62, pp. 493-507, 2004

[21] H. E. Hunter Tables of prolate spheroidal functions for m=0: Volume I. （页面存档备份，存于互联网档案馆） (1965)

[22] H. E. Hunter Tables of prolate spheroidal functions for m=0 : Volume II. （页面存档备份，存于互联网档案馆） (1965)

[23] S. Hanish, R. V. Baier, A. L. Van Buren, and B. J. King Tables of radial spheroidal wave functions, volume 1, prolate, m = 0 (1970)

[24] S. Hanish, R. V. Baier, A. L. Van Buren, and B. J. King Tables of radial spheroidal wave functions, volume 2, prolate, m = 1 （页面存档备份，存于互联网档案馆） (1970)

[25] S. Hanish, R. V. Baier, A. L. Van Buren, and B. J. King Tables of radial spheroidal wave functions, volume 3, prolate, m = 2 （页面存档备份，存于互联网档案馆） (1970)

[26] A. L. Van Buren, B. J. King, R. V. Baier, and S. Hanish. Tables of angular spheroidal wave functions, vol. 1, prolate, m = 0, Naval Research Lab. Publication, U. S. Govt. Printing Office, 1975

[27] F. J. Simons, M. A. Wieczorek and F. A. Dahlen. Spatiospectral concentration on a sphere. SIAM Review, 2006, doi:10.1137/S0036144504445765

[28] F. J. Simons and Dahlen, F. A. Spherical Slepian functions and the polar gap in Geodesy. Geophysical Journal International, 2006, doi:10.1111/j.1365-246X.2006.03065.x

[29] F. A. Dahlen和F. J. Simons. Spectral estimation on a sphere in geophysics and cosmology. Geophysical Journal International, 2008, doi:10.1111/j.1365-246X.2008.03854.x

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