Hostname: page-component-586b7cd67f-tf8b9 Total loading time: 0 Render date: 2024-11-28T04:45:41.394Z Has data issue: false hasContentIssue false
  • English
  • Français

XXVII.—Expansions of Lamé Functions into Series of Legendre Functions*

Published online by Cambridge University Press:  14 February 2012

A. Erdélyi
A. Erdélyi
Affiliation:
Mathematical Institute, The University, Edinburgh
Get access Rights & Permissions [Opens in a new window]

Summary

28. This paper contains the investigation of certain properties of periodic solutions of Lamé's differential equation by means of representation of these solutions by (in general infinite) series of associated Legendre functions. Terminating series of associated Legendre functions representing Lamé polynomials have been used by E. Heine and G. H. Darwin. The latter used them also for numerical computation of Lamé polynomials. It appears that infinite series of Legendre functions representing transcendental Lamé functions have not been discussed previously. In two respects these series seem to be superior to the generally used power-series and Fourier-Jacobi series, (i) They are convergent in some parts of the complex plane of the variable where both power-series and Fourier-Jacobi series diverge, (ii) They permit by simply replacing Legendre functions of first kind by those of second kind, to deal with Lamé functions of second kind as well as Lamé functions of first kind (§ 15).

In §§ 2 and 8 of the present paper the series are heuristically deduced from the integral equations satisfied by periodic Lamé functions. Inserting the series found heuristically, with unknown coefficients, into Lamé's differential equation, recurrence relations for the coefficients are obtained (§§ 9–12). These recurrence relations yield the (in general transcendental) equations in form of (in general infinite) continued fractions for the determination of the characteristic numbers. The convergence of the series can be discussed completely.

There are altogether forty-eight different series. Every one of the eight types of Lamé polynomials is represented by six different series (see table in § 13). There are interesting relations (§ 14) between series representing the same function.

Next infinite series representing transcendental Lamé functions are discussed. It is seen that transcendental Lamé functions are only simply-periodic (§§ 18, 19). Lamé functions of real (§§ 20–22) and imaginary (§§ 23-24) period are represented by series of Legendre functions the variables of which are different in both cases.

The paper concludes with a brief discussion of the most important limiting cases, and a short mention of other types of series of Legendre functions representing Lamé functions.

Type
Research Article
Information
Proceedings of the Royal Society of Edinburgh Section A: Mathematics , Volume 62 , Issue 3 , 1948 , pp. 247 - 267
Copyright
Copyright © Royal Society of Edinburgh 1946

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES TO LITERATURE

Darwin, G. H., 1901. “Ellipsoidal harmonic analysis”, Trans. Roy. Soc. London, A, CXCVII, 461557.Google Scholar
Gauss, C. F., 1866. Gesammelte Werke, III.Google Scholar
Heine, E., 1859 a. “Auszug eines Schreibens über Lamésche Funktionen an den Herausgeber”, Journ. für Math., LVI, 7986.Google Scholar
Heine, E., 1859b. “Einige Eigenschaften der Laméschen Funktionen”, Journ. fur Math., LVI, 8799.Google Scholar
Heine, E., 1878. Handbuch der Kugelfunktionen, I.Google Scholar
Hobson, E. W., 1892. “The harmonic functions for the elliptic cone”, Proc. London Math. Soc., xxm, 231240.Google Scholar
Hobson, E. W., 1931. The theory of spherical and ellipsoidal harmonics.Google Scholar
Humbert, P., 1926. “Fonctions de Lamé et fonctions de Mathieu”, Mini. Sci. Math., Fasc. x.Google Scholar
Ince, E. L., 1940a. “The periodic Lamé functions”, Proc. Roy. Soc. Edin., LX, 4763.CrossRefGoogle Scholar
Ince, E. L., 1940b. “Further investigations into the periodic Lamé functions”, Proc. Roy. Soc. Edin., LX, 8399.CrossRefGoogle Scholar
Lambe, C. G., and Ward, D. R., 1934. “Some differential equations and associated integral equations”, Quart. Journ. Math. (Oxford), v, 8197.Google Scholar
Lindemann, F., 1883. “Ueber die Differentialgleichung der Funktionen des elliptischen Zylinders”, Math. Ann., XXII, 117123.CrossRefGoogle Scholar
Perron, O., 1913. Die Lehre von den Kettenbrüchen.Google Scholar
Schubert, H., 1886. “Ueber die Integration der Differentialgleichung ”, Dissertation, Königsberg.Google Scholar
Strutt, M. J. O., 1932. “Lamésche-Mathieusche und verwandte Funktionen in Physik und Technik”, Ergebnisse der Math, und ihrer Grenzgebiete, Band I, Heft 3.Google Scholar
Whittaker, E. T., and Watson, G. N., 1927. Modern Analysis.Google Scholar