Uniform Asymptotic Expansion of the Associated Legendre Function to Leading Term for Complex Degree and Integral Order

The associated Legendre function arises naturally in the study of spherical waves. Since in practical applications it is most often symbolically represented by P_n ^m(xi) for m les n and P_n ^m(xi) equiv 0 for m > n where m is the integer order and n is the integer degree, this form will be employed to develop the uniform asymptotic expansion. The considerable extent to which this function appears in literature substantiates its importance in engineering and science, and particularly to spherical harmonics. In his book, "Partial Differential Equations in Physics" Sommerfeld covers a variety of subjects including spherical harmonics, and gives a detailed account of obtaining an expansion of the associated Legendre function, P_n ^m(cos(thetas)), by the method of steepest descents over the interval 0 les thetas les pi. The results he obtains are quite accurate for n Gt m except as thetas approaches the critical points, thetas rarr 0 or thetas rarr pi. Beginning with the same integral representation of the associated Legendre function with integer order and degree that Sommerfeld employed, a uniform asymptotic expansion is found that is applicable to the neighborhoods of thetas = 0 and thetas = pi and that becomes increasingly more accurate as n increases beyond m. Furthermore, the accuracy of the resulting uniform asymptotic expansion remains for real degree and complex degree as well. The results are plotted in order to assess the accuracy and the domain of validity of the uniform asymptotic expansion. The results of the uniform asymptotic expansion are also compared to the available approximation of the associated Legendre function given in terms of Bessel functions for small values of thetas.