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Error bounds and exponential improvements for the asymptotic expansions of the gamma function and its reciprocal

Published online by Cambridge University Press:  03 June 2015

Gergő Nemes
Gergő Nemes*
Affiliation:
Department of Mathematics and Its Applications, Central European University, Nádor utca 9, 1051 Budapest, Hungary, (nemesgery@gmail.com)
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Abstract

In 1994 Boyd derived a resurgence representation for the gamma function, exploiting the 1991 reformulation of the method of steepest descents by Berry and Howls. Using this representation, he was able to derive a number of properties of the asymptotic expansion for the gamma function, including explicit and realistic error bounds, the smooth transition of the Stokes discontinuities and asymptotics for the late coefficients. The main aim of this paper is to modify Boyd’s resurgence formula, making it suitable for deriving better error estimates for the asymptotic expansions of the gamma function and its reciprocal. We also prove the exponentially improved versions of these expansions complete with error terms. Finally, we provide new (formal) asymptotic expansions for the coefficients appearing in the asymptotic series and compare their numerical efficacy with the results of earlier authors.

Type
Research Article
Information
Proceedings of the Royal Society of Edinburgh Section A: Mathematics , Volume 145 , Issue 3 , June 2015 , pp. 571 - 596
Copyright
Copyright © Royal Society of Edinburgh 2015 

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References

1 Berry, M. V.. Uniform asymptotic smoothing of Stokes’s discontinuities. Proc. R. Soc. Lond. A422 (1989), 721.Google Scholar
2 Berry, M. V. and Howls, C. J.. Hyperasymptotics for integrals with saddles. Proc. R. Soc. Lond. A434 (1991), 657675.Google Scholar
3 Borwein, J. M. and Corless, R. M.. Emerging tools for experimental mathematics. Am. Math. Mon. 106 (1999), 899909.Google Scholar
4 Boyd, W. G. C.. Stieltjes transforms and the Stokes phenomenon. Proc. R. Soc. Lond. A 429 (1990), 227246.Google Scholar
5 Boyd, W. G. C.. Error bounds for the method of steepest descents. Proc. R. Soc. Lond. A440 (1993), 493518.Google Scholar
6 Boyd, W. G. C.. Gamma function asymptotics by an extension of the method of steepest descents. Proc. R. Soc. Lond. A 447 (1994), 609630.Google Scholar
7 Boyd, W. G. C.. Approximations for the late coefficients in asymptotic expansions arising in the method of steepest descents. Meth. Applic. Analysis 2 (1995), 475489.Google Scholar
8 Brassesco, S. and Méndez, M. A.. The asymptotic expansion for n! and the Lagrange inversion formula. Ramanujan J. 24 (2011), 219234.Google Scholar
9 Comtet, L.. Advanced combinatorics (Dordrecht: Reidel, 1974).Google Scholar
10 Copson, E. T.. Asymptotic expansions (Cambridge University Press, 1965).Google Scholar
11 Angelis, V. De. Asymptotic expansions and positivity of coefficients for large powers of analytic functions. Int. J. Math. Math. Sci. 2003 (2003), 10031025.Google Scholar
12 Diekmann, O.. Asymptotic expansion of certain numbers related to the gamma function (Amsterdam: Mathematisch Centrum, 1975).Google Scholar
13 Dingle, R. B.. Asymptotic expansions: their derivation and interpretation (Academic, 1973).Google Scholar
14 Lauwerier, H. A.. The calculation of the coefficients of certain asymptotic series by means of linear recurrent relations. Appl. Sci. Res. B2 (1952), 7784.Google Scholar
15 López, J. L., Pagola, P. and Sinusía, E. Pérez. A simplification of Laplace’s method: applications to the gamma function and Gauss hypergeometric function. J. Approx. Theory 161 (2009), 280291.Google Scholar
16 Murnaghan, F. D. and Wrench, J. W. Jr. The converging factor for the exponential integral. David Taylor Model Basin Report 1535 (1963).Google Scholar
17 Nemes, G.. An explicit formula for the coefficients in Laplace’s method. Constr. Approx. 38 (2013), 471487.Google Scholar
18 Olver, F. W. J.. The asymptotic expansion of Bessel functions of large order. Phil. Trans. R. Soc. Lond. A 247 (1954), 328368.Google Scholar
19 Olver, F. W. J.. Error bounds for the Laplace approximation for definite integrals. J. Approx. Theory 1 (1968), 293313.Google Scholar
20 Olver, F. W. J.. Why steepest descents? SIAM Rev. 12 (1970), 228247.Google Scholar
21 Olver, F. W. J.. Uniform, exponentially improved, asymptotic expansions for the generalized exponential integral. SIAM J. Math. Analysis 22 (1991), 14601474.Google Scholar
22 Olver, F. W. J.. Uniform, exponentially improved, asymptotic expansions for the confluent hypergeometric function and other integral transforms. SIAM J. Math. Analysis 22 (1991), 14751489.Google Scholar
23 Olver, F. W. J., Lozier, D. W., Boisvert, R. F. and Clark, C. W. (eds). NIST handbook of mathematical functions (Cambridge University Press, 2010).Google Scholar
24 Paris, R. B.. On the use of Hadamard expansions in hyperasymptotic evaluation of Laplace-type integrals. I. Real variable. J. Computat. Appl. Math. 167 (2004), 293319.Google Scholar
25 Paris, R. B.. Hadamard expansions and hyperasymptotic evaluation: an extension of the method of steepest descents (Cambridge University Press, 2011).Google Scholar
26 Paris, R. B. and Kaminski, D.. Asymptotics and Mellin–Barnes integrals (Cambridge University Press, 2001).Google Scholar
27 Paris, R. B. and Wood, A. D.. Exponentially-improved asymptotics for the gamma function. J. Computat. Appl. Math. 41 (1992), 135143.Google Scholar
28 Remmert, R. and Kay, L. D.. Classical topics in complex function theory (Springer, 1997).Google Scholar
29 Spira, R.. Calculation of the gamma function by Stirling’s formula. Math. Comp. 25 (1971), 317322.Google Scholar
30 Temme, N. M.. Special functions: an introduction to the classical functions of mathematical physics (Wiley, 1996).Google Scholar
31 Titchmarsh, E. C.. The theory of functions, 2nd edn (Oxford University Press, 1976).Google Scholar
32 Watson, G. N.. Theorems stated by Ramanujan (V): approximations connected with e x . Proc. Lond. Math. Soc. 29 (1929), 293308.Google Scholar
33 Wong, R.. Asymptotic approximations of integrals (Philadelphia, PA: SIAM, 2001).Google Scholar
34 Wrench, J. W. Jr. Concerning two series for the gamma function. Math. Comput. 22 (1968), 617626.Google Scholar