On the Error in the Padé Approximants for a Form of the Incomplete Gamma Function Including the Exponential Function

Closed form expressions for all entries of the Pade matrix table and their errors are derived for the incomplete gamma function $H(c,z) = cz^{ - c} e^{ - z} \int_0^z {e^t t^{c - 1} dt} ,\quad R(c) > 0,\quad H(0,z) = e^{ - z} .$ Asymptotic estimates for the error are developed. Let $(\mu ,\nu )$ b...

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Bibliographic Details
Published in:SIAM journal on mathematical analysis 1975-10, Vol.6 (5), p.829-839
Main Author: Luke, Yudell L.
Format: Article
Language:English
Subjects:
Approximation
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Summary:Closed form expressions for all entries of the Pade matrix table and their errors are derived for the incomplete gamma function $H(c,z) = cz^{ - c} e^{ - z} \int_0^z {e^t t^{c - 1} dt} ,\quad R(c) > 0,\quad H(0,z) = e^{ - z} .$ Asymptotic estimates for the error are developed. Let $(\mu ,\nu )$ be a position in the Pade matrix table where $\mu $ and $\nu $ are the degrees of the denominator and numerator polynomials, respectively, which define the Pade approximant. Our error representations hold for $c$ and $z$ fixed, $c$ not a negative integer, with $\mu $ or $\nu $ or both $\mu $ and $\nu $ approaching infinity. Under these conditions the Pade approximants converge along all rows, columns and diagonals. The asymptotic representations are remarkable in that they give very easy to apply and very realistic estimates when the parameters $\mu $ and $\nu $ are rather small. In the case $c = 0$, that is, the exponential function, uniform asymptotic estimates are developed for the main diagonal and first and second subdiagonal entries of the Pade matrix.
ISSN:0036-1410
1095-7154
DOI:10.1137/0506072