Computation of the Generalized Mittag-Leffler Function and its Inverse in the Complex Plane
R. Hilfer, und H. Seybold. Abstract Book of the XXIII IUPAP International Conference on Statistical Physics, Genova, Italy, (9-13 July 2007)
Zusammenfassung
The generalized Mittag-Leffler function $E_\alpha,\beta(z)$
has been computed for arbitrary complex argument $zınC$
and parameters $\alphaınR^+$ and $\betaınR$ 1.
This function plays a fundamental role in the theory of fractional
differential equations and numerous applications in physics.
The Mittag-Leffler function interpolates smoothly between exponential
and algebraic functional behaviour. A numerical algorithm for its
evaluation has been developed. The algorithm is based on integral
representations and exponential asymptotics. Results of extensive
numerical calculations are presented. We find that all complex
zeros emerge from the point $z=1$ for small $\alpha$. They diverge towards
$-ınfty+(2k-1)\pii$ for $\alpha1^-$ and towards
$-ınfty+2k\pii$ for $\alpha1^+$ ($kınZ$).
All complex zeros collapse pairwise onto the negative real axis for
$\alpha2$. We introduce and study also the inverse generalized
Mittag-Leffler function, and determine its principal branch numerically.
0.5truecm
\noindent
1 R. Hilfer and H.J. Seybold, Integral Transforms and
Special Functions, vol. 17, (2006), p. 637
%0 Book Section
%1 statphys23_0509
%A Hilfer, R.
%A Seybold, H.J.
%B Abstract Book of the XXIII IUPAP International Conference on Statistical Physics
%C Genova, Italy
%D 2007
%E Pietronero, Luciano
%E Loreto, Vittorio
%E Zapperi, Stefano
%K calculus fractional function mittag-leffler statphys23 topic-1
%T Computation of the Generalized Mittag-Leffler Function and its Inverse in the Complex Plane
%U http://st23.statphys23.org/webservices/abstract/preview_pop.php?ID_PAPER=509
%X The generalized Mittag-Leffler function $E_\alpha,\beta(z)$
has been computed for arbitrary complex argument $zınC$
and parameters $\alphaınR^+$ and $\betaınR$ 1.
This function plays a fundamental role in the theory of fractional
differential equations and numerous applications in physics.
The Mittag-Leffler function interpolates smoothly between exponential
and algebraic functional behaviour. A numerical algorithm for its
evaluation has been developed. The algorithm is based on integral
representations and exponential asymptotics. Results of extensive
numerical calculations are presented. We find that all complex
zeros emerge from the point $z=1$ for small $\alpha$. They diverge towards
$-ınfty+(2k-1)\pii$ for $\alpha1^-$ and towards
$-ınfty+2k\pii$ for $\alpha1^+$ ($kınZ$).
All complex zeros collapse pairwise onto the negative real axis for
$\alpha2$. We introduce and study also the inverse generalized
Mittag-Leffler function, and determine its principal branch numerically.
0.5truecm
\noindent
1 R. Hilfer and H.J. Seybold, Integral Transforms and
Special Functions, vol. 17, (2006), p. 637
@incollection{statphys23_0509,
abstract = {The generalized Mittag-Leffler function $\mathrm{E}_{\alpha,\beta}(z)$
has been computed for arbitrary complex argument $z\in\mathbb{C}$
and parameters $\alpha\in\mathbb{R}^+$ and $\beta\in\mathbb{R}$ [1].
This function plays a fundamental role in the theory of fractional
differential equations and numerous applications in physics.
The Mittag-Leffler function interpolates smoothly between exponential
and algebraic functional behaviour. A numerical algorithm for its
evaluation has been developed. The algorithm is based on integral
representations and exponential asymptotics. Results of extensive
numerical calculations are presented. We find that all complex
zeros emerge from the point $z=1$ for small $\alpha$. They diverge towards
$-\infty+(2k-1)\pi\mathrm{i}$ for $\alpha\to 1^-$ and towards
$-\infty+2k\pi\mathrm{i}$ for $\alpha\to 1^+$ ($k\in\mathbb{Z}$).
All complex zeros collapse pairwise onto the negative real axis for
$\alpha\to 2$. We introduce and study also the inverse generalized
Mittag-Leffler function, and determine its principal branch numerically.
\vspace{0.5truecm}
\par \noindent
[1] R. Hilfer and H.J. Seybold, Integral Transforms and
Special Functions, vol. 17, (2006), p. 637},
added-at = {2007-06-20T10:16:09.000+0200},
address = {Genova, Italy},
author = {Hilfer, R. and Seybold, H.J.},
biburl = {https://www.bibsonomy.org/bibtex/298375f0320c749852c36736fbd3f8d25/statphys23},
booktitle = {Abstract Book of the XXIII IUPAP International Conference on Statistical Physics},
editor = {Pietronero, Luciano and Loreto, Vittorio and Zapperi, Stefano},
interhash = {39b81decf0ac922e2becae241ddee793},
intrahash = {98375f0320c749852c36736fbd3f8d25},
keywords = {calculus fractional function mittag-leffler statphys23 topic-1},
month = {9-13 July},
timestamp = {2007-06-20T10:16:22.000+0200},
title = {Computation of the Generalized Mittag-Leffler Function and its Inverse in the Complex Plane},
url = {http://st23.statphys23.org/webservices/abstract/preview_pop.php?ID_PAPER=509},
year = 2007
}