From the hyper-Bessel operators of Dimovski to the generalized fractional calculus

In 1966 Ivan Dimovski introduced and started detailed studies on the Bessel type differential operators B of arbitrary (integer) order m ≥ 1. He also suggested a variant of the Obrechkoff integral transform (arising in a paper of 1958 by another Bulgarian mathematician Nikola Obrechkoff) as a Laplac...

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Bibliographic Details
Published in:Fractional calculus & applied analysis 2014-12, Vol.17 (4), p.977-1000
Main Author: Kiryakova, Virginia
Format: Article
Language:English
Subjects:
Abstract Harmonic Analysis
Analysis
Functional Analysis
generalized fractional calculus
hyper-Bessel operators
Integral Transforms
integral transforms of Laplace type
Mathematics
Mathematics and Statistics
Operational Calculus
Primary 26A33, 44A40
Secondary 44A20, 33C60, 33E12
special functions
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Summary:In 1966 Ivan Dimovski introduced and started detailed studies on the Bessel type differential operators B of arbitrary (integer) order m ≥ 1. He also suggested a variant of the Obrechkoff integral transform (arising in a paper of 1958 by another Bulgarian mathematician Nikola Obrechkoff) as a Laplace-type transform basis of a corresponding operational calculus for B and for its linear right inverse integral operator L . Later, the developments on these linear singular differential operators appearing in many problems of mathematical physics, have been continued by the author of this survey who called them hyper-Bessel differential operators, in relation to the notion of hyper-Bessel functions of Delerue (1953), shown to form a fundamental system of solutions of the IVPs for By ( t ) = λy ( t ). We have been able to extend Dimovski’s results on the hyper-Bessel operators and on the Obrechkoff transform due to the happy hint to attract the tools of the special functions as Meijer’s G -function and Fox’s H -function to handle successfully these matters. These author’s studies have lead to the introduction and development of a theory of generalized fractional calculus (GFC) in her monograph (1994) and subsequent papers, and to various applications of this GFC in other topics of analysis, differential equations, special functions and integral transforms. Here we try briefly to expose the ideas leading to this GFC, its basic facts and some of the mentioned applications.
ISSN:1311-0454
1314-2224
DOI:10.2478/s13540-014-0210-4