@article{ajams2015333,
author={Benghorbal, Mhenni M.},
title={A Unified Formula for The <i>n</i>th Derivative and The <i>n</i>th Anti-Derivative of the Bessel Function of Real Orders},
journal={American Journal of Applied Mathematics and Statistics},
volume={3},
number={3},
pages={100--104},
year={2015},
url={http://pubs.sciepub.com/ajams/3/3/3},
issn={2328-7292},
abstract={A complete solution to the problem of finding the <i>n</i>th derivative and the <i>n</i>th anti-derivative of elementary and special functions has been given. It deals with the problem of finding formulas for the <i>n</i>th derivative and the <i>n</i>th anti-derivative of elementary and special functions. We do not limit <i>n </i>to be an integer, it can be a real number. In general, the solution is given through unified formulas in terms of the Fox H-function and the Miejer G-function which, in many cases, can be simplified to less general functions. This, in turn, makes the first real use of these two special functions in the literature and shows the need of such functions. In this talk, we would like to present the idea on the Bessel function which is a well known special function. One of the key points in this work is that the approach does not depend on integration techniques. We adopt the classical definitions for generalization of differentiation and integration. Namely, the <i>n</i>th order of differentiation is found according to the Riemann-Liouville definition <img src=image/abs1.png></img> where (<i>k </i><i>?</i><i> </i>1 <i>&lt; n &lt; k</i>) and <img src=image/abs2.png></img>. The generalized Cauchy <i>n</i>-fold integral is adopted for the <i>n</i>th order of integration <img src=image/abs3.png></img>},
doi={10.12691/ajams-3-3-3}
publisher={Science and Education Publishing}
}