Expressing Solutions of Bessel Differential Equation in terms of Hypergeometric Functions

Wali Mohammad Azizi; Athiqullah Hayat; Mohammad Alim Rohani; Asadullah Torabi; Abdul Bari Sadiqi

doi:10.55544/jrasb.2.6.21

Authors

Wali Mohammad Azizi Department of Mathematics, Faculty of Education, Kandahar University, AFGHANISTAN. https://orcid.org/0009-0006-8673-2721
Athiqullah Hayat Civil Department, Faculty of Engineering, Kandahar University, AFGHANISTAN.
Mohammad Alim Rohani Department of Mathematics, Faculty of Education, Kandahar University, AFGHANISTAN.
Asadullah Torabi Department of Mathematics, Faculty of Education, Kandahar University, AFGHANISTAN.
Abdul Bari Sadiqi Department of Mathematics, Faculty of Education, Kandahar University, AFGHANISTAN.

DOI:

https://doi.org/10.55544/jrasb.2.6.21

Keywords:

Bessel Differential Equation, Frobenius Approach, Hypergeometric Functions, Hypergeometric Series

Abstract

The BDE (Bessel differential equation) is a second-order linear ordinary differential equation (ODE), and it is considered one of the most significant differential equations because of its extensive applications. The solutions of this differential equation are called Bessel functions. These solutions can be expressed in terms of hypergeometric functions, and in this study, the Bessel functions of the first kind are worked. Hypergeometric functions are the sum of a hypergeometric series. A series ∑▒u_n is known as hypergeometric when the ratio u_(n+1)⁄u_n is a rational function of n. BDE has coefficients with variables; therefore, it is solved by the Frobenius approach. We implement some mathematical steps based on the definition of hypergeometric functions to express the solutions in terms of hypergeometric function. The result shows that the solution of the BDE in terms of hypergeometric function is f(x)=a_0 x^p (_1^ )F_2 (1;1+(p+ρ)/2,1+(p-ρ)/2;x^2⁄4) and the two linearly independent solutions for the BDE of order ρ in terms of hypergeometric function are 〖f_1 (x)=a〗_0 x^ρ (_0^ )F_1 (1+ρ;x^2⁄4) and〖〖 f〗_2 (x)=a〗_0 x^ρ (_0^ )F_1 (1-ρ;x^2⁄4).

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