1. Introduction
A number of integral formulas involving a variety of special functions have been developed by many authors (see [2,3,4,5], also see [7] and [10]) motivated by their work. We presents two integral formulae involving the Multiple (multiindex) Mittag-Leffler function, which are expressed in terms of Wright Hypergeometric function. Some interesting cases of our main results are also considered.
The generalization of the generalized hypergeometric series pFq (1.9) is due to Fox [1] and Wright ([12,13,14]) who studied the asymptotic expansion of the generalized Wright Hypergeometric function defined by (see [7, p.21]).
where the coefficients A1, ⋯, Ap and B1, ⋯, Bq are positive real numbers such that
A special case of (1) is
where pFq is the generalized hypergeometric series defined by (see [8, section 1.5])
where (λ)n is called the pochhammer’s symbol [8].
Kiryakova [11] defined the multiple (multiindex) Mittag-Leffler function as follows. Let m > 1 be an integer, ρ1, ⋯ ρm > 0 and μ1, ⋯, μm be arbitrary real numbers. By means of “multiindices” (ρi)(μi), we introduce the so-called multiindex(m-tuple,multiple) Mittag-Leffler functions.
In what follows the relations of (1.2) with some known special functions:
(i) For m=2, if we put and μ1 = 1, μ2 = 1, in (1.2), we have
(ii) For m=2, if we put and μ1 = β, μ2 = 1, in (1.2), we have
(iii) For m=2, if we put and μ1 = v + 1, μ2 = 1 and replacing z by in (1.2), we have (see [11])
where Jv(z) is a Bessel function of first kind (see [8,9]).
(iv) For m=2, if we put and replacing z by in (1.2), we have (see [11])
where Sμ,v(z) is a Struve function (see [8,9]).
(v) For m=2, if we put and replacing z by in (1.2), we have (see [11])
where Hv(z) is a Lommel function (see [8,9]).
In the present investigations, we shall be invoking following relations, see Obhettinger [6].
provided 0 < R(μ) < R(λ).
2. Main results
Two generalized integral formulae, which have been established in this section, are expressed in terms of generalized (Wrigt) hypergeometric function, Multiple Mittag-Leffler, with suitable arguments in the integrands, is invoked in the analysis of the results under investigation.
First Integral
The following integral formula holds true:
Second Integral
The following integral formula holds true:
Proof of (2.1).
In order to derive (2.1), we denote the left- hand side of (2.1) by I, expressing as a series with the help of (1.2) and then interchanging the order of integration and summation, which is justified by uniform convergence of the involved series under the given conditions, we get
Evaluating the above integral with the help of (1.8), we get
Finally, summing the above series with the help of (1.1), we arrive at the right hand side of (2.1). This completes the proof of first result.
Proof of (2.2).
Similarly, to derive (2.2), we denote the left- hand side of (2.2) by I′, expressing as a series with the help of (1.2) and then interchanging the order of integration and summation, which is justified by uniform convergence of the involved series under the given conditions, we get
Evaluating the above integral with the help of (1.8), we get
Finally, summing the above series with the help of (1.1), we arrive at the right hand side of (2.2). This completes the proof of second result.
3. Special Cases
In this section, we define some special cases of our main results:
The above results (3.1) and (3.2) can be established with the help of integrals (2.1) and (2.2) by taking and using equation (1.3).
The above results (3.3) and (3.4) can be established with the help of integrals (2.1) and (2.2) by taking and using equation (1.4).
The above results (3.5) and (3.6) can be established with the help of integrals (2.1) and (2.2) by taking replacing z by and using equation (1.5) (see [11]).
The above results (3.7) and (3.8) can be established with the help of integrals (2.1) and (2.2) by taking replacing z by and using equation (1.6) (see [11]).
The above results (3.9) and (3.10) can be established with the help of integrals (2.1) and (2.2) by taking replacing z by and using equation (1.7).
References
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