Inversion of a Class of Singular Integral Operators on Entire Functions

Abstract

Given constants x, ∈ C and the space H0 of entire functions in C vanishing at 0, we consider the integro-differential operator L = ( x \, (1-)1-x ) \; δ M\, , with δ = z \, d/dz and M:H0 → H0 defined by Mf(z) = ∫01 e-z t-(1-(1-x)t) \, f (z \, t-(1-t) ) \, dtt, z ∈ C, for any f ∈ H0. Operator L originates from an inversion problem in Queuing Theory. Bringing the inversion of L back to that of M translates into a singular Volterra integral equation, but with no explicit kernel. In this paper, the inverse of operator L is derived through a new inversion formula recently obtained for infinite matrices with entries involving Hypergeometric polynomials. For x R- \1\ and Re() < 0, we then show that the inverse L-1 of L on H0 has the integral representation L-1g(z) = 1-x2iπ x \, ez ∫1(0+) e-xtzt(t-1) \, g (z \, (-t)(1-t)1- ) \, dt, z ∈ C, for any g ∈ H0, where the bounded integration contour in the complex plane starts at point 1 and encircles the point 0 in the positive sense. Other related integral representations of L-1 are also provided.

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