The finite Hankel transform operator: Some explicit and local estimates of the eigenfunctions and eigenvalues decay rates

Abstract

For fixed real numbers c>0, α>-12, the finite Hankel transform operator, denoted by Hcα is given by the integral operator defined on L2(0,1) with kernel Kα(x,y)= c xy Jα(cxy). To the operator Hcα, we associate a positive, self-adjoint compact integral operator Qcα=c\, Hcα\, Hcα. Note that the integral operators Hcα and Qcα commute with a Sturm-Liouville differential operator Dcα. In this paper, we first give some useful estimates and bounds of the eigenfunctions of Hcα or Qcα. These estimates and bounds are obtained by using some special techniques from the theory of Sturm-Liouville operators, that we apply to the differential operator Dcα. If (μn,α(c))n and λn,α(c)=c\, |μn,α(c)|2 denote the infinite and countable sequence of the eigenvalues of the operators Hc(α) and Qcα, arranged in the decreasing order of their magnitude, then we show an unexpected result that for a given integer n≥ 0, λn,α(c) is decreasing with respect to the parameter α. As a consequence, we show that for α≥ 12, the λn,α(c) and the μn,α(c) have a super-exponential decay rate. Also, we give a lower decay rate of these eigenvalues. As it will be seen, the previous results are essential tools for the analysis of a spectral approximation scheme based on the eigenfunctions of the finite Hankel transform operator. Some numerical examples will be provided to illustrate the results of this work.