On the singular value decomposition of n-fold integration operators

Abstract

In theory and practice of inverse problems, linear operator equations Tx=y with compact linear forward operators T having a non-closed range R(T) and mapping between infinite dimensional Hilbert spaces plays some prominent role. As a consequence of the ill-posedness of such problems, regularization approaches are required, and due to its unlimited qualification spectral cut-off is an appropriate method for the stable approximate solution of corresponding inverse problems. For this method, however, the singular system \σi(T),ui(T),vi(T)\i=1∞ of the compact operator T is needed, at least for i=1,2,...,N, up to some stopping index N. In this note we consider n-fold integration operators T=Jn\;(n=1,2,...) in L2([0,1]) occurring in numerous applications, where the solution of the associated operator equation is characterized by the n-th generalized derivative x=y(n) of the Sobolev space function y ∈ Hn([0,1]). Almost all textbooks on linear inverse problems present the whole singular system \σi(J1),ui(J1),vi(J1)\i=1∞ in an explicit manner. However, they do not discuss the singular systems for Jn,\;n 2. We will emphasize that this seems to be a consequence of the fact that for higher n the eigenvalues σ2i(Jn) of the associated ODE boundary value problems obey transcendental equations, the complexity of which is growing with n. We present the transcendental equations for n=2,3,... and discuss and illustrate the associated eigenfunctions and some of their properties.