Boundary triples and Weyl m-functions for powers of the Jacobi differential operator

Abstract

The abstract theory of boundary triples is applied to the classical Jacobi differential operator and its powers in order to obtain the Weyl m-function for several self-adjoint extensions with interesting boundary conditions: separated, periodic and those that yield the Friedrichs extension. These matrix-valued Nevanlinna–Herglotz m-functions are, to the best knowledge of the author, the first explicit examples to stem from singular higher-order differential equations.The creation of the boundary triples involves taking pieces, determined in [26], of the principal and non-principal solutions of the differential equation and putting them into the sesquilinear form to yield maps from the maximal domain to the boundary space. These maps act like quasi-derivatives, which are usually not well-defined for all functions in the maximal domain of singular expressions. However, well-defined regularizations of quasi-derivatives are produced by putting the pieces of the non-principal solutions through a modified Gram–Schmidt process.