Invertible bases and root vectors for analytic matrix-valued functions

Abstract

We revisit the concept of a minimal basis through the lens of the theory of modules over a commutative ring R. We first review the conditions for the existence of a basis for submodules of Rn where R is a B\'ezout domain. Then, we define the concept of invertible basis of a submodule of Rn and, when R is an elementary divisor domain, we link it to the Main Theorem of [G. D. Forney Jr., SIAM J. Control 13, 493--520, 1975]. Over an elementary divisor domain, the submodules admitting an invertible basis are precisely the free pure submodules of Rn. As an application, we let ⊂eq C be either a connected compact set or a connected open set, and we specialize to R=A, the ring of functions that are analytic on . We show that, for any matrix A(z) ∈ Am × n, ker \ A(z) An is a free A-module and admits an invertible basis, or equivalently a basis that is full rank upon evaluation at any λ ∈ . Finally, given λ ∈ , we use invertible bases to define and study maximal sets of root vectors at λ for A(z). This in particular allows us to define eigenvectors also for analytic matrices that do not have full column rank.