English

Root functions of a meromorphic matrix function and applications

Complex Variables 2025-10-22 v2 Functional Analysis

Abstract

A practical method is presented for determining root and pole cancellation functions of a matrix function Q(z)Q(z) meromorphic on the extended complex plane Cˉ:=C{}\bar{\mathbb{C}}:=\mathbb{C} \cup \left\{ \infty \right\}. This method is applied to solve a nonlinear system of nNn\in \mathbb{N} differential equations of order lNl\in \mathbb{N} with nn unknown functions ui(t)u_{i}\left( t \right), where i=1,,ni=1,\, \mathellipsis ,\,n . For a function QNκ(H),κN{0}Q\in \mathcal{N}_{\kappa}(\mathcal{H}) ,\, \kappa \in \mathbb{N} \cup \lbrace 0 \rbrace, posesing a pole at infinity of order mNm \in \mathbb{N}, the following factorization is establish Q(z)=(zβ)mQ~(z),zD(Q), Q(z)=(z-\beta)^{m}\tilde{Q}(z), \, z\in \mathcal{D}(Q), where βR\beta \in \mathbb{R} is a regular point of QQ, and Q~Nκ(H)\tilde{Q}\in \mathcal{N}_{\kappa'}(\mathcal{H}) is holomotphic at \infty. Unlike the Krein-Langer representation of QQ, which involves a linear relation AA, this representation employs a bounded operator A~\tilde{A} in the Krein-Langer representation of Q~\tilde{Q}. The operator A~\tilde{A} and the relation AA have identical spectra, except at β\beta and \infty. We demonstrate how to obtain this representation for a given meromorphic function QNκn×nQ\in \mathcal{N}_{\kappa}^{n \times n} using the root functions developed in this work.

Keywords

Cite

@article{arxiv.2505.06812,
  title  = {Root functions of a meromorphic matrix function and applications},
  author = {Muhamed Borogovac},
  journal= {arXiv preprint arXiv:2505.06812},
  year   = {2025}
}

Comments

20 pages

R2 v1 2026-06-28T23:28:24.112Z