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Main Authors: Oertel, Alexander, Schürmann, Achill
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.05841
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author Oertel, Alexander
Schürmann, Achill
author_facet Oertel, Alexander
Schürmann, Achill
contents We generalize Voronoi's theory of perfect quadratic forms to generalized copositive matrices over a closed convex and full-dimensional cone K. We introduce a notion of a K-copositive minimum and of perfect K-copositive matrices. We consider a key feature of a given cone, which we call Interior Ryshkov (IR) property. Under this property the classical theory and its applications generalize nicely and we prove that rationally generated cones possess this IR property. For contrast, we give a detailed example of a simple cone without the IR property, showing various differences to the classical case. Moreover, this example yields connections to questions of number theory, in particular to Diophantine approximation and the Pell Equation. Finally, as an application, we give inner and outer polyhedral approximations for the generalized completely positive cone and a method to find rational certificates for (non-)membership in this cone.
format Preprint
id arxiv_https___arxiv_org_abs_2602_05841
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Generalized Perfect Matrices
Oertel, Alexander
Schürmann, Achill
Metric Geometry
Number Theory
11H55, 52B70 (Primary), 11D09, 11J04, 90C20 (Secondary)
We generalize Voronoi's theory of perfect quadratic forms to generalized copositive matrices over a closed convex and full-dimensional cone K. We introduce a notion of a K-copositive minimum and of perfect K-copositive matrices. We consider a key feature of a given cone, which we call Interior Ryshkov (IR) property. Under this property the classical theory and its applications generalize nicely and we prove that rationally generated cones possess this IR property. For contrast, we give a detailed example of a simple cone without the IR property, showing various differences to the classical case. Moreover, this example yields connections to questions of number theory, in particular to Diophantine approximation and the Pell Equation. Finally, as an application, we give inner and outer polyhedral approximations for the generalized completely positive cone and a method to find rational certificates for (non-)membership in this cone.
title Generalized Perfect Matrices
topic Metric Geometry
Number Theory
11H55, 52B70 (Primary), 11D09, 11J04, 90C20 (Secondary)
url https://arxiv.org/abs/2602.05841