Distance structures for generalized metric spaces
Abstract
Let be an algebraic structure, where is a commutative binary operation with identity , and is a translation-invariant total order with least element . Given a distinguished subset , we define the natural notion of a "generalized" -metric space, with distances in . We study such metric spaces as first-order structures in a relational language consisting of a distance inequality for each element of . We first construct an ordered additive structure on the space of quantifier-free -types consistent with the axioms of -metric spaces with distances in , and show that, if is an -metric space with distances in , then any model of logically inherits a canonical -metric. Our primary application of this framework concerns countable, universal, and homogeneous metric spaces, obtained as generalizations of the rational Urysohn space. We adapt previous work of Delhomm\'{e}, Laflamme, Pouzet, and Sauer to fully characterize the existence of such spaces. We then fix a countable totally ordered commutative monoid , with least element , and consider , the countable Urysohn space over . We show that quantifier elimination for is characterized by continuity of addition in , which can be expressed as a first-order sentence of in the language of ordered monoids. Finally, we analyze an example of Casanovas and Wagner in this context.
Cite
@article{arxiv.1502.05002,
title = {Distance structures for generalized metric spaces},
author = {Gabriel Conant},
journal= {arXiv preprint arXiv:1502.05002},
year = {2018}
}
Comments
30 pages