Natural orders for asymmetric space--time coding: minimizing the discriminant

TL;DR

This paper explores the construction of algebraic space--time codes for asymmetric MIMO channels, focusing on minimizing the discriminant of the natural order in cyclic division algebras to improve wireless communication performance.

Contribution

It provides explicit pairs of fields and non-norm elements for asymmetric MIMO setups, achieving minimal discriminants in the associated cyclic division algebras.

Findings

Explicit minimal discriminant orders for asymmetric MIMO channels

Construction of cyclic division algebras with optimal properties

Enhanced algebraic framework for space--time coding

Abstract

Algebraic space--time coding --- a powerful technique developed in the context of multiple-input multiple-output (MIMO) wireless communications --- has profited tremendously from tools from Class Field Theory and, more concretely, the theory of central simple algebras and their orders. During the last decade, the study of space--time codes for practical applications, and more recently for future generation (5G+) wireless systems, has provided a practical motivation for the consideration of many interesting mathematical problems. One such problem is the explicit computation of orders of central simple algebras with small discriminants. In this article, we consider the most interesting asymmetric MIMO channel setups and, for each treated case, we provide explicit pairs of fields and a corresponding non-norm element giving rise to a cyclic division algebra whose natural order has the minimum possible discriminant.