order unit

An order unit is an element of an ordered vector space which can be used to bound all elements from above.{{cite book|title=Convex Cones|last1=Fuchssteiner|first1=Benno|last2=Lusky|first2=Wolfgang|isbn=9780444862907|publisher=Elsevier|year=1981}} In this way (as seen in the first example below) the order unit generalizes the unit element in the reals.

According to H. H. Schaefer, "most of the ordered vector spaces occurring in analysis do not have order units."{{sfn|Schaefer|Wolff|1999|pp=230–234}}

Definition

For the ordering cone $K \subseteq X$ in the vector space $X$ , the element $e \in K$ is an order unit (more precisely a $K$ -order unit) if for every $x \in X$ there exists a $\lambda_x > 0$ such that $\lambda_x e - x \in K$ (that is, $x \leq_K \lambda_x e$ ).{{cite book|author=Charalambos D. Aliprantis|author2=Rabee Tourky|title=Cones and Duality|isbn=9780821841464|publisher=American Mathematical Society|year=2007}}

= Equivalent definition =

The order units of an ordering cone $K \subseteq X$ are those elements in the algebraic interior of $K;$ that is, given by $\operatorname{core}(K).$

Examples

Let $X = \R$ be the real numbers and $K = \R_+ = \{x \in \R : x \geq 0\},$ then the unit element $1$ is an {{em|order unit}}.

Let $X = \R^n$ and $K = \R^n_+ = \left\{ x_i \in \R : \text{ for all } i = 1, \ldots, n : x_i \geq 0 \right\},$ then the unit element $\vec{1} = (1, \ldots, 1)$ is an {{em|order unit}}.

Each interior point of the positive cone of an ordered topological vector space is an order unit.{{sfn|Schaefer|Wolff|1999|pp=230–234}}

Properties

Each order unit of an ordered TVS is interior to the positive cone for the order topology.{{sfn|Schaefer|Wolff|1999|pp=230–234}}

If $(X, \leq)$ is a preordered vector space over the reals with order unit $u,$ then the map $p(x) := \inf \{ t \in \R : x \leq t u \}$ is a sublinear functional.{{sfn|Narici|Beckenstein|2011|pp=139-153}}

Order unit norm

Suppose $(X, \leq)$ is an ordered vector space over the reals with order unit $u$ whose order is Archimedean and let $U = [-u, u].$

Then the Minkowski functional $p_U$ of $U,$ defined by $p_{U}(x) := \inf \{ r > 0 : x \in r [-u, u] \},$ is a norm called the {{visible anchor|order unit norm}}.

It satisfies $p_U(u) = 1$ and the closed unit ball determined by $p_U$ is equal to $[-u, u];$ that is, $[-u, u] = \left\{ x \in X : p_U(x) \leq 1 \right\}.$ {{sfn|Narici|Beckenstein|2011|pp=139-153}}

References

Bibliography

{{Narici Beckenstein Topological Vector Spaces|edition=2}}
{{Schaefer Wolff Topological Vector Spaces|edition=2}}

Category:Mathematical analysis

Category:Topology