Order topology (functional analysis)

The family of all locally convex topologies on X for which every order interval is bounded is non-empty (since it contains the coarsest possible topology on X) and the order topology is the upper bound of this family.[1]

A subset of X is a neighborhood of 0 in the order topology if and only if it is convex and absorbs every order interval in X.[1] Note that a neighborhood of 0 in the order topology is necessarily absorbing since [x, x] = { x } for all x in X.[1]

For every a ≥ 0, let ${\displaystyle X_{a}=\cup _{n=1}^{\infty }n[-a,a]}$ and endow X_a with its order topology (which makes it into a normable space). The set of all X_a's is directed under inclusion and if X_a ⊆ X_b then the natural inclusion of X_a into X_b is continuous. If X is a regularly ordered vector space over the reals and if H is any subset of the positive cone C of X that is cofinal in C (e.g. H could be C), then X with its order topology is the inductive limit of ${\displaystyle \left\{X_{a}:a\geq 0\right\}}$ (where the bonding maps are the natural inclusions).[3]

The lattice structure can compensate in part for any lack of an order unit:

Theorem:[3] Let X be a vector lattice with a regular order and let C denote its positive cone. Then the order topology on X is the finest locally convex topology on X for which C is a normal cone; it is also the same as the Mackey topology induced on X with respect to the duality ${\displaystyle \left\langle X,X^{+}\right\rangle }$.

In particular, if ${\displaystyle (X,\tau )}$ is an ordered Fréchet lattice over the real numbers then ${\displaystyle \tau }$ is the ordered topology on X if and only if the positive cone of X is a normal cone in ${\displaystyle (X,\tau )}$.[3]

If X is a regularly ordered vector lattice then the ordered topology is the finest locally convex TVS topology on X making X into a locally convex vector lattice. If in addition X is order complete then X with the order topology is a barreled space and every band decomposition of X is a topological direct sum for this topology.[3] In particular, if the order of a vector lattice X is regular then the order topology is generated by the family of all lattice seminorms on X.[3]

Throughout we let (X, ≤) be an ordered vector space and we let 𝜏_≤ denote the order topology on X.

• The dual of (X, 𝜏_≤) is the order bound dual X^b of X.[3]
• If X^b separates points in X (such as if (X, ≤) is regular) then (X, 𝜏_≤) is a bornological locally convex TVS.[3]
• Each positive linear operator between two ordered vector spaces is continuous for the respective order topologies.[3]
• Each order unit of an ordered TVS is interior to the positive cone for the order topology.[3]
• If the order of an ordered vector space X is a regular order and if each positive sequence of type ${\displaystyle l^{1}}$ in X is order summable, then X endowed with its order topology is a barreled space.[3]
• If the order of an ordered vector space X is a regular order and if for all x ≥ 0 and y ≥ 0 we have [0, x] + [0, y] = [0, x + y] then the positive cone of X is a normal cone in X when X is endowed with the order topology.[3]
  • In particular, the continuous dual space of X with the order topology will be the order dual X⁺.
• If (X, ≤) is an Archimedean ordered vector space over the real numbers having an order unit and let 𝜏_≤ denote the order topology on X. Then (X, 𝜏_≤) is an ordered TVS that is normable, 𝜏_≤ is the finest locally convex TVS topology on X such that the positive cone is normal, and the following are equivalent:[3]

1. (X, 𝜏_≤) is complete.
2. Each positive sequence of type ${\displaystyle l^{1}}$ in X is order summable.

• In particular, if (X, ≤) is an Archimedean ordered vector space having an order unit then the order ≤ is a regular order and X^b = X⁺.[3]
• If X is a Banach space and an ordered vector space with an order unit then X's topological is identical to the order topology if and only if the positive cone of X is a normal cone in X.[3]
• A vector lattice homomorphism from X into Y is a topological homomorphism when X and Y are given their respective order topology (functional analysis)|order topologies.[4]

If M is a solid vector subspace of a vector lattice X, then the order topology of X/M is the quotient of the order topology on X.[4]

• The order topology of a finite product of ordered vector spaces (this product having its canonical order) is identical to the product topology of the topological product of the constituent ordered vector spaces (when each is given its order topology).[3]

• Ordered topological vector space
• Ordered vector space
• Vector lattice

• Narici, Lawrence; Beckenstein, Edward (2011). Topological Vector Spaces. Pure and applied mathematics (Second ed.). Boca Raton, FL: CRC Press. ISBN 978-1584888666. OCLC 144216834.
• Schaefer, Helmut H.; Wolff, Manfred P. (1999). Topological Vector Spaces. GTM. 8 (Second ed.). New York, NY: Springer New York Imprint Springer. ISBN 978-1-4612-7155-0. OCLC 840278135.CS1 maint: ref=harv (link)