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Ordered vector space

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A point x in R2 and the set of all y such that x ≤ y (in red). The order here is x ≤ y if and only if x1y1 and x2y2.

In mathematics, an ordered vector space or partially ordered vector space is a vector space equipped with a partial order that is compatible with the vector space operations.

Definition

Given a vector space X over the real numbers R and a preorder ≤ on the set X, the pair (X, ≤) is called a preordered vector space and we say that the preorder ≤ is compatible with the vector space structure of X and call ≤ a vector preorder on X if for all x, y, z in X and λ in R with λ ≥ 0 the following two axioms are satisfied

  1. xy implies x + zy + z
  2. yx implies λyλx.

If ≤ is a partial order compatible with the vector space structure of X then (X, ≤) is called an ordered vector space and ≤ is called a vector partial order on X. The two axioms imply that translations and positive homotheties are automorphisms of the order structure and the mapping x ↦ −x is an isomorphism to the dual order structure. Ordered vector spaces are ordered groups under their addition operation. Note that xy if and only if −y ≤ −x.

Positive cones and their equivalence to orderings

A subset C of a vector space X is called a cone if for all real r > 0, rC ⊆ C. A cone is called pointed if it contains the origin. A cone C is convex if and only if C + C ⊆ C. The intersection of any non-empty family of cones (resp. convex cones) is again a cone (resp. convex cone); the same is true of the union of an increasing (under set inclusion) family of cones (resp. convex cones). A cone C in a vector space X is said to be generating if X = CC.[1] A positive cone is generating if and only if it is a directed set under ≤.

Given a preordered vector space X, the subset X + of all elements x in (X, ≤) satisfying x ≥ 0 is a pointed convex cone with vertex 0 (i.e. it contains 0) called the positive cone of X and denoted by . The elements of the positive cone are called positive. If x and y are elements of a preordered vector space (X, ≤), then xy if and only if y − xX+. Given any pointed convex cone C with vertex 0, one may define a preorder ≤ on X that is compatible with the vector space structure of X by declaring for all x and y in X, that xy if and only if y − xC; the positive cone of this resulting preordered vector space is C. There is thus a one-to-one correspondence between pointed convex cones with vertex 0 and vector preorders on X.[1] If X is preordered then we may form an equivalence relation on X by defining x is equivalent to y if and only if xy and yx; if N is the equivalence class containing the origin then N is a vector subspace of X and X/N is an ordered vector space under the relation: AB if and only there exist a in A and b in B such that ab.[1]

A subset of C of a vector space X is called a proper cone if it is a convex cone of vertex 0 satisfying C ∩ (−C) = {0}. Explicitly, C is a proper cone if (1) C + C ⊆ C, (2) rC ⊆ C for all r > 0, and (3) C ∩ (−C) = {0}.[2] The intersection of any non-empty family of proper cones is again a proper cone. Each proper cone C in a real vector space induces an order on the vector space by defining xy if and only if y − xC, and furthermore, the positive cone of this ordered vector space will be C. Therefore, there exists a one-to-one correspondence between the proper convex cones of X and the vector partial orders on X.

By a total vector ordering on X we mean a total order on X that is compatible with the vector space structure of X. The family of total vector orderings on a vector space X is in one-to-one correspondence with the family of all proper cones that are maximal under set inclusion.[1] A total vector ordering cannot be Archimedean if its dimension, when considered as a vector space over the reals, is greater than 1.[1]

If R and S are two orderings of a vector space with positive cones P and Q, respectively, then we say that R is finer than S if P ⊆ Q.[2]

Examples

The real numbers with the usual ordering form a totally ordered vector space. For all integers n ≥ 0, the Euclidean space Rn considered as a vector space over the reals with the lexicographic ordering forms a preordered vector space whose order is Archimedean if and only if n = 0 or 1.[3]

Pointwise order

If S is any set and if X is a vector space (over the reals) of real-valued functions on S, then the pointwise order on X is given by, for all f, gX, fg if and only if f(s) ≤ g(s) for all s in S.[3]

Spaces that are typically assigned this order include:

  • the space 𝓁(S, R) of bounded real-valued maps on S.
  • the space c0(R) of real-valued sequences that converge to 0.
  • the space C(S, R) of continuous real-valued functions on a topological space S.
  • for any non-negative integer n, the Euclidean space Rn when considered as the space C({1, …, n}, R) where S = {1, …, n} is given the discrete topology.

The space of all measurable almost-everywhere bounded real-valued maps on R, where the preorder is defined for all f, g by fg if and only if f(s) ≤ g(s) almost everywhere.[3]

Intervals and the order bound dual

An order interval in a preordered vector space is set of the form

[a, b] = {x : axb},
[a, b[ = {x : ax < b},
]a, b] = {x : a < xb}, or
]a, b[ = {x : a < x < b}.

From axioms 1 and 2 above it follows that x, y ∈ [a, b] and 0 < λ < 1 implies λx + (1 − λ)y in [a, b]; thus these order intervals are convex. A subset is said to be order bounded if it is contained in some order interval.[2] In a preordered real vector space, if for x ≥ 0 then the interval of the form [−x, x] is balanced.[2] An order unit of a preordered vector space is any element x such that the set [−x, x] is absorbing.[2]

The set of all linear functionals on a preordered vector space X that map every order interval into a bounded set is called the order bound dual of X and denoted by Xb.[2] If a space is ordered then its order bound dual is a vector subspace of its algebraic dual.

A subset A of an ordered vector space X is called order complete if for every non-empty subset BA such that B is order bounded in A, both and exist and are elements of A. We say that an ordered vector space X is order complete is X is an order complete subset of X.[4]

Examples

If (X, ≤) is a preordered vector space over the reals with order unit u, then the map is a sublinear functional.[3]

Properties

If X is a preordered vector space then for all x, yX,

  • x ≥ 0 and y ≥ 0 imply x + y ≥ 0.[3]
  • xy if and only if −y ≤ −x.[3]
  • xy and r < 0 imply rxry.[3]
  • xy if and only if y = sup{x, y} if and only if x = inf{x, y}.[3]
  • sup{x, y} exists if and only if inf{−x, −y} exists, in which case inf{−x, −y} = −sup{x, y}.[3]
  • sup{x, y} exists if and only if inf{x, y} exists, in which case for all zX,[3]
    • sup{x + z, y + z} = z + sup{x, y}, and
    • inf{x + z, y + z} = z + inf{x, y}
    • x + y = inf{x, y} + sup{x, y}.
  • X is a vector lattice if and only if sup{0, x} exists for all x in X.[3]

Spaces of linear maps

A cone is said to be generating if is equal to the whole vector space.[2] If and are two non-trivial ordered vector spaces with respective positive cones and then is generating in if and only if the set is a proper cone in which is the space of all linear maps from into In this case, the ordering defined by is called the canonical ordering of [2] More generally, if is any vector subspace of such that is a proper cone, the ordering defined by is called the canonical ordering of [2]

Positive functionals and the order dual

A linear function on a preordered vector space is called positive if it satisfies either of the following equivalent conditions:

  1. implies
  2. if then [3]

The set of all positive linear forms on a vector space with positive cone called the dual cone and denoted by is a cone equal to the polar of The preorder induced by the dual cone on the space of linear functionals on is called the dual preorder.[3]

The order dual of an ordered vector space is the set, denoted by defined by Although there do exist ordered vector spaces for which set equality does not hold.[2]

Special types of ordered vector spaces

Let X be an ordered vector space. We say that an ordered vector space X is Archimedean ordered and that the order of X is Archimedean if whenever x in X is such that is majorized (i.e. there exists some y in X such that nxy for all ) then x ≤ 0.[2] A topological vector space (TVS) that is an ordered vector space is necessarily Archimedean if its positive cone is closed.[2]

We say that a preordered vector space X is regularly ordered and that its order is regular if it is Archimedean ordered and X + distinguishes points in X.[2] This property guarantees that there are sufficiently many positive linear forms to be able to successfully use the tools of duality to study ordered vector spaces.[2]

An ordered vector space is called a vector lattice if for all elements x and y, the supremum sup(x, y) and infimum inf(x, y) exist.[2]

Subspaces, quotients, and products

Throughout let X be a preordered vector space with positive cone C.

Subspaces

If M is a vector subspace of X then the canonical ordering on M induced by X's positive cone C is the partial order induced by the pointed convex cone C ∩ M, where this cone is proper if C is proper.[2]

Quotient space

Let M be a vector subspace of an ordered vector space X, be the canonical projection, and let . Then is a cone in X/M that induces a canonical preordering on the quotient space X/M. If is a proper cone in X/M then makes X/M into an ordered vector space.[2] If M is C-saturated then defines the canonical order of X/M.[1] Note that provides an example of an ordered vector space where is not a proper cone.

If X is also a topological vector space (TVS) and if for each neighborhood V of 0 in X there exists a neighborhood U of 0 such that [(U + N) ∩ C] ⊆ V + N then is a normal cone for the quotient topology.[1]

If X is a topological vector lattice and M is a closed solid sublattice of X then X/L is also a topological vector lattice.[1]

Product

If S is any set then the space XS of all functions from S into X is canonically ordered by the proper cone .[2]

Suppose that is a family of preordered vector spaces and that the positive cone of is . Then is a pointed convex cone in , which determines a canonical ordering on ; C is a proper cone if all are proper cones.[2]

Algebraic direct sum

The algebraic direct sum of is a vector subspace of that is given the canonical subspace ordering inherited from .[2] If X1, ..., Xn are ordered vector subspaces of an ordered vector space X then X is the ordered direct sum of these subspaces if the canonical algebraic isomorphism of X onto (with the canonical product order) is an order isomorphism.[2]

Examples

  • The real numbers with the usual order is an ordered vector space.
  • R2 is an ordered vector space with the ≤ relation defined in any of the following ways (in order of increasing strength, i.e., decreasing sets of pairs):
    • Lexicographical order: (a, b) ≤ (c, d) if and only if a < c or (a = c and bd). This is a total order. The positive cone is given by x > 0 or (x = 0 and y ≥ 0), i.e., in polar coordinates, the set of points with the angular coordinate satisfying π/2 < θπ/2, together with the origin.
    • (a, b) ≤ (c, d) if and only if ac and bd (the product order of two copies of R with "≤"). This is a partial order. The positive cone is given by x ≥ 0 and y ≥ 0, i.e., in polar coordinates 0 ≤ θπ/2, together with the origin.
    • (a, b) ≤ (c, d) if and only if (a < c and b < d) or (a = c and b = d) (the reflexive closure of the direct product of two copies of R with "<"). This is also a partial order. The positive cone is given by (x > 0 and y > 0) or (x = y = 0), i.e., in polar coordinates, 0 < θ < π/2, together with the origin.
Only the second order is, as a subset of R4, closed; see partial orders in topological spaces.
For the third order the two-dimensional "intervals" p < x < q are open sets which generate the topology.
  • Rn is an ordered vector space with the ≤ relation defined similarly. For example, for the second order mentioned above:
    • xy if and only if xiyi for i = 1, ..., n.
  • A Riesz space is an ordered vector space where the order gives rise to a lattice.
  • The space of continuous functions on [0, 1] where fg if and only if f(x) ≤ g(x) for all x in [0, 1].

See also

References

  1. ^ a b c d e f g h Schaefer & Wolff 1999, pp. 250–257.
  2. ^ a b c d e f g h i j k l m n o p q r s t u Schaefer & Wolff 1999, pp. 205–209.
  3. ^ a b c d e f g h i j k l m Narici & Beckenstein 2011, pp. 139–153.
  4. ^ Schaefer & Wolff 1999, pp. 204–214.

Bibliography

  • Aliprantis, Charalambos D; Burkinshaw, Owen (2003). Locally solid Riesz spaces with applications to economics (Second ed.). Providence, R. I.: American Mathematical Society. ISBN 0-8218-3408-8.
  • Bourbaki, Nicolas; Elements of Mathematics: Topological Vector Spaces; ISBN 0-387-13627-4.
  • 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. Vol. 8 (Second ed.). New York, NY: Springer New York Imprint Springer. ISBN 978-1-4612-7155-0. OCLC 840278135.
  • Wong (1979). Schwartz spaces, nuclear spaces, and tensor products. Berlin New York: Springer-Verlag. ISBN 3-540-09513-6. OCLC 5126158.