Normal cone (functional analysis)

In mathematics, specifically in order theory and functional analysis, if C is a cone at 0 in a topological vector space X such that 0 ∈ C and if ${\mathcal {U}}$ is the neighborhood filter at the origin, then C is called normal if ${\mathcal {U}}=\left[{\mathcal {U}}\right]_{C}$ , where $\left[{\mathcal {U}}\right]_{C}:=\left\{[U]_{C}:U\in {\mathcal {U}}\right\}$ and where for any subset S of X, [S]_C := (S + C) ∩ (S − C) is the C-saturatation of S.[1]

Normal cones play an important role in the theory of ordered topological vector spaces and topological vector lattices.

Characterizations

If C is a cone in a TVS X then for any subset S of X let $[S]_{C}:=\left(S+C\right)\cap \left(S-C\right)$ be the C-saturated hull of S of X and for any collection ${\mathcal {S}}$ of subsets of X let $\left[{\mathcal {S}}\right]_{C}:=\left\{\left[S\right]_{C}:S\in {\mathcal {S}}\right\}$ . If C is a cone in a TVS X then C is normal if ${\mathcal {U}}=\left[{\mathcal {U}}\right]_{C}$ , where ${\mathcal {U}}$ is the neighborhood filter at the origin.[1]

If ${\mathcal {T}}$ is a collection of subsets of X and if ${\mathcal {F}}$ is a subset of ${\mathcal {T}}$ then ${\mathcal {F}}$ is a fundamental subfamily of ${\mathcal {T}}$ if every $T\in {\mathcal {T}}$ is contained as a subset of some element of ${\mathcal {F}}$ . If ${\mathcal {G}}$ is a family of subsets of a TVS X then a cone C in X is called a ${\mathcal {G}}$ -cone if $\left\{{\overline {\left[G\right]_{C}}}:G\in {\mathcal {G}}\right\}$ is a fundamental subfamily of ${\mathcal {G}}$ and C is a strict ${\mathcal {G}}$ -cone if $\left\{\left[G\right]_{C}:G\in {\mathcal {G}}\right\}$ is a fundamental subfamily of ${\mathcal {G}}$ .[1] Let ${\mathcal {B}}$ denote the family of all bounded subsets of X.

If C is a cone in a TVS X (over the real or complex numbers), then the following are equivalent:[1]

C is a normal cone.
For every filter ${\mathcal {F}}$ in X, if $\lim {\mathcal {F}}=0$ then $\lim \left[{\mathcal {F}}\right]_{C}=0$ .
There exists a neighborhood base ${\mathcal {G}}$ in X such that $B\in {\mathcal {G}}$ implies $\left[B\cap C\right]_{C}\subseteq B$ .

and if X is a vector space over the reals then we may add to this list:[1]

There exists a neighborhood base at the origin consisting of convex, balanced, C-saturated sets.
There exists a generating family ${\mathcal {P}}$ of semi-norms on X such that $p(x)\leq p(x+y)$ for all $x,y\in C$ and $p\in {\mathcal {P}}$ .

and if X is a locally convex space and if the dual cone of C is denoted by $X^{\prime }$ then we may add to this list:[1]

For any equicontinuous subset $S\subseteq X^{\prime }$ , there exists an equicontiuous $B\subseteq C^{\prime }$ such that $S\subseteq B-B$ .
The topology of X is the topology of uniform convergence on the equicontinuous subsets of $C^{\prime }$ .

and if X is an infrabarreled locally convex space and if ${\mathcal {B}}^{\prime }$ is the family of all strongly bounded subsets of $X^{\prime }$ then we may add to this list:[1]

The topology of X is the topology of uniform convergence on strongly bounded subsets of $C^{\prime }$ .
$C^{\prime }$ $\text{[math]}$ is a ${\mathcal {B}}^{\prime }$ $\text{[math]}$ -cone in $X^{\prime }$ $\text{[math]}$ .
- this means that the family $\left\{{\overline {\left[B^{\prime }\right]_{C}}}:B^{\prime }\in {\mathcal {B}}^{\prime }\right\}$ is a fundamental subfamily of ${\mathcal {B}}^{\prime }$ .
$C^{\prime }$ $\text{[math]}$ is a strict ${\mathcal {B}}^{\prime }$ $\text{[math]}$ -cone in $X^{\prime }$ $\text{[math]}$ .
- this means that the family $\left\{\left[B^{\prime }\right]_{C}:B^{\prime }\in {\mathcal {B}}^{\prime }\right\}$ is a fundamental subfamily of ${\mathcal {B}}^{\prime }$ .

and if X is an ordered locally convex TVS over the reals whose positive cone is C, then we may add to this list:

there exists a Hausdorff locally compact topological space S such that X is isomorphic (as an ordered TVS) with a subspace of R(S), where R(S) is the space of all real-valued continuous functions on X under the topology of compact convergence.[2]

If X is a locally convex TVS, C is a cone in X with dual cone $C^{\prime }\subseteq X^{\prime }$ , and ${\mathcal {G}}$ is a saturated family of weakly bounded subsets of $X^{\prime }$ , then[1]

if $C^{\prime }$ is a ${\mathcal {G}}$ -cone then C is a normal cone for the ${\mathcal {G}}$ -topology on X;
if C is a normal cone for a ${\mathcal {G}}$ -topology on X consistent with $\left\langle X,X^{\prime }\right\rangle$ then $C^{\prime }$ is a strict ${\mathcal {G}}$ -cone in $X^{\prime }$ .

If X is a Banach space, C is a closed cone in X,, and ${\mathcal {B}}^{\prime }$ is the family of all bounded subsets of $X_{b}^{\prime }$ then the dual cone $C^{\prime }$ is normal in $X_{b}^{\prime }$ if and only if C is a strict ${\mathcal {B}}$ -cone.[1]

If X is a Banach space and C is a cone in X then the following are equivalent:[1]

C is a ${\mathcal {B}}$ -cone in X;
$X={\overline {C}}-{\overline {C}}$ ;
${\overline {C}}$ is a strict ${\mathcal {B}}$ -cone in X.

Properties

If X is a Hausdorff TVS then every normal cone in X is a proper cone.[1]
If X is a normable space and if C is a normal cone in X then $X^{\prime }=C^{\prime }-C^{\prime }$ .[1]
Suppose that the positive cone of an ordered locally convex TVS X is weakly normal in X and that Y is an ordered locally convex TVS with positive cone D. If Y = D - D then H - H is dense in $L_{s}\left(X;Y\right)$ $\text{[math]}$ where H is the canonical positive cone of $L\left(X;Y\right)$ $\text{[math]}$ and $L_{s}\left(X;Y\right)$ $\text{[math]}$ is the space $L\left(X;Y\right)$ $\text{[math]}$ with the topology of simple convergence.[3]
- If ${\mathcal {G}}$ is a family of bounded subsets of X, then there are apparently no simple conditions guaranteeing that H is a ${\mathcal {T}}$ -cone in $L_{\mathcal {G}}\left(X;Y\right)$ , even for the most common types of families ${\mathcal {T}}$ of bounded subsets of $L_{\mathcal {G}}\left(X;Y\right)$ (except for very special cases).[3]

Sufficient conditions

If the topology on X is locally convex then the closure of a normal cone is a normal cone.[1]

Suppose that $\left\{X_{\alpha }:\alpha \in A\right\}$ is a family of locally convex TVSs and that $C_{\alpha }$ is a cone in $X_{\alpha }$ . If $X:=\bigoplus _{\alpha }X_{\alpha }$ is the locally convex direct sum then the cone $C:=\bigoplus _{\alpha }C_{\alpha }$ is a normal cone in X if and only if each $X_{\alpha }$ is normal in $X_{\alpha }$ .[1]

If X is a locally convex space then the closure of a normal cone is a normal cone.[1]

If C is a cone in a locally convex TVS X and if $C^{\prime }$ is the dual cone of C, then $X^{\prime }=C^{\prime }-C^{\prime }$ if and only if C is weakly normal.[1] Every normal cone in a locally convex TVS is weakly normal.[1] In a normed space, a cone is normal if and only if it is weakly normal.[1]

If X and Y are ordered locally convex TVSs and if ${\mathcal {G}}$ is a family of bounded subsets of X, then if the positive cone of X is a ${\mathcal {G}}$ -cone in X and if the positive cone of Y is a normal cone in Y then the positive cone of $L_{\mathcal {G}}\left(X;Y\right)$ is a normal cone for the ${\mathcal {G}}$ -topology on $L\left(X;Y\right)$ .[4]

References

Schaefer & Wolff 1999, pp. 215–222.
Schaefer & Wolff 1999, pp. 222-225.
Schaefer & Wolff 1999, pp. 225–229.
Schaefer & Wolff 1999, pp. 225-229.

Schaefer, Helmut H.; Wolff, Manfred P. (1999). Topological Vector Spaces. GTM. 3. New York, NY: Springer New York Imprint Springer. ISBN 978-1-4612-7155-0. OCLC 840278135.CS1 maint: ref=harv (link)

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.

[FOOTNOTESchaeferWolff1999215–222-1] Schaefer & Wolff 1999, pp. 215–222.

[FOOTNOTESchaeferWolff1999222-225-2] Schaefer & Wolff 1999, pp. 222-225.

[FOOTNOTESchaeferWolff1999225–229-3] Schaefer & Wolff 1999, pp. 225–229.

[FOOTNOTESchaeferWolff1999225-229-4] Schaefer & Wolff 1999, pp. 225-229.

Functional analysis (topics, glossary)
Spaces	Hilbert space, Banach space, Fréchet space, topological vector space
Theorems	Hahn–Banach theorem, closed graph theorem, uniform boundedness principle, Kakutani fixed-point theorem, Krein–Milman theorem, min-max theorem, Gelfand–Naimark theorem, Banach–Alaoglu theorem
Operators	bounded operator, compact operator, adjoint operator, unitary operator, Hilbert–Schmidt operator, trace class, unbounded operator
Algebras	Banach algebra, C-algebra, spectrum of a C-algebra, operator algebra, group algebra of a locally compact group, von Neumann algebra
Open problems	invariant subspace problem, Mahler's conjecture
Applications	Besov space, Hardy space, spectral theory of ordinary differential equations, heat kernel, index theorem, calculus of variation, functional calculus, integral operator, Jones polynomial, topological quantum field theory, noncommutative geometry, Riemann hypothesis
Advanced topics	locally convex space, approximation property, balanced set, Schwartz space, weak topology, barrelled space, Banach–Mazur distance, Tomita–Takesaki theory

Ordered topological vector spaces
Basic concepts	Ordered topological vector space Ordered vector space Partially ordered space Riesz space Order topology Order unit Topological vector lattice Vector lattice
Types of orders/spaces	AL-space AM-space Archimedean Banach lattice Fréchet lattice Locally convex vector lattice Normed lattice Order bound dual Order dual Order complete Regularly ordered
Types of elements/subsets	Band Cone-saturated Lattice disjoint Dual/Polar cone Normal cone Order complete Order summable Order unit Quasi-interior point Solid set Weak order unit
Topologies/Convergence	Order convergence Order topology
Operators	Positive
Main results	Freudenthal spectral

Normal cone (functional analysis)

Characterizations

Properties

Sufficient conditions

See also

References