Brauner space

In functional analysis and related areas of mathematics a Brauner space is a complete compactly generated locally convex space $X$ having a sequence of compact sets $K_{n}$ such that every other compact set $T\subseteq X$ is contained in some $K_{n}$ .

Brauner spaces are named after Kalman George Brauner, who began their study.^[1] All Brauner spaces are stereotype and are in the stereotype duality relations with Fréchet spaces:^[2]^[3]

for any Fréchet space $X$ its stereotype dual space^[4] $X^{\star }$ is a Brauner space,
and vice versa, for any Brauner space $X$ its stereotype dual space $X^{\star }$ is a Fréchet space.

Special cases of Brauner spaces are Smith spaces.

Examples

Let $M$ be a $\sigma$ -compact locally compact topological space, and ${\mathcal {C}}(M)$ the Fréchet space of all continuous functions on $M$ (with values in ${\mathbb {R} }$ or ${\mathbb {C} }$ ), endowed with the usual topology of uniform convergence on compact sets in $M$ . The dual space ${\mathcal {C}}^{\star }(M)$ of Radon measures with compact support on $M$ with the topology of uniform convergence on compact sets in ${\mathcal {C}}(M)$ is a Brauner space.
Let $M$ be a smooth manifold, and ${\mathcal {E}}(M)$ the Fréchet space of all smooth functions on $M$ (with values in ${\mathbb {R} }$ or ${\mathbb {C} }$ ), endowed with the usual topology of uniform convergence with each derivative on compact sets in $M$ . The dual space ${\mathcal {E}}^{\star }(M)$ of distributions with compact support in $M$ with the topology of uniform convergence on bounded sets in ${\mathcal {E}}(M)$ is a Brauner space.
Let $M$ be a Stein manifold and ${\mathcal {O}}(M)$ the Fréchet space of all holomorphic functions on $M$ with the usual topology of uniform convergence on compact sets in $M$ . The dual space ${\mathcal {O}}^{\star }(M)$ of analytic functionals on $M$ with the topology of uniform convergence on bounded sets in ${\mathcal {O}}(M)$ is a Brauner space.

In the special case when $M=G$ possesses a structure of a topological group the spaces ${\mathcal {C}}^{\star }(G)$ , ${\mathcal {E}}^{\star }(G)$ , ${\mathcal {O}}^{\star }(G)$ become natural examples of stereotype group algebras.

Let $M\subseteq {\mathbb {C} }^{n}$ be a complex affine algebraic variety. The space ${\mathcal {P}}(M)={\mathbb {C} }[x_{1},...,x_{n}]/\{f\in {\mathbb {C} }[x_{1},...,x_{n}]:\ f{\big |}_{M}=0\}$ of polynomials (or regular functions) on $M$ , being endowed with the strongest locally convex topology, becomes a Brauner space. Its stereotype dual space ${\mathcal {P}}^{\star }(M)$ (of currents on $M$ ) is a Fréchet space. In the special case when $M=G$ is an affine algebraic group, ${\mathcal {P}}^{\star }(G)$ becomes an example of a stereotype group algebra.
Let $G$ be a compactly generated Stein group.^[5] The space ${\mathcal {O}}_{\exp }(G)$ of all holomorphic functions of exponential type on $G$ is a Brauner space with respect to a natural topology.^[6]

Notes

^ Brauner 1973.
^ Akbarov 2003, p. 220.
^ Akbarov 2009, p. 466.
^ The stereotype dual space to a locally convex space $X$ is the space $X^{\star }$ of all linear continuous functionals $f:X\to \mathbb {C}$ endowed with the topology of uniform convergence on totally bounded sets in $X$ .
^ I.e. a Stein manifold which is at the same time a topological group.
^ Akbarov 2009, p. 525.

References

Brauner, K. (1973). "Duals of Fréchet spaces and a generalization of the Banach-Dieudonné theorem". Duke Mathematical Journal. 40 (4): 845–855. doi:10.1215/S0012-7094-73-04078-7.
Akbarov, S.S. (2003). "Pontryagin duality in the theory of topological vector spaces and in topological algebra". Journal of Mathematical Sciences. 113 (2): 179–349. doi:10.1023/A:1020929201133. S2CID 115297067.
Akbarov, S.S. (2009). "Holomorphic functions of exponential type and duality for Stein groups with algebraic connected component of identity". Journal of Mathematical Sciences. 162 (4): 459–586. arXiv:0806.3205. doi:10.1007/s10958-009-9646-1. S2CID 115153766.

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