LF-space

In mathematics, an LF-space is a topological vector space V that is a locally convex inductive limit of a countable inductive system $(V_n, i_{nm})$ of Fréchet spaces. This means that V is a direct limit of the system $(V_n, i_{nm})$ in the category of locally convex topological vector spaces and each $V_n$ is a Fréchet space.

Some authors restrict the term LF-space to mean that V is a strict locally convex inductive limit, which means that the topology induced on $V_n$ by $V_{n+1}$ is identical to the original topology on $V_n$ .^[1]

The topology on V can be described by specifying that an absolutely convex subset U is a neighborhood of 0 if and only if $U \cap V_n$ is an absolutely convex neighborhood of 0 in $V_n$ for every n.

Properties

An LF-space is barrelled and bornological (and thus ultrabornological).

Examples

A typical example of an LF-space is, $C^\infty_c(\mathbb{R}^n)$ , the space of all infinitely differentiable functions on $\mathbb{R}^n$ with compact support. The LF-space structure is obtained by considering a sequence of compact sets $K_1 \subset K_2 \subset \ldots \subset K_i \subset \ldots \subset \mathbb{R}^n$ with $\bigcup_i K_i = \mathbb{R}^n$ and for all i, $K_i$ is a subset of the interior of $K_{i+1}$ . Such a sequence could be the balls of radius i centered at the origin. The space $C_c^\infty(K_i)$ of infinitely differentiable functions on $\mathbb{R}^n$ with compact support contained in $K_i$ has a natural Fréchet space structure and $C^\infty_c(\mathbb{R}^n)$ inherits its LF-space structure as described above. The LF-space topology does not depend on the particular sequence of compact sets $K_i$ .

With this LF-space structure, $C^\infty_c(\mathbb{R}^n)$ is known as the space of test functions, of fundamental importance in the theory of distributions.

References

↑ Helgason, Sigurdur (2000). Groups and geometric analysis : integral geometry, invariant differential operators, and spherical functions (Reprinted with corr. ed.). Providence, R.I: American Mathematical Society. p. 398. ISBN 0-8218-2673-5.

Treves, François (1967), Topological Vector Spaces, Distributions and Kernels, Academic Press, pp. 126 ff .

Functional analysis

Set / subset types	Absolutely convex Absorbing Balanced Bounded Convex Radial Star-shaped Symmetric Linear cone (subset) Convex cone (subset)

TVS types	Banach Barrelled Bornological Brauner F-space Finite-dimensional Fréchet (tame) Hilbert LF-space Locally convex Mackey Montel Nuclear Normed (norm) Quasinormed Reflexive Riesz Smith Stereotype Webbed Topological tensor product (of Hilbert spaces)

Mapping topologies	Dual Dual space Operator Strong (polar operator) Ultrastrong Weak (operator) Ultraweak Uniform convergence

Linear operators	Adjoint Bilinear (form) Bounded / Unbounded Closed Continuous / Discontinuous Compact Fredholm Hilbert–Schmidt Functionals (positive) Normal Nuclear Self-adjoint Strictly singular Trace class Transpose Unitary

Set operations	Algebraic interior (core) Interior Minkowski addition Polar

Banach algebras	C-algebras Spectrum (C-algebra radius) Spectral theory

Theorems	Banach–Alaoglu Banach–Saks Banach–Mazur Bessel's inequality Cauchy–Schwarz inequality Closed range Closed graph Eberlein–Šmulian Freudenthal spectral Gelfand–Mazur Goldstine Hahn–Banach (hyperplane separation) Kakutani fixed-point Lomonosov's invariant subspace Mackey–Arens Mazur's lemma M. Riesz extension Open mapping Parseval's identity Schauder fixed-point

Analysis	Bochner space Differentiation in Fréchet spaces Derivatives (Fréchet Gâteaux functional holomorphic) Integrals (Bochner Dunford Gelfand–Pettis regulated weak) Functional calculus (Borel continuous holomorphic) Inverse function theorem (Nash–Moser theorem) Vector measure

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