Approximation theorems for group valued functions.
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Título
Approximation theorems for group valued functions.Fecha de publicación
2011-02Editor
© ElsevierISSN
0021-9045Tipo de documento
info:eu-repo/semantics/articleVersión de la editorial
http://www.sciencedirect.com/science/article/pii/S002190451000153XVersión
info:eu-repo/semantics/publishedVersionPalabras clave / Materias
Resumen
Stone–Weierstrass-type theorems for groups of group-valued functions with a discrete range or a discrete domain are obtained. We study criteria for a subgroup of the group of continuous functions C(X,G) (X compact, G ... [+]
Stone–Weierstrass-type theorems for groups of group-valued functions with a discrete range or a discrete domain are obtained. We study criteria for a subgroup of the group of continuous functions C(X,G) (X compact, G a topological group) to be uniformly dense. These criteria are based on the existence of so-called condensing functions, where a continuous function ϕ:G→G is said to be condensing (respectively, finitely condensing) if it does not operate on any proper, point separating, closed subgroup of C(K,G), with K compact, (respectively, with K finite) that contains the constant functions.
The set DF(G) of finitely condensing functions in C(G,G), is characterized, for any Abelian topological group G, as the set of those functions that are both non-affine and do not have nontrivial generalized periods (i.e. that do not factorize through nontrivial quotients of G). This provides approximation theorems for functions with discrete domain and arbitrary (topological group) range.
We also show that when G is discrete, every finitely condensing functions is condensing. The set of D(G) of condensing functions is thus characterized for discrete Abelian G. This provides approximation theorems for functions with an arbitrary (compact) domain and a discrete range. Answering an old question of Sternfeld, the description of D(Z) that follows is particularly simple: given ϕ:Z→Z, ϕ∈D(Z) if and only if for every k∈N with k≥2, there are n1,n2∈Z such that n1−n2 is a multiple of k, while ϕ(n1)−ϕ(n2) is not. [-]
Publicado en
Journal of Approximation Theory (February 2011), vol. 163, no. 2, 183-196Derechos de acceso
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