- Source: Category of topological vector spaces
In mathematics, the category of topological vector spaces is the category whose objects are topological vector spaces and whose morphisms are continuous linear maps between them. This is a category because the composition of two continuous linear maps is again a continuous linear map. The category is often denoted TVect or TVS.
Fixing a topological field K, one can also consider the subcategory TVectK of topological vector spaces over K with continuous K-linear maps as the morphisms.
TVect is a concrete category
Like many categories, the category TVect is a concrete category, meaning its objects are sets with additional structure (i.e. a vector space structure and a topology) and its morphisms are functions preserving this structure. There are obvious forgetful functors into the category of topological spaces, the category of vector spaces and the category of sets.
TVect
K
{\displaystyle K}
is a topological category
The category is topological, which means loosely speaking that it relates to its "underlying category", the category of vector spaces, in the same way that Top relates to Set. Formally, for every K-vector space
V
{\displaystyle V}
and every family
(
(
V
i
,
τ
i
)
,
f
i
)
i
∈
I
{\displaystyle ((V_{i},\tau _{i}),f_{i})_{i\in I}}
of topological K-vector spaces
(
V
i
,
τ
i
)
{\displaystyle (V_{i},\tau _{i})}
and K-linear maps
f
i
:
V
→
V
i
,
{\displaystyle f_{i}:V\to V_{i},}
there exists a vector space topology
τ
{\displaystyle \tau }
on
V
{\displaystyle V}
so that the following property is fulfilled:
Whenever
g
:
Z
→
V
{\displaystyle g:Z\to V}
is a K-linear map from a topological K-vector space
(
Z
,
σ
)
,
{\displaystyle (Z,\sigma ),}
it holds that
g
:
(
Z
,
σ
)
→
(
V
,
τ
)
{\displaystyle g:(Z,\sigma )\to (V,\tau )}
is continuous
⟺
{\displaystyle \iff }
∀
i
∈
I
:
f
i
∘
g
:
(
Z
,
σ
)
→
(
V
i
,
τ
i
)
{\displaystyle \forall i\in I:f_{i}\circ g:(Z,\sigma )\to (V_{i},\tau _{i})}
is continuous.
The topological vector space
(
V
,
τ
)
{\displaystyle (V,\tau )}
is called "initial object" or "initial structure" with respect to the given data.
If one replaces "vector space" by "set" and "linear map" by "map", one gets a characterisation of the usual initial topologies in Top. This is the reason why categories with this property are called "topological".
There are numerous consequences of this property. For example:
"Discrete" and "indiscrete" objects exist. A topological vector space is indiscrete iff it is the initial structure with respect to the empty family. A topological vector space is discrete iff it is the initial structure with respect to the family of all possible linear maps into all topological vector spaces. (This family is a proper class, but that does not matter: Initial structures with respect to all classes exists iff they exists with respect to all sets)
Final structures (the similar defined analogue to final topologies) exist. But there is a catch: While the initial structure of the above property is in fact the usual initial topology on
V
{\displaystyle V}
with respect to
(
τ
i
,
f
i
)
i
∈
I
{\displaystyle (\tau _{i},f_{i})_{i\in I}}
, the final structures do not need to be final with respect to given maps in the sense of Top. For example: The discrete objects (= final with respect to the empty family) in
TVect
K
{\displaystyle {\textbf {TVect}}_{K}}
do not carry the discrete topology.
Since the following diagram of forgetful functors commutes
Vect
K
→
Set
↑
↑
TVect
K
→
Top
{\displaystyle {\begin{array}{ccc}{\textbf {Vect}}_{K}&\rightarrow &{\textbf {Set}}\\\uparrow &&\uparrow \\{\textbf {TVect}}_{K}&\rightarrow &{\textbf {Top}}\end{array}}}
and the forgetful functor from
Vect
K
{\displaystyle {\textbf {Vect}}_{K}}
to Set is right adjoint, the forgetful functor from
TVect
K
{\displaystyle {\textbf {TVect}}_{K}}
to Top is right adjoint too (and the corresponding left adjoints fit in an analogue commutative diagram). This left adjoint defines "free topological vector spaces". Explicitly these are free K-vector spaces equipped with a certain initial topology.
Since
Vect
K
{\displaystyle {\textbf {Vect}}_{K}}
is (co)complete,
TVect
K
{\displaystyle {\textbf {TVect}}_{K}}
is (co)complete too.
See also
Category of groups – category of groups and group homomorphismsPages displaying wikidata descriptions as a fallback
Category of metric spaces – mathematical category with metric spaces as its objects and distance-non-increasing maps as its morphismsPages displaying wikidata descriptions as a fallback
Category of sets – Category in mathematics where the objects are sets
Category of topological spaces – category whose objects are topological spaces and whose morphisms are continuous mapsPages displaying wikidata descriptions as a fallback
Category of topological spaces with base point – Topological space with a distinguished pointPages displaying short descriptions of redirect targets
References
Lang, Serge (1972). Differential manifolds. Reading, Mass.–London–Don Mills, Ont.: Addison-Wesley Publishing Co., Inc.
Kata Kunci Pencarian:
- Limit langsung
- Topological vector space
- Category of topological spaces
- Category of topological vector spaces
- Locally convex topological vector space
- Direct sum
- Bounded set (topological vector space)
- Pointed space
- Normed vector space
- Fréchet space
- Complemented subspace