Inverse-producing extensions of Topological Algebras/topological algebra

Definition: Topological Vector Space

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A topological vector space   over   is a vector space over the field   that has a topology with which scalar multiplication and addition are continuous mappings.

 

In the following, for all topological vector spaces, we shall use the Hausdorff property be assumed.

Definition: Neighbourhood

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Let   be a topological space with a topology   as a system of open sets   and  , then denote

  •   the set of all neighbourhoods from the point  ,
  •   the set of all open Neighbourhoods from the point  ,
  •   the set of all closed neighbourhoods of point  .

Remark: Indexing with topology

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If no misunderstanding about the underlying topological space can occur, the index   is not included as a designation of the topology used.

Remark: Analogy to the epsilon neighbourhood

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In convergence statements in the real numbers one usually considers only   neighbourhood. In doing so, one would actually have to consider in topological spaces for arbitrary neighbourhoods from   find an index bound   of a net   above which all   lie with  . However, since the   neighbourhoods are an neighbourhood basis, by the convergence definition one only needs to show the property for all neighbourhoods with  .

Convergence in topological spaces

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Let   be a topological space,  ,   an index set (partial order) and   a mesh. The convergence of   against   is then defined as follows:

 .

(where " " for   is the partial order on the index set).

Definiton: Neighbourhood basis

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Let   be a topological space,   and   the set of all neighbourhoods of  .   is called the neighbourhood basis of   if for every : .

Remark: Epsilon spheres in normalized spaces

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Let   be a normed space, then the   spheres form

 

an ambient basis of   the set of all environments of   of  .

Learning Task 1

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Let   be a toplogic space with chaotic topology  .

  • Determine   for any  .
  • Show that any sequence   converges in   against any limit  .

Learning Task 2

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Let   be a metric space with the discrete topology given by the metric:

 .
  • Determine   for any  .
  • How many sets make up   minimal for any  ?
  • Formally state all sequences   in   that converge to a limit  !

Definition: open sets

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Let   be a topological space and   be the system of open sets, that is:

 .

Task

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Let   be a topological space on the basic set of real numbers. However, the topology does not correspond to the Euclic topology over the set  , but the open sets are defined as follows.

 
  • Show that   is a topological space.
  • Show that the sequence   does not converge to   in the topological space  .

Here   is the complement of   in  .

Remark: open - closed

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By the system of open sets in a topology   the closed sets of the topology are also defined at the same time as their complements.

Definition: closed sets

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Let   be a topological space and   be the system of open sets.

 

Definition: open kernel

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Let   be a topological space and  , then the open kernel   of   is the union of all open subsets of  .

 .

Definition: closed hull

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Let   be a topological space. The closed hull   of   is the intersection over all closed subsets of   containing   and   is open.

 

Definition: edge of a set

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The topological edge   of   is defined as follows:

 

Remark: sequences and nets

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In metric spaces, one can still work with the natural numbers as countable index sets. In arbitrary topological spaces one has to generalize the notion of sequences to the notion of nets.

Definition: nets

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Let   be a topological space and   an index set (with partial order), then   denotes the set of all families indexed by   in  :

 

Definition: finite sequences

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Let   be a vector space, then   denotes the set of all finite sequences with elements in  :

 


Definition: Algebra

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An algebra   over the field   is a vector space over   in which a multiplication is an inner join

 

is defined where for all   and   the following properties are satisfied:

 

Definition: topological algebra

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A topological algebra   over the field   is a topological vector space   over  , where also multiplication is

 

is a continuous inner knotting.

Continuity of multiplication

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Continuity of multiplication means here:

 

Multiplicative topology - continuity

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The topology is called multiplicative if holds:

 

Remark: Multiplicative topology - Gaugefunctionals

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In describing topology, the Topologization Lemma for Algebras shows that the topology can also be described by a system of Gaugefunctionals

Unitary algebra

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The algebra   is called unital if it has a neutral element   of multiplication. In particular, one defines   for all  . The set of all invertible (regular) elements is denoted by  . Non-invertible elements are called singular.


Task: matrix algebras

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Consider the set   of square   matrices with matrix multiplication and the maxmum norm of the components of the matrix. Try to prove individual properties of an algebra (  is a non-commutative unitary algebra). For the proof that   with matrix multiplication is also a topological algebra, see Topologization Lemma for Algebras.

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Let   be a topological algebra over the field  ,   and   be subsets of  , then define

 

Learning Tasks

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Draw the following set   of vectors as sets of points in the Cartesian coordinate system   with   and   and the following intervals  :

  •  .
  •  .
  •  .

See also

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