General linear group over a field: Difference between revisions
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* [[Special orthogonal group]] is the intersection of the [[orthogonal group]] and the [[special linear group]] | * [[Special orthogonal group]] is the intersection of the [[orthogonal group]] and the [[special linear group]] | ||
* [[Orthogonal similitude group]] is the group of matrices <math>A</math> such that <math>AA^t</math> is a scalar matrix | * [[Orthogonal similitude group]] is the group of matrices <math>A</math> such that <math>AA^t</math> is a scalar matrix | ||
* [[Symmetric group]] which is the group of permutation matrices, embedded in the general linear group | |||
All of these, except the orthogonal similtude group, form sub-IAPSes. | All of these, except the orthogonal similtude group, form sub-IAPSes. | ||
==Quotients== | |||
{{inner automorphism group|projective general linear group}} | |||
==Supergroups== | ==Supergroups== | ||
Revision as of 16:15, 24 September 2007
This term associates to every field, a corresponding group property. In other words, given a field, every group either has the property with respect to that field or does not have the property with respect to that field
This group property is natural number-parametrized, in other words, for every natural number, we get a corresponding group property
This article is about the unit group (group of invertible elements) in the following ring/monoid: matrix ring
This article is about a general term. A list of important particular cases (instances) is available at Category:General linear groups
Definition
In terms of dimension
Let be a natural number and a field. The general linear group of order over , denoted , is defined in the following equivalent ways:
- is the group of all invertible -linear maps from the vector space to itself, under composition. In other words, it is the group of automorphisms of as a -vector space.
- is the group of all invertible matrices with entries over
In terms of vector spaces
Let be a -vector space (which may be finite or infinite-dimensional). The general linear group over , denoted , is the group of all vector space automorphisms from to itself.
Note that when , this reduces to the definition . Further, since for , and since any two vectro spaces of the same dimension are isomorphic, the s cover all general linear groups corresponding to finite-dimensional vector spaces.
As a map
As a functor from fields to groups
If we fix , we can think of as a functor from the category of fields to the category of groups.
As an IAPS
Further information: GL IAPS
For a fixed field , the general linear groups form an IAPS of groups parametrized by . In other words, we naturally have concatenation maps:
This map takes a matrix of order and a matrix of order and putputs the block diagonal matrix with blocks and .
As a functor from fields to IAPSes
If we fix neither nor , we can view as a functor from fields to the category of IAPSes of groups.
Subgroups
The general linear group has a number of important subgroups. Some of them are listed below:
- Orthogonal group is the subgroup comprising those matrices such that is the identity matrix. Further information: Orthogonal group in general linear group
- Special linear group is the subgroup comprising those matrices with determinant 1. Further information: Special linear group in general linear group
- Symplectic group is the subgroup comprising matrices such that where is a certain fixed matrix. Further information: Symplectic group in general linear group
- Special orthogonal group is the intersection of the orthogonal group and the special linear group
- Orthogonal similitude group is the group of matrices such that is a scalar matrix
- Symmetric group which is the group of permutation matrices, embedded in the general linear group
All of these, except the orthogonal similtude group, form sub-IAPSes.
Quotients
Inner automorphism group
The inner automorphism group of this group, viz the quotient group by its center, is abstractly isomorphic to: projective general linear group
Supergroups
Some important groups in which the general linear group is contained:
- General affine group which is the semidirect product of the vector space (as an Abelian group) and the general linear group acting on it
- Skew-linear group which is the semidirect product of the general linear group with the transpose-inverse map
Extensions
Groups having the general linear group as a quotient?