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 n be a natural number and k a field. The general linear group of order n over k, denoted GL(n,k), is defined in the following equivalent ways:

  • GL(n,k) is the group of all invertible k-linear maps from the vector space kn to itself, under composition. In other words, it is the group of automorphisms of kn as a k-vector space.
  • GL(n,k) is the group of all invertible n×n matrices with entries over k

In terms of vector spaces

Let V be a k-vector space (which may be finite or infinite-dimensional). The general linear group over V, denoted GL(V), is the group of all vector space automorphisms from V to itself.

Note that when V=kn, this reduces to the definition Gl(n,k). Further, since GL(V)GL(W) for VW, and since any two vectro spaces of the same dimension are isomorphic, the GL(n,k)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 n, we can think of GLn as a functor from the category of fields to the category of groups.

As an IAPS

Further information: GL IAPS

For a fixed field k, the general linear groups GL(n,k) form an IAPS of groups parametrized by n. In other words, we naturally have concatenation maps:

Φm,n:GL(m,k)×GL(n,k)GL(m+n,k)

This map takes a matrix A of order m and a matrix B of order n and putputs the block diagonal matrix with blocks A and B.

As a functor from fields to IAPSes

If we fix neither n nor k, we can view GL 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:

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:

Extensions

Groups having the general linear group as a quotient?