Difference between revisions of "General linear group"
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| − | {{TEX| | + | {{TEX|done}} |
| + | {{MSC|20|15}} | ||
| − | The group of all | + | The general linear group of degree $n$ is |
| + | the group of all $(n\times n)$ invertible matrices over an associative ring (cf. | ||
| + | [[Associative rings and algebras|Associative rings and algebras]]) $K$ | ||
| + | with a unit; the usual symbols are $\def\GL{\textrm{GL}} \GL_n(K)$ or $\GL(n,K)$. The general linear | ||
| + | group $\GL(n,K)$ can also be defined as the automorphism group $\textrm{Aut}_K(V)$ of the | ||
| + | free right $K$-module $V$ with $n$ generators. | ||
| − | In research on the group | + | In research on the group $\GL(n,K)$ its normal structure is of considerable |
| + | interest. The centre $Z_n$ of the group $\GL(n,K)$ consists of scalar matrices | ||
| + | with entries from the centre of the ring (cf. | ||
| + | [[Centre of a ring|Centre of a ring]]) $K$. When $K$ is commutative | ||
| + | one defines the | ||
| + | [[Special linear group|special linear group]] $\def\SL{\textrm{SL}} \SL(n,K)$, which consists of | ||
| + | matrices with determinant 1. When $K$ is a field, the | ||
| + | [[Commutator subgroup|commutator subgroup]] of the group $\GL(n,K)$ coincides | ||
| + | with $\SL(n,K)$ (apart from the case $n=2$, $|K| = 2$), and any | ||
| + | [[Normal subgroup|normal subgroup]] of $\GL(n,K)$ is either contained in $Z_n$ | ||
| + | or contains $\SL(n,K)$. In particular, the projective special linear group | ||
| − | + | $$\def\PSL{\textrm{PSL}} \PSL(n,K) = \SL(n,K)/\SL(n,K)\cap Z_n$$ | |
| + | is a simple group (apart from the cases $n=2$, $|K|=2,3$). | ||
| − | is a | + | If $K$ is a |
| + | [[Skew-field|skew-field]] and $n>1$, any normal subgroup of $\GL(n,K)$ is | ||
| + | either contained in $Z_n$ or contains the commutator subgroup $\SL^+(n,K)$ of $\GL(n,K)$ | ||
| + | generated by transvections (cf. | ||
| + | [[Transvection|Transvection]]), and the quotient group $\SL^+(n,K)/\SL^+(n,K)\cap Z_n$ is | ||
| + | simple. Also, there exists a natural isomorphism | ||
| + | $$\GL(n,K)/\SL^+(n,K) \simeq K^*/[K^*,K^*],$$ | ||
| + | where $K^*$ is | ||
| + | the multiplicative group of the skew-field $K$. If $K$ is | ||
| + | finite-dimensional over its centre $k$, then the role of $\SL(n,K)$ is played | ||
| + | by the group of all matrices from $\GL(n,K)$ with reduced norm 1. The groups | ||
| + | $\SL(n,K)$ and $\SL^+(n,K)$ do not always coincide, although this is so if $k$ is a | ||
| + | global field (see | ||
| + | [[Kneser–Tits hypothesis|Kneser–Tits hypothesis]]). | ||
| − | + | The study of the normal structure of general linear groups over a ring | |
| + | $K$ is associated with | ||
| + | [[Algebraic K-theory|algebraic $K$-theory]]. The group $\GL(n,K)$ over a | ||
| + | general ring $K$ may contain numerous normal subgroups. For example, | ||
| + | if $K$ is a commutative ring without zero divisors and with a finite | ||
| + | number of generators, then $\GL(n,K)$ is a | ||
| + | [[Residually-finite group|residually-finite group]], i.e. for each | ||
| + | element $g$ there exists a normal subgroup $N_g$ of finite index not | ||
| + | containing $g$. In the case $K=\Z$, the description of the normal | ||
| + | subgroups of $\GL(n,\Z)$ is in fact equivalent to the | ||
| + | [[Congruence problem|congruence problem]] for $\SL(n,\Z)$, since | ||
| + | $$[\GL(n,\Z):\SL(n,\Z)] = 2,$$ | ||
| + | and any | ||
| + | non-scalar normal subgroup of the group $\SL(n,\Z)$ for $n>2$ is a | ||
| + | [[Congruence subgroup|congruence subgroup]]. | ||
| − | + | There is a deep analogy between the structure of general linear groups | |
| − | + | and that of other classical groups. This analogy extends also to | |
| − | + | simple algebraic groups and Lie groups. | |
| − | |||
| − | |||
| − | |||
| − | |||
| − | |||
| − | |||
| − | |||
| − | There is a deep analogy between the structure of general linear groups and that of other classical groups. This analogy extends also to simple algebraic groups and Lie groups. | ||
====References==== | ====References==== | ||
| − | + | {| | |
| + | |- | ||
| + | |valign="top"|{{Ref|Ar}}||valign="top"| E. Artin, "Geometric algebra", Interscience (1957) {{MR|0082463}} {{ZBL|0077.02101}} | ||
| + | |- | ||
| + | |valign="top"|{{Ref|Ba}}||valign="top"| H. Bass, "Algebraic K-theory", Benjamin (1968) {{MR|0249491}} {{ZBL|0174.30302}} | ||
| + | |- | ||
| + | |valign="top"|{{Ref|Di}}||valign="top"| J.A. Dieudonné, "La géométrie des groupes classiques", Springer (1955) {{MR|0072144}} {{ZBL|0067.26104}} | ||
| + | |- | ||
| + | |} | ||
Revision as of 22:32, 29 February 2012
2020 Mathematics Subject Classification: Primary: 20-XX Secondary: 15-XX [MSN][ZBL]
The general linear group of degree $n$ is the group of all $(n\times n)$ invertible matrices over an associative ring (cf. Associative rings and algebras) $K$ with a unit; the usual symbols are $\def\GL{\textrm{GL}} \GL_n(K)$ or $\GL(n,K)$. The general linear group $\GL(n,K)$ can also be defined as the automorphism group $\textrm{Aut}_K(V)$ of the free right $K$-module $V$ with $n$ generators.
In research on the group $\GL(n,K)$ its normal structure is of considerable interest. The centre $Z_n$ of the group $\GL(n,K)$ consists of scalar matrices with entries from the centre of the ring (cf. Centre of a ring) $K$. When $K$ is commutative one defines the special linear group $\def\SL{\textrm{SL}} \SL(n,K)$, which consists of matrices with determinant 1. When $K$ is a field, the commutator subgroup of the group $\GL(n,K)$ coincides with $\SL(n,K)$ (apart from the case $n=2$, $|K| = 2$), and any normal subgroup of $\GL(n,K)$ is either contained in $Z_n$ or contains $\SL(n,K)$. In particular, the projective special linear group
$$\def\PSL{\textrm{PSL}} \PSL(n,K) = \SL(n,K)/\SL(n,K)\cap Z_n$$ is a simple group (apart from the cases $n=2$, $|K|=2,3$).
If $K$ is a skew-field and $n>1$, any normal subgroup of $\GL(n,K)$ is either contained in $Z_n$ or contains the commutator subgroup $\SL^+(n,K)$ of $\GL(n,K)$ generated by transvections (cf. Transvection), and the quotient group $\SL^+(n,K)/\SL^+(n,K)\cap Z_n$ is simple. Also, there exists a natural isomorphism $$\GL(n,K)/\SL^+(n,K) \simeq K^*/[K^*,K^*],$$ where $K^*$ is the multiplicative group of the skew-field $K$. If $K$ is finite-dimensional over its centre $k$, then the role of $\SL(n,K)$ is played by the group of all matrices from $\GL(n,K)$ with reduced norm 1. The groups $\SL(n,K)$ and $\SL^+(n,K)$ do not always coincide, although this is so if $k$ is a global field (see Kneser–Tits hypothesis).
The study of the normal structure of general linear groups over a ring $K$ is associated with algebraic $K$-theory. The group $\GL(n,K)$ over a general ring $K$ may contain numerous normal subgroups. For example, if $K$ is a commutative ring without zero divisors and with a finite number of generators, then $\GL(n,K)$ is a residually-finite group, i.e. for each element $g$ there exists a normal subgroup $N_g$ of finite index not containing $g$. In the case $K=\Z$, the description of the normal subgroups of $\GL(n,\Z)$ is in fact equivalent to the congruence problem for $\SL(n,\Z)$, since $$[\GL(n,\Z):\SL(n,\Z)] = 2,$$ and any non-scalar normal subgroup of the group $\SL(n,\Z)$ for $n>2$ is a congruence subgroup.
There is a deep analogy between the structure of general linear groups and that of other classical groups. This analogy extends also to simple algebraic groups and Lie groups.
References
| [Ar] | E. Artin, "Geometric algebra", Interscience (1957) MR0082463 Zbl 0077.02101 |
| [Ba] | H. Bass, "Algebraic K-theory", Benjamin (1968) MR0249491 Zbl 0174.30302 |
| [Di] | J.A. Dieudonné, "La géométrie des groupes classiques", Springer (1955) MR0072144 Zbl 0067.26104 |
How to Cite This Entry:
General linear group. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=General_linear_group&oldid=21370
General linear group. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=General_linear_group&oldid=21370
This article was adapted from an original article by V.P. Platonov (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article