# Difference between revisions of "Rank of a group"

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''(general and special rank of a group)'' | ''(general and special rank of a group)'' | ||

− | A notion from group theory. A group | + | A notion from group theory. A group $G$ has finite general rank $r$ if $r$ is the minimal number such that any finitely-generated subgroup of $G$ is contained in a subgroup having $r'$ generators $(r'\leq r)$. A group $G$ has finite special rank $r$ if $r$ is the minimal number such that any finitely-generated subgroup of $G$ has a system of generators of at most $r$ elements. If no such finite number exists, then the general (special) rank of the group is said to be infinite. |

The general rank of a group is smaller than or equal to its special rank. There are groups with finite general rank (even equal to two) and infinite special rank. Such is, for instance, the countable symmetric group. For an Abelian group the general and special rank coincide with its Prüfer rank (see [[Abelian group|Abelian group]]). | The general rank of a group is smaller than or equal to its special rank. There are groups with finite general rank (even equal to two) and infinite special rank. Such is, for instance, the countable symmetric group. For an Abelian group the general and special rank coincide with its Prüfer rank (see [[Abelian group|Abelian group]]). |

## Latest revision as of 16:24, 19 April 2014

*(general and special rank of a group)*

A notion from group theory. A group $G$ has finite general rank $r$ if $r$ is the minimal number such that any finitely-generated subgroup of $G$ is contained in a subgroup having $r'$ generators $(r'\leq r)$. A group $G$ has finite special rank $r$ if $r$ is the minimal number such that any finitely-generated subgroup of $G$ has a system of generators of at most $r$ elements. If no such finite number exists, then the general (special) rank of the group is said to be infinite.

The general rank of a group is smaller than or equal to its special rank. There are groups with finite general rank (even equal to two) and infinite special rank. Such is, for instance, the countable symmetric group. For an Abelian group the general and special rank coincide with its Prüfer rank (see Abelian group).

#### References

[1] | A.G. Kurosh, "The theory of groups" , 1–2 , Chelsea (1955–1956) (Translated from Russian) |

**How to Cite This Entry:**

Rank of a group.

*Encyclopedia of Mathematics.*URL: http://encyclopediaofmath.org/index.php?title=Rank_of_a_group&oldid=14796