# Difference between revisions of "Groups of order 48"

Line 4: | Line 4: | ||

==Statistics at a glance== | ==Statistics at a glance== | ||

+ | |||

+ | The number 48 has prime factorization <math>48 = 2^4 \cdot 3</math>. {{only two prime factors hence solvable}} | ||

{| class="sortable" border="1" | {| class="sortable" border="1" | ||

− | ! Quantity !! Value | + | ! Quantity !! Value !! Explanation |

|- | |- | ||

− | | Total number of groups || [[count::52]] | + | | Total number of groups || [[count::52]] || |

|- | |- | ||

− | | Number of abelian groups || 5 | + | | Number of abelian groups || 5 || (number of abelian groups of order <math>2^4</math>) times (number of abelian groups of order <math>3^1</math>) = ([[number of unordered integer partitions]] of 4) times ([[number of unordered integer partitions]] of 1) = <math>5 \times 1 = 5</math>. See [[classification of finite abelian groups]] and [[structure theorem for finitely generated abelian groups]]. |

|- | |- | ||

− | | Number of nilpotent groups || 14 | + | | Number of nilpotent groups || 14 || (number of [[groups of order 16]]) times (number of [[groups of order 3]]) = <math>14 \times 1 = 14</math>. See [[number of nilpotent groups equals product of number of groups of order each maximal prime power divisor]], which in turn follows from [[equivalence of definitions of finite nilpotent group]]. |

|- | |- | ||

− | | Number of solvable groups || 52 | + | | Number of solvable groups || 52 || {{only two prime factors hence solvable}} |

|- | |- | ||

− | | Number of simple groups || 0 | + | | Number of simple groups || 0 || Follows from all groups of this order being solvable. |

|} | |} | ||

Line 56: | Line 58: | ||

| [[elementary abelian group:E16]] || 14 || 4 || || 49, 50, 51, 52 | | [[elementary abelian group:E16]] || 14 || 4 || || 49, 50, 51, 52 | ||

|} | |} | ||

+ | |||

+ | ==GAP implementation== | ||

+ | |||

+ | {{this order in GAP|order = 48|idgroup = yes}} | ||

+ | |||

+ | <pre>gap> SmallGroupsInformation(48); | ||

+ | |||

+ | There are 52 groups of order 48. | ||

+ | They are sorted by their Frattini factors. | ||

+ | 1 has Frattini factor [ 6, 1 ]. | ||

+ | 2 has Frattini factor [ 6, 2 ]. | ||

+ | 3 has Frattini factor [ 12, 3 ]. | ||

+ | 4 - 19 have Frattini factor [ 12, 4 ]. | ||

+ | 20 - 27 have Frattini factor [ 12, 5 ]. | ||

+ | 28 - 30 have Frattini factor [ 24, 12 ]. | ||

+ | 31 - 33 have Frattini factor [ 24, 13 ]. | ||

+ | 34 - 43 have Frattini factor [ 24, 14 ]. | ||

+ | 44 - 47 have Frattini factor [ 24, 15 ]. | ||

+ | 48 - 52 have trivial Frattini subgroup. | ||

+ | |||

+ | For the selection functions the values of the following attributes | ||

+ | are precomputed and stored: | ||

+ | IsAbelian, IsNilpotentGroup, IsSupersolvableGroup, IsSolvableGroup, | ||

+ | LGLength, FrattinifactorSize and FrattinifactorId. | ||

+ | |||

+ | This size belongs to layer 2 of the SmallGroups library. | ||

+ | IdSmallGroup is available for this size.</pre> |

## Revision as of 17:43, 15 June 2011

This article gives information about, and links to more details on, groups of order 48

See pages on algebraic structures of order 48| See pages on groups of a particular order

This article gives basic information comparing and contrasting groups of order .

## Statistics at a glance

The number 48 has prime factorization . There are only two prime factors of this number. Order has only two prime factors implies solvable (by Burnside's -theorem) and hence all groups of this order are solvable groups (specifically, finite solvable groups). Another way of putting this is that the order is a solvability-forcing number. In particular, there is no simple non-abelian group of this order.

Quantity | Value | Explanation |
---|---|---|

Total number of groups | 52 | |

Number of abelian groups | 5 | (number of abelian groups of order ) times (number of abelian groups of order ) = (number of unordered integer partitions of 4) times (number of unordered integer partitions of 1) = . See classification of finite abelian groups and structure theorem for finitely generated abelian groups. |

Number of nilpotent groups | 14 | (number of groups of order 16) times (number of groups of order 3) = . See number of nilpotent groups equals product of number of groups of order each maximal prime power divisor, which in turn follows from equivalence of definitions of finite nilpotent group. |

Number of solvable groups | 52 | There are only two prime factors of this number. Order has only two prime factors implies solvable (by Burnside's -theorem) and hence all groups of this order are solvable groups (specifically, finite solvable groups). Another way of putting this is that the order is a solvability-forcing number. In particular, there is no simple non-abelian group of this order. |

Number of simple groups | 0 | Follows from all groups of this order being solvable. |

## Sylow subgroups

### 2-Sylow subgroups

Here is the occurrence summary:

Group of order 16 | GAP ID (second part) | Number of groups of order 48 in which it is a 2-Sylow subgroup | List of these groups | Second part of GAP ID of these groups |
---|---|---|---|---|

cyclic group:Z16 | 1 | 2 | 1, 2 | |

direct product of Z4 and Z4 | 2 | 3 | 3, 11, 20 | |

SmallGroup(16,3) | 3 | 4 | 14, 19, 21, 30 | |

nontrivial semidirect product of Z4 and Z4 | 4 | 3 | 12, 13, 22 | |

direct product of Z8 and Z2 | 5 | 3 | 4, 9, 23 | |

M16 | 6 | 3 | 5, 10, 24 | |

dihedral group:D16 | 7 | 3 | 7, 15, 25 | |

semidihedral group:SD16 | 8 | 5 | 6, 16, 17, 26, 29 | |

generalized quaternion group:Q16 | 9 | 4 | 8, 18, 27, 28 | |

direct product of Z4 and V4 | 10 | 4 | 31, 35, 42, 44 | |

direct product of D8 and Z2 | 11 | 5 | 36, 38, 43, 45, 48 | |

direct product of Q8 and Z2 | 12 | 4 | 32, 34, 40, 46 | |

central product of D8 and Z4 | 13 | 5 | 33, 37, 39, 41, 47 | |

elementary abelian group:E16 | 14 | 4 | 49, 50, 51, 52 |

## GAP implementation

The order 48 is part of GAP's SmallGroup library. Hence, any group of order 48 can be constructed using the SmallGroup function by specifying its group ID. Also, IdGroup is available, so the group ID of any group of this order can be queried.

Further, the collection of all groups of order 48 can be accessed as a list using GAP's AllSmallGroups function.

Here is GAP's summary information about how it stores groups of this order, accessed using GAP's SmallGroupsInformation function:

gap> SmallGroupsInformation(48); There are 52 groups of order 48. They are sorted by their Frattini factors. 1 has Frattini factor [ 6, 1 ]. 2 has Frattini factor [ 6, 2 ]. 3 has Frattini factor [ 12, 3 ]. 4 - 19 have Frattini factor [ 12, 4 ]. 20 - 27 have Frattini factor [ 12, 5 ]. 28 - 30 have Frattini factor [ 24, 12 ]. 31 - 33 have Frattini factor [ 24, 13 ]. 34 - 43 have Frattini factor [ 24, 14 ]. 44 - 47 have Frattini factor [ 24, 15 ]. 48 - 52 have trivial Frattini subgroup. For the selection functions the values of the following attributes are precomputed and stored: IsAbelian, IsNilpotentGroup, IsSupersolvableGroup, IsSolvableGroup, LGLength, FrattinifactorSize and FrattinifactorId. This size belongs to layer 2 of the SmallGroups library. IdSmallGroup is available for this size.