# Difference between revisions of "Klein four-group"

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==Bigger groups== | ==Bigger groups== |

## Revision as of 16:31, 21 December 2014

This article is about a particular group, i.e., a group unique upto isomorphism. View specific information (such as linear representation theory, subgroup structure) about this groupView a complete list of particular groups (this is a very huge list!)[SHOW MORE]

## Contents

## Definition

### Verbal definitions

The Klein four-group, usually denoted , is defined in the following equivalent ways:

- It is the direct product of the group with itself
- It is the group comprising the elements under coordinate-wise multiplication
- It is the unique non-cyclic group of order 4
- It is the subgroup of the symmetric group of degree four comprising the double transpositions, and the identity element.
- It is the Burnside group : the
*free group*on two generators with exponent two.

### Multiplication table

The multiplication table with non-identity elements and identity element :

Element/element | ||||
---|---|---|---|---|

The multiplication table can be described as follows (and this characterizes the group):

- The product of the identity element and any element is that element itself.
- The product of any non-identity element with itself is the identity element.
- The product of two distinct non-identity elements is the third non-identity element.

## Elements

`Further information: element structure of Klein four-group`

### Up to conjugation

There are four conjugacy classes, each containing one element (the conjugacy classes are singleton because the group is abelian.

### Up to automorphism

There are two equivalence classes of elements upto automorphism: the identity element as a singleton, and all the non-identity elements. All the non-identity elements are equivalent under automorphism.

## Arithmetic functions

Want to compare and contrast arithmetic function values with other groups of the same order? Check out groups of order 4#Arithmetic functions

## Group properties

Property | Satisfied? | Explanation | Comment |
---|---|---|---|

Abelian group | Yes | ||

Nilpotent group | Yes | ||

Elementary abelian group | Yes | ||

Solvable group | Yes | ||

Supersolvable group | Yes | ||

Cyclic group | No | ||

Rational-representation group | Yes | ||

Rational group | Yes | ||

Ambivalent group | Yes |

## Endomorphisms

### Automorphisms

The automorphism group is naturally identified with the group as follows. Each element of the automorphism group corresponds to a permutation of the three non-identity elements.

The holomorph, viz the direct product with the automorphism group, is the symmetric group on 4 elements.

### Endomorphisms

The non-automorphism endomorphisms include:

- The trivial map
- Pick an arbitrary direct sum decomposition and an arbitrary two-element subgroup. Then the projection on the first direct factor for the decomposition, composed with the isomorphism to the other two-element subgroup, is an endomorphism.

## Subgroups

`Further information: subgroup structure of Klein four-group`

### Summary

### Quick summary

Item | Value |
---|---|

Number of subgroups | 5 As elementary abelian group of prime-square order for prime : |

Number of conjugacy classes of subgroups | 5 (same as number of subgroups, because the group is an abelian group |

Number of automorphism classes of subgroups | 3 As elementary abelian group of order : |

Isomorphism classes of subgroups | trivia group (1 time), cyclic group:Z2 (3 times, all in the same automorphism class), Klein four-group (1 time). |

### Table classifying subgroups up to automorphism

Note that because abelian implies every subgroup is normal, all the subgroups are normal subgroups.

Automorphism class of subgroups | List of subgroups | Isomorphism class | Order of subgroups | Index of subgroups | Number of conjugacy classes(=1 iff automorph-conjugate subgroup) | Size of each conjugacy class(=1 iff normal subgroup) | Total number of subgroups(=1 iff characteristic subgroup) | Isomorphism class of quotient (if exists) | Subnormal depth | Nilpotency class |
---|---|---|---|---|---|---|---|---|---|---|

trivial subgroup | trivial group | 1 | 4 | 1 | 1 | 1 | Klein four-group | 1 | 0 | |

Z2 in V4 | cyclic group:Z2 | 2 | 2 | 3 | 1 | 3 | cyclic group:Z2 | 1 | 1 | |

whole group | Klein four-group | 4 | 1 | 1 | 1 | 1 | trivial group | 0 | 1 | |

Total (3 rows) | -- | -- | -- | -- | 5 | -- | 5 | -- | -- | -- |

## Bigger groups

### Groups containing it as a subgroup

- Alternating group:A4 which is the semidirect product of the Klein-four group by a cyclic group of order 3
- Symmetric group:S4 which is the holomorph of the Klein-four group, and in which the Klein-four group is a characteristic subgroup
- Dihedral group:D8 which is the dihedral group of order 8, acting on a set of four elements. It sits between the Klein-four group and the symmetric group on 4 elements

Note that the Klein-four group embeds in two ways inside the symmetric group, one, as double transpositions, the other, as the direct product of a pair of involutions. We usually refer to the former embedding, when nothing is explicitly stated.

### Groups having it as a quotient

In general, whenever a group has a subgroup of index two that is *not* characteristic, then the intersection of that subgroup and any other automorph of it, is of index four, and the quotient obtained is the Klein-four group.

It may also occur as the intersection of index-two subgroups that are not automorphs of each other.

Some examples:

- The quaternion group, which has the Klein-four group as its inner automorphism group. The normal subgroups can be taken as those generated by the squareroots of
- The dihedral group of order eight, which has the Klein-four group as its inner automorphism group. Here, it is the quotient by the intersection of two subgroups of order four, one being a cyclic subgroup, the other being itself a Klein-four group.

## Implementation in GAP

### Group ID

This finite group has order 4 and has ID 2 among the groups of order 4 in GAP's SmallGroup library. For context, there are groups of order 4. It can thus be defined using GAP's SmallGroup function as:

`SmallGroup(4,2)`

For instance, we can use the following assignment in GAP to create the group and name it :

`gap> G := SmallGroup(4,2);`

Conversely, to check whether a given group is in fact the group we want, we can use GAP's IdGroup function:

`IdGroup(G) = [4,2]`

or just do:

`IdGroup(G)`

to have GAP output the group ID, that we can then compare to what we want.

### Other descriptions

The group can also be defined using GAP's ElementaryAbelianGroup function as:

`ElementaryAbelianGroup(4)`