# Difference between revisions of "Coset"

### From Online Dictionary of Crystallography

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==Definition== | ==Definition== | ||

− | If G is a group, H a | + | If G is a group, H a [[subgroup]] of G, and g an element of G, then |

:gH = { gh : h ∈ H } is a '''left coset of H''' in ''G'' | :gH = { gh : h ∈ H } is a '''left coset of H''' in ''G'' | ||

:Hg = { hg : h ∈ H } is a '''right coset of H''' in ''G''. | :Hg = { hg : h ∈ H } is a '''right coset of H''' in ''G''. |

## Revision as of 17:31, 25 April 2007

Classe suivant un sous-groupe (*Fr*). Restklasse (*Ge*). Classe laterale (*It*). 剰余類 (*Ja*).

## Definition

If G is a group, H a subgroup of G, and g an element of G, then

- gH = { gh : h ∈ H } is a
**left coset of H**in*G* - Hg = { hg : h ∈ H } is a
**right coset of H**in*G*.

The decomposition of a group into cosets is unique. Left coset and right cosets however in general do not coincide, unless H is a normal subgroup of G.

Any two left cosets are either identical or disjoint: the left cosets form a partition of G, because every element of G belongs to one and only one left coset. In particular the identity is only in one coset, and that coset is H itself; this is also the only coset that is a subgroup. The same holds for right cosets.

All left cosets and all right cosets have the same order (number of elements, or cardinality), equal to the order of H, because H is itself a coset. Furthermore, the number of left cosets is equal to the number of right cosets and is known as the **index** of H in G, written as [G : H] and given by Lagrange's theorem:

- |G|/|H| = [G : H].

## Example

The coset decomposition of the twin lattice point group with respect to the point group of the individual gives the different possible twin laws. Each element in a coset is a possible twin operation.