Commutator: Difference between revisions

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imported>Richard Pinch
(derived groups)
imported>Richard Pinch
m (typo)
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Commutators of higher order are defined iteratively as
Commutators of higher order are defined iteratively as


:<math> [x_1,x2_,\ldots,x_{n-1},x_n] = [x_1,[x_2,\ldots,[x_{n-1},x_n]\ldots]] . \,</math>
:<math> [x_1,x_2,\ldots,x_{n-1},x_n] = [x_1,[x_2,\ldots,[x_{n-1},x_n]\ldots]] . \,</math>


The higher derived groups are defined as <math>G^{(1)} = [G,G]</math>, <math>G^{(2)} = [G^{(1)},G^{(1)}]</math> and so on.
The higher derived groups are defined as <math>G^{(1)} = [G,G]</math>, <math>G^{(2)} = [G^{(1)},G^{(1)}]</math> and so on.

Revision as of 11:23, 8 November 2008

In algebra, the commutator of two elements of an algebraic structure is a measure of whether the algebraic operation is commutative.

Group theory

In a group, written multiplicatively, the commutator of elements x and y may be defined as

(although variants on this definition are possible). Elements x and y commute if and only if the commutator [x,y] is equal to the group identity. The commutator subgroup or derived group of G is the subgroup generated by all commutators, written or . It is normal and indeed characteristic and the quotient G/[G,G] is abelian. A quotient of G by a normal subgroup N is abelian if and only if N contains the commutator subgroup.

Commutators of higher order are defined iteratively as

The higher derived groups are defined as , and so on.

Ring theory

In a ring, the commutator of elements x and y may be defined as

References

  • Marshall Hall jr (1959). The theory of groups. New York: Macmillan, 123-124.