Semigroup: Difference between revisions
imported>Richard Pinch (added free semigroup on one generator) |
imported>Richard Pinch (Congruences and quotients) |
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* Every [[monoid]] is a semigroup, by "forgetting" the identity element. | * Every [[monoid]] is a semigroup, by "forgetting" the identity element. | ||
* Every [[group (mathematics)|group]] is a semigrpup, by "forgetting" the identity element and inverse operation. | * Every [[group (mathematics)|group]] is a semigrpup, by "forgetting" the identity element and inverse operation. | ||
==Congruences== | |||
A '''congruence''' on a semigroup ''S'' is an [[equivalence relation]] <math>\sim</math> which respects the binarey operation: | |||
:<math>a \sim b \hbox{ and } c \sim d \Rightarrow a \star c \sim b \star d . \,</math> | |||
The [[equivalence class]]es under a congruence can be given a semigroup structure | |||
:<math>[x] \circ [y] = [x \star y] \, </math> | |||
and this defines the '''quotient semigroup''' <math>S/\sim\,</math>. | |||
==Cancellation property== | ==Cancellation property== |
Revision as of 15:01, 13 November 2008
In algebra, a semigroup is a set equipped with a binary operation satisfying certain properties similar to but less stringent than those of a group. A motivating example of a semigroup is the set of positive integers with multiplication as the operation.
Formally, a semigroup is a set S with a binary operation satisfying the following conditions:
- S is closed under ;
- The operation is associative.
A commutative semigroup is one which satisfies the further property that for all x and y in S. Commutative semigroups are often written additively.
A subsemigroup of S is a subset T of S which is closed under the binary operation.
A semigroup homomorphism f from semigroup to is a map from S to T satisfying
Examples
- The positive integers under addition form a commutative semigroup.
- The positive integers under multiplication form a commutative semigroup.
- Square matrices under matrix multiplication form a semigroup, not in general commutative.
- Every monoid is a semigroup, by "forgetting" the identity element.
- Every group is a semigrpup, by "forgetting" the identity element and inverse operation.
Congruences
A congruence on a semigroup S is an equivalence relation which respects the binarey operation:
The equivalence classes under a congruence can be given a semigroup structure
and this defines the quotient semigroup .
Cancellation property
A semigroup satisfies the cancellation property if
- and
A semigroup is a subsemigroup of a group if and only if it satisfies the cancellation property.
Free semigroup
The free semigroup on a set G of generators is the set of all words on G, the finite sequences of elements of G, with the binary operation being concatenation (juxtaposition). The free semigroup on one generator g may be identified with the monoid of positive integers under addition