Monoid: Difference between revisions
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A ''[[commutative]] monoid'' is one which satisfies the further property that <math>x \star y = y \star x</math> for all ''x'' and ''y'' in ''M''. Commutative monoids are often written additively. | A ''[[commutative]] monoid'' is one which satisfies the further property that <math>x \star y = y \star x</math> for all ''x'' and ''y'' in ''M''. Commutative monoids are often written additively. | ||
An element ''x'' of a monoid is ''invertible'' if there exists an element ''y'' such that <math>x \star y = y \star x = I</math>: the inverse may be written as <math>x^{-1}</math>. The product of invertible elements is invertible, | An element ''x'' of a monoid is ''invertible'' if there exists an element ''y'' such that <math>x \star y = y \star x = I</math>: this is the ''inverse element'' for x and may be written as <math>x^{-1}</math>: by associativity an element can have at most one inverse (note that <math>x = y^{-1}</math> as well). The identity element is self-inverse and the product of invertible elements is invertible, | ||
:<math>(xy)^{-1} = y^{-1} x^{-1} \, </math> | :<math>(xy)^{-1} = y^{-1} x^{-1} \, </math> | ||
so the invertible elements form a group, the ''unit group'' of ''M''. | |||
A ''pseudoinverse'' for ''x'' is an element <math>x^{+}</math> such that <math>x x^{+} x = x</math>. The inverse, if it exists, is a pseudoinverse, but a pseudoinverse may exists for a non-invertible element. | |||
A ''submonoid'' of ''M'' is a subset ''S'' of ''M'' which contains the identity element ''I'' and is closed under the binary operation. | A ''submonoid'' of ''M'' is a subset ''S'' of ''M'' which contains the identity element ''I'' and is closed under the binary operation. | ||
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The '''free monoid''' 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 identity element is the empty (zero-length) word. The free monoid on one generator ''g'' may be identified with the monoid of non-negative integers | The '''free monoid''' 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 identity element is the empty (zero-length) word. The free monoid on one generator ''g'' may be identified with the monoid of non-negative integers | ||
:<math> n \leftrightarrow g^n = gg \cdots g . \,</math> | :<math> n \leftrightarrow g^n = gg \cdots g . \,</math>[[Category:Suggestion Bot Tag]] |
Latest revision as of 06:00, 21 September 2024
In algebra, a monoid 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 monoid is the set of positive integers with multiplication as the operation.
Formally, a monoid is set M with a binary operation satisfying the following conditions:
- M is closed under ;
- The operation is associative
- There is an identity element such that
- for all x in M.
A commutative monoid is one which satisfies the further property that for all x and y in M. Commutative monoids are often written additively.
An element x of a monoid is invertible if there exists an element y such that : this is the inverse element for x and may be written as : by associativity an element can have at most one inverse (note that as well). The identity element is self-inverse and the product of invertible elements is invertible,
so the invertible elements form a group, the unit group of M.
A pseudoinverse for x is an element such that . The inverse, if it exists, is a pseudoinverse, but a pseudoinverse may exists for a non-invertible element.
A submonoid of M is a subset S of M which contains the identity element I and is closed under the binary operation.
A monoid homomorphism f from monoid to is a map from M to N satisfying
- ;
Examples
- The non-negative integers under addition form a commutative monoid, with zero as identity element.
- The positive integers under multiplication form a commutative monoid, with one as identity element.
- The set of all maps from a set to itself forms a monoid, with function composition as the operation and the identity map as the identity element.
- Square matrices under matrix multiplication form a monoid, with the identity matrix as the identity element: this monoid is not in general commutative.
- Every group is a monoid, by "forgetting" the inverse operation.
Cancellation property
A monoid satisfies the cancellation property if
- and
A monoid is a submonoid of a group if and only if it satisfies the cancellation property.
Free monoid
The free monoid 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 identity element is the empty (zero-length) word. The free monoid on one generator g may be identified with the monoid of non-negative integers