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Munn semigroup

In mathematics, the Munn semigroup is the inverse semigroup of isomorphisms between principal ideals of a semilattice. Munn semigroups are named for the Scottish mathematician Walter Douglas Munn (1929–2008).

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In mathematics, the Munn semigroup is the inverse semigroup of isomorphisms between principal ideals of a semilattice (a commutative semigroup of idempotents). Munn semigroups are named for the Scottish mathematician Walter Douglas Munn (1929–2008).1

Construction's steps

Let E {\displaystyle E} be a semilattice.

1) For all e in E, we define Ee: = {i ∈ E : i ≤ e} which is a principal ideal of E.

2) For all ef in E, we define Te,f as the set of isomorphisms of Ee onto Ef.

3) The Munn semigroup of the semilattice E is defined as: TE :=  e , f E {\displaystyle \bigcup _{e,f\in E}}  { Te,f : (ef) ∈ U }.

The semigroup's operation is composition of partial mappings. In fact, we can observe that TE ⊆ IE where IE is the symmetric inverse semigroup because all isomorphisms are partial one-one maps from subsets of E onto subsets of E.

The idempotents of the Munn semigroup are the identity maps 1Ee.

Theorem

For every semilattice E {\displaystyle E} , the semilattice of idempotents of T E {\displaystyle T_{E}} is isomorphic to E.

Example

Let E = { 0 , 1 , 2 , . . . } {\displaystyle E=\{0,1,2,...\}} . Then E {\displaystyle E} is a semilattice under the usual ordering of the natural numbers ( 0 < 1 < 2 < . . . {\displaystyle 0<1<2<...} ). The principal ideals of E {\displaystyle E} are then E n = { 0 , 1 , 2 , . . . , n } {\displaystyle En=\{0,1,2,...,n\}} for all n {\displaystyle n} . So, the principal ideals E m {\displaystyle Em} and E n {\displaystyle En} are isomorphic if and only if m = n {\displaystyle m=n} .

Thus T n , n {\displaystyle T_{n,n}} = { 1 E n {\displaystyle 1_{En}} } where 1 E n {\displaystyle 1_{En}} is the identity map from En to itself, and T m , n = {\displaystyle T_{m,n}=\emptyset } if m n {\displaystyle m\not =n} . The semigroup product of 1 E m {\displaystyle 1_{Em}} and 1 E n {\displaystyle 1_{En}} is 1 E min { m , n } {\displaystyle 1_{E\operatorname {min} \{m,n\}}} . In this example, T E = { 1 E 0 , 1 E 1 , 1 E 2 , } E . {\displaystyle T_{E}=\{1_{E0},1_{E1},1_{E2},\ldots \}\cong E.}

References

References