A CORRESPONDENCE BETWEEN BALANCED VARIETIES AND INVERSE MONOIDS

2006 ◽  
Vol 16 (05) ◽  
pp. 887-924 ◽  
Author(s):  
MARK V. LAWSON
Keyword(s):  
Special Class ◽  
Linear Equations ◽  
Special Kind ◽  
Free Monoid ◽  
Inverse Monoid ◽  
Inverse Monoids ◽  
Group V ◽  
Thompson's Groups ◽  
Term Algebra ◽  
Thompson Group

There is a well-known correspondence between varieties of algebras and fully invariant congruences on the appropriate term algebra. A special class of varieties are those which are balanced, meaning they can be described by equations in which the same variables appear on each side. In this paper, we prove that the above correspondence, restricted to balanced varieties, leads to a correspondence between balanced varieties and inverse monoids. In the case of unary algebras, we recover the theorem of Meakin and Sapir that establishes a bijection between congruences on the free monoid with n generators and wide, positively self-conjugate inverse submonoids of the polycyclic monoid on n generators. In the case of varieties generated by linear equations, meaning those equations where each variable occurs exactly once on each side, we can replace the clause monoid above by the linear clause monoid. In the case of algebras with a single operation of arity n, we prove that the linear clause monoid is isomorphic to the inverse monoid of right ideal isomorphisms between the finitely generated essential right ideals of the free monoid on n letters, a monoid previously studied by Birget in the course of work on the Thompson group V and its analogues. We show that Dehornoy's geometry monoid of a balanced variety is a special kind of inverse submonoid of ours. Finally, we construct groups from the inverse monoids associated with a balanced variety and examine some conditions under which they still reflect the structure of the underlying variety. Both free groups and Thompson's groups Vn,1 arise in this way.

scholarly journals EQUATIONS IN FREE INVERSE MONOIDS

2007 ◽  
Vol 17 (04) ◽  
pp. 761-795 ◽  
Author(s):  
TIMOTHY DEIS ◽  
JOHN MEAKIN ◽  
G. SÉNIZERGUES
Keyword(s):  
Free Group ◽  
Free Monoid ◽  
Finite System ◽  
System Of Equations ◽  
Inverse Monoid ◽  
Single Variable ◽  
Systems Of Equations ◽  
Inverse Monoids ◽  
Consistency Problem ◽  
Free Inverse Monoid

It is known that the problem of determining consistency of a finite system of equations in a free group or a free monoid is decidable, but the corresponding problem for systems of equations in a free inverse monoid of rank at least two is undecidable. Any solution to a system of equations in a free inverse monoid induces a solution to the corresponding system of equations in the associated free group in an obvious way, but solutions to systems of equations in free groups do not necessarily lift to solutions in free inverse monoids. In this paper, we show that the problem of determining whether a solution to a finite system of equations in a free group can be extended to a solution of the corresponding system in the associated free inverse monoid is decidable. We are able to use this to solve the consistency problem for certain classes of single-variable equations in free inverse monoids.

scholarly journals A NONCOMMUTATIVE GENERALIZATION OF STONE DUALITY

2010 ◽  
Vol 88 (3) ◽  
pp. 385-404 ◽  
Author(s):  
M. V. Lawson
Keyword(s):  
Boolean Algebras ◽  
Inverse Monoid ◽  
Stone Duality ◽  
Inverse Monoids ◽  
Group Of Units ◽  
Boolean Spaces ◽  
Thompson Group

AbstractWe prove that the category of boolean inverse monoids is dually equivalent to the category of boolean groupoids. This generalizes the classical Stone duality between boolean algebras and boolean spaces. As an instance of this duality, we show that the boolean inverse monoid Cn associated with the Cuntz groupoid Gn is the strong orthogonal completion of the polycyclic (or Cuntz) monoid Pn. The group of units of Cn is the Thompson group Vn,1.

scholarly journals Coherency, free inverse monoids and related free algebras

2016 ◽  
Vol 163 (1) ◽  
pp. 23-45 ◽  
Author(s):  
VICTORIA GOULD ◽  
MIKLÓS HARTMANN
Keyword(s):  
Free Monoid ◽  
Free Algebras ◽  
Inverse Monoid ◽  
Finitely Generated ◽  
Free Monoids ◽  
Inverse Monoids ◽  
Existentially Closed ◽  
Free Left ◽  
Connected Subgraphs ◽  
Finitely Presented

AbstractA monoid S is right coherent if every finitely generated subact of every finitely presented right S-act is finitely presented. This is the non-additive notion corresponding to that for a ring R stating that every finitely generated submodule of every finitely presented right R-module is finitely presented. For monoids (and rings) right coherency is an important finitary property which determines, amongst other things, the existence of a model companion of the class of right S-acts (right R-modules) and hence that the class of existentially closed right S-acts (right R-modules) is axiomatisable.Choo, Lam and Luft have shown that free rings are right (and left) coherent; the authors, together with Ruškuc, have shown that (free) groups, free commutative monoids and free monoids have the same properties. It is then natural to ask whether other free algebras in varieties of monoids, possibly with an augmented signature, are right coherent. We demonstrate that free inverse monoids are not.Munn described the free inverse monoid FIM(Ω) on Ω as consisting of birooted finite connected subgraphs of the Cayley graph of the free group on Ω. Sitting within FIM(Ω) we have free algebras in other varieties and quasi-varieties, in particular the free left ample monoid FLA(Ω) and the free ample monoid FAM(Ω). The former is the free algebra in the variety of unary monoids corresponding to partial maps with distinguished domain; the latter is the two-sided dual. For example, FLA(Ω) is obtained from FIM(Ω) by considering only subgraphs with vertices labelled by elements of the free monoid on Ω.The main objective of the paper is to show that FLA(Ω) is right coherent. Furthermore, by making use of the same techniques we show that FIM(Ω), FLA(Ω) and FAM(Ω) satisfy (R), (r), (L) and (l), related conditions arising from the axiomatisability of certain classes of right S-acts and of left S-acts.

FREE INVERSE MONOIDS AND GRAPH IMMERSIONS

1993 ◽  
Vol 03 (01) ◽  
pp. 79-99 ◽  
Author(s):  
STUART W. MARGOLIS ◽  
JOHN C. MEAKIN
Keyword(s):  
Formal Language ◽  
Inverse Monoid ◽  
Finitely Generated ◽  
Inverse Monoids ◽  
Rational Subset ◽  
The Relationship ◽  
Subgroup Theorem ◽  
Free Inverse Monoid ◽  
Natural Way

The relationship between covering spaces of graphs and subgroups of the free group leads to a rapid proof of the Nielsen-Schreier subgroup theorem. We show here that a similar relationship holds between immersions of graphs and closed inverse submonoids of free inverse monoids. We prove using these methods, that a closed inverse submonoid of a free inverse monoid is finitely generated if and only if it has finite index if and only if it is a rational subset of the free inverse monoid in the sense of formal language theory. We solve the word problem for the free inverse category over a graph Γ. We show that immersions over Γ may be classified via conjugacy classes of loop monoids of the free inverse category over Γ. In the case that Γ is a bouquet of X circles, we prove that the category of (connected) immersions over Γ is equivalent to the category of (transitive) representations of the free inverse monoid FIM(X). Such representations are coded by closed inverse submonoids of FIM(X). These monoids will be constructed in a natural way from groups acting freely on trees and they admit an idempotent pure retract onto a free inverse monoid. Applications to the classification of finitely generated subgroups of free groups via finite inverse monoids are developed.

BIRGET–RHODES EXPANSION OF GROUPS AND INVERSE MONOIDS OF MÖBIUS TYPE

2002 ◽  
Vol 12 (04) ◽  
pp. 525-533 ◽  
Author(s):  
KEUNBAE CHOI ◽  
YONGDO LIM
Keyword(s):  
Hausdorff Space ◽  
Inverse Monoid ◽  
Expansion Formula ◽  
Inverse Monoids ◽  
Isolated Point

In this paper we prove that if a group G acts faithfully on a Hausdorff space X and acts freely at a non-isolated point, then the Birget–Rhodes expansion [Formula: see text] of the group G is isomorphic to an inverse monoid of Möbius type obtained from the action.

Symmetric groupoids, free categories and E*-unitary inverse monoids

1999 ◽  
Vol 129 (5) ◽  
pp. 959-984 ◽  
Author(s):  
Jonathan Leech
Keyword(s):  
Special Class ◽  
Graph Algebras ◽  
Inverse Monoids

Symmetric groupoids which classify the monomorphism contexts of objects in arbitrary categories are studied, along with their connections to symmetric inverse monoids and symmetric inverse algebras. Particular attention is given to symmetric groupoids of objects in free categories and to the inverse algebras induced from them by 0-closure. These graph algebras generalize both the class of polycyclic semigroups and the class of combinatorial ω-semigroups with adjoined zeros. Since all such algebras are E*-unitary, an analogue of McAlister's theory of.E-unitary inverse monoids is developed for a special class of E*-unitary inverse monoids and then illustrated on the class of graph algebras.

On The Schützenberger Product of Three Copies of a Free Group

1998 ◽  
Vol 08 (05) ◽  
pp. 533-551 ◽  
Author(s):  
O. Neto ◽  
H. Sezinando
Keyword(s):  
Free Group ◽  
Free Monoid ◽  
Inverse Monoid ◽  
Natural Structure ◽  
Free Inverse Monoid

We show that the Schützenberger product "cut down to generators" of three copies of a free group is a relatively free monoid with involution. We show that its set of idempotents has a natural structure of a semilattice. This semilattice is naturally isomorphic to the semilattice of idempotents of a free inverse monoid.

Inverse semigroup homomorphisms via partial group actions

2001 ◽  
Vol 64 (1) ◽  
pp. 157-168 ◽  
Author(s):  
Benjamin Steinberg
Keyword(s):  
Inverse Semigroup ◽  
Group Actions ◽  
Inverse Semigroups ◽  
Inverse Monoid ◽  
Partial Group ◽  
Inverse Monoids ◽  
Maximal Group ◽  
Special Cases ◽  
Quick Proof ◽  
Group Component

This papar constructs all homomorphisms of inverse semigroups which factor through an E-unitary inverse semigroup; the construction is in terms of a semilattice component and a group component. It is shown that such homomorphisms have a unique factorisation βα with α preserving the maximal group image, β idempotent separating, and the domain I of β E-unitary; moreover, the P-representation of I is explicitly constructed. This theory, in particular, applies whenever the domain or codomain of a homomorphism is E-unitary. Stronger results are obtained for the case of F-inverse monoids.Special cases of our results include the P-theorem and the factorisation theorem for homomorphisms from E-unitary inverse semigroups (via idempotent pure followed by idempotent separating). We also deduce a criterion of McAlister–Reilly for the existence of E-unitary covers over a group, as well as a generalisation to F-inverse covers, allowing a quick proof that every inverse monoid has an F-inverse cover.

scholarly journals Construction of Inverse Unit Regular Monoids from a Semilattice and a Group

2018 ◽  
Vol 7 (4.36) ◽  
pp. 950
Author(s):  
Sreeja V.K
Keyword(s):  
Inverse Monoid ◽  
Inverse Monoids ◽  
Regular Semigroups ◽  
Group Of Units ◽  
Regular Monoid

This paper is a continuation of a previous paper [6] in which the structure of certain unit regular semigroups called R-strongly unit regular monoids has been studied. A monoid S is said to be unit regular if for each element s Î S there exists an element u in the group of units G of S such that s = sus. Hence where su is an idempotent and is a unit. A unit regular monoid S is said to be a unit regular inverse monoid if the set of idempotents of S form a semilattice. Since inverse monoids are R unipotent, every element of a unit regular inverse monoid can be written as s = eu where the idempotent part e is unique and u is a unit. Here we give a detailed study of inverse unit regular monoids and the results  are mainly based on [10]. The relations between the semilattice of idempotents and the group of units in unit regular inverse monoids are better identified in this case. .

THE FREE AMPLE MONOID

2009 ◽  
Vol 19 (04) ◽  
pp. 527-554 ◽  
Author(s):  
JOHN FOUNTAIN ◽  
GRACINDA M. S. GOMES ◽  
VICTORIA GOULD
Keyword(s):  
Semidirect Product ◽  
Free Monoid ◽  
Inverse Monoid ◽  
Free Inverse Monoid

We show that the free weakly E-ample monoid on a set X is a full submonoid of the free inverse monoid FIM(X) on X. Consequently, it is ample, and so coincides with both the free weakly ample and the free ample monoid FAM(X) on X. We introduce the notion of a semidirect product Y*T of a monoid T acting doubly on a semilattice Y with identity. We argue that the free monoid X* acts doubly on the semilattice [Formula: see text] of idempotents of FIM(X) and that FAM(X) is embedded in [Formula: see text]. Finally we show that every weakly E-ample monoid has a proper ample cover.

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