Wreath product

In group theory, the wreath product is a specialized product of two groups, based on a semidirect product. Wreath products are used in the classification of permutation groups and also provide a way of constructing interesting examples of groups.

Given two groups A and H, there exist two variations of the wreath product: the unrestricted wreath product A Wr H (also written A≀H) and the restricted wreath product A wr H. Given a set Ω with an H-action there exists a generalization of the wreath product which is denoted by A Wr_Ω H or A wr_Ω H respectively.

The notion generalizes to semigroups and is a central construction in the Krohn–Rhodes structure theory of finite semigroups.

Definition

Let A and H be groups and Ω a set with H acting on it. Let K be the direct product

K=\prod _{\omega \in \Omega }A_{\omega }

of copies of A_ω := A indexed by the set Ω. The elements of K can be seen as arbitrary sequences (a_ω) of elements of A indexed by Ω with component-wise multiplication. Then the action of H on Ω extends in a natural way to an action of H on the group K by

h(a_{\omega }):=(a_{h^{-1}\omega }).

Then the unrestricted wreath product A Wr_Ω H of A by H is the semidirect product K ⋊ H. The subgroup K of A Wr_Ω H is called the base of the wreath product.

The restricted wreath product A wr_Ω H is constructed in the same way as the unrestricted wreath product except that one uses the direct sum

K=\bigoplus _{\omega \in \Omega }A_{\omega }

as the base of the wreath product. In this case the elements of K are sequences (a_ω) of elements in A indexed by Ω of which all but finitely many a_ω are the identity element of A.

In the most common case, one takes Ω := H, where H acts in a natural way on itself by left multiplication. In this case, the unrestricted and restricted wreath product may be denoted by A Wr H and A wr H respectively. This is called the regular wreath product.

Notation and conventions

The structure of the wreath product of A by H depends on the H-set Ω and in case Ω is infinite it also depends on whether one uses the restricted or unrestricted wreath product. However, in literature the notation used may be deficient and one needs to pay attention to the circumstances.

In literature A≀_ΩH may stand for the unrestricted wreath product A Wr_Ω H or the restricted wreath product A wr_Ω H.
Similarly, A≀H may stand for the unrestricted regular wreath product A Wr H or the restricted regular wreath product A wr H.
In literature the H-set Ω may be omitted from the notation even if Ω ≠ H.
In the special case that H = S_n is the symmetric group of degree n it is common in the literature to assume that Ω = {1,...,n} (with the natural action of S_n) and then omit Ω from the notation. That is, A≀S_n commonly denotes A≀_{1,...,n}S_n instead of the regular wreath product A≀_{S_n}S_n. In the first case the base group is the product of n copies of A, in the latter it is the product of n! copies of A.

Properties

Agreement of unrestricted and restricted wreath product on finite Ω

Since the finite direct product is the same as the finite direct sum of groups, it follows that the unrestricted A Wr_Ω H and the restricted wreath product A wr_Ω H agree if the H-set Ω is finite. In particular this is true when Ω = H is finite.

Subgroup

A wr_Ω H is always a subgroup of A Wr_Ω H.

Cardinality properties

If A, H and Ω are finite, then

|A≀_ΩH| = |A|^|Ω||H|.[1]

Universal embedding theorem

Universal embedding theorem: If G is an extension of A by H, then there exists a subgroup of the unrestricted wreath product A≀H which is isomorphic to G.[2] This is also known as the Krasner–Kaloujnine embedding theorem. The Krohn–Rhodes theorem involves what is basically the semigroup equivalent of this.[3]

Canonical actions of wreath products

If the group A acts on a set Λ then there are two canonical ways to construct sets from Ω and Λ on which A Wr_Ω H (and therefore also A wr_Ω H) can act.

The imprimitive wreath product action on Λ × Ω.

If ((a_ω),h) ∈ A Wr_Ω H and (λ,ω′) ∈ Λ × Ω, then

((a_{\omega }),h)\cdot (\lambda ,\omega '):=(a_{h(\omega ')}\lambda ,h\omega ').

The primitive wreath product action on Λ^Ω.

An element in Λ^Ω is a sequence (λ_ω) indexed by the H-set Ω. Given an element ((a_ω), h) ∈ A Wr_Ω H its operation on (λ_ω) ∈ Λ^Ω is given by

((a_{\omega }),h)\cdot (\lambda _{\omega }):=(a_{h^{-1}\omega }\lambda _{h^{-1}\omega }).

Examples

The Lamplighter group is the restricted wreath product ℤ₂≀ℤ.
$ℤ m ≀ S n$ (Generalized symmetric group).

The base of this wreath product is the n-fold direct product

ℤ_mⁿ = ℤ_m × ... × ℤ_m

of copies of ℤ_m where the action φ : S_n → Aut(ℤ_mⁿ) of the symmetric group S_n of degree n is given by

φ(σ)(α₁,..., α_n) := (α_σ(1),..., α_σ(n)).[4]

S₂≀S_n (Hyperoctahedral group).

The action of S_n on {1,...,n} is as above. Since the symmetric group S₂ of degree 2 is isomorphic to ℤ₂ the hyperoctahedral group is a special case of a generalized symmetric group.[5]

The smallest non-trivial wreath product is ℤ₂≀ℤ₂, which is the two-dimensional case of the above hyperoctahedral group. It is the symmetry group of the square, also called Dih₄, the dihedral group of order 8.
Let p be a prime and let n≥1. Let P be a Sylow p-subgroup of the symmetric group S_pⁿ of degree pⁿ. Then P is isomorphic to the iterated regular wreath product W_n = ℤ_p ≀ ℤ_p≀...≀ℤ_p of n copies of ℤ_p. Here W₁ := ℤ_p and W_k := W_k−1≀ℤ_p for all k ≥ 2.[6][7] For instance, the Sylow 2-subgroup of S₄ is the above ℤ₂≀ℤ₂ group.
The Rubik's Cube group is a subgroup of index 12 in the product of wreath products, (ℤ₃≀S₈) × (ℤ₂≀S₁₂), the factors corresponding to the symmetries of the 8 corners and 12 edges.

References

Joseph J. Rotman, An Introduction to the Theory of Groups, p. 172 (1995)
M. Krasner and L. Kaloujnine, "Produit complet des groupes de permutations et le problème d'extension de groupes III", Acta Sci. Math. Szeged 14, pp. 69–82 (1951)
J D P Meldrum (1995). Wreath Products of Groups and Semigroups. Longman [UK] / Wiley [US]. p. ix. ISBN 978-0-582-02693-3.
J. W. Davies and A. O. Morris, "The Schur Multiplier of the Generalized Symmetric Group", J. London Math. Soc (2), 8, (1974), pp. 615–620
P. Graczyk, G. Letac and H. Massam, "The Hyperoctahedral Group, Symmetric Group Representations and the Moments of the Real Wishart Distribution", J. Theoret. Probab. 18 (2005), no. 1, 1–42.
Joseph J. Rotman, An Introduction to the Theory of Groups, p. 176 (1995)
L. Kaloujnine, "La structure des p-groupes de Sylow des groupes symétriques finis", Annales Scientifiques de l'École Normale Supérieure. Troisième Série 65, pp. 239–276 (1948)

External links

Wreath product in Encyclopedia of Mathematics.
Some Applications of the Wreath Product Construction. Archived 21 February 2014 at the Wayback Machine

This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.

[1] Joseph J. Rotman, An Introduction to the Theory of Groups, p. 172 (1995)

[2] M. Krasner and L. Kaloujnine, "Produit complet des groupes de permutations et le problème d'extension de groupes III", Acta Sci. Math. Szeged 14, pp. 69–82 (1951)

[Meldrum1995-3] J D P Meldrum (1995). Wreath Products of Groups and Semigroups. Longman [UK] / Wiley [US]. p. ix. ISBN 978-0-582-02693-3.

[4] J. W. Davies and A. O. Morris, "The Schur Multiplier of the Generalized Symmetric Group", J. London Math. Soc (2), 8, (1974), pp. 615–620

[5] P. Graczyk, G. Letac and H. Massam, "The Hyperoctahedral Group, Symmetric Group Representations and the Moments of the Real Wishart Distribution", J. Theoret. Probab. 18 (2005), no. 1, 1–42.

[6] Joseph J. Rotman, An Introduction to the Theory of Groups, p. 176 (1995)

[7] L. Kaloujnine, "La structure des p-groupes de Sylow des groupes symétriques finis", Annales Scientifiques de l'École Normale Supérieure. Troisième Série 65, pp. 239–276 (1948)