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In mathematics, the affine group or general affine group of any affine space over a field K is the group of all invertible affine transformations from the space into itself.

It is a Lie group if K is the real or complex field or quaternions.

Relation to general linear group
Construction from general linear group

Concretely, given a vector space V, it has an underlying affine space A obtained by “forgetting” the origin, with V acting by translations, and the affine group of A can be described concretely as the semidirect product of V by GL(V), the general linear group of V:

\( \operatorname{Aff}(A) = V \rtimes \operatorname{GL}(V) \)

The action of GL(V) on V is the natural one (linear transformations are automorphisms), so this defines a semidirect product.

In terms of matrices, one writes:

\( \operatorname{Aff}(n,K) = K^n \rtimes \operatorname{GL}(n,K) \)

where here the natural action of GL(n,K) on Kn is matrix multiplication of a vector.
Stabilizer of a point

Given the affine group of an affine space A, the stabilizer of a point p is isomorphic to the general linear group of the same dimension (so the stabilizer of a point in Aff(2,R) is isomorphic to GL(2,R)); formally, it is the general linear group of the vector space \( (A,p) \): recall that if one fixes a point, an affine space becomes a vector space.

All these subgroups are conjugate, where conjugation is given by translation from p to q (which is uniquely defined), however, no particular subgroup is a natural choice, since no point is special – this corresponds to the multiple choices of transverse subgroup, or splitting of the short exact sequence

\( 1 \to V \to V \rtimes \operatorname{GL}(V) \to \operatorname{GL}(V) \to 1. \)

In the case that the affine group was constructed by starting with a vector space, the subgroup that stabilizes the origin (of the vector space) is the original GL(V).

Matrix representation

Representing the affine group as a semidirect product of V by GL(V), then by construction of the semidirect product, the elements are pairs (M, v), where v is a vector in V and M is a linear transform in GL(V), and multiplication is given by:

\( (M,v) \cdot (N,w) = (MN, v+Mw).\, \)

This can be represented as the (n + 1)×(n + 1) block matrix:

\( \left( \begin{array}{c|c} M & v\\ \hline 0 & 1 \end{array}\right) \)

where M is an n×n matrix over K, v an n × 1 column vector, 0 is a 1 × n row of zeros, and 1 is the 1 × 1 identity block matrix.

Formally, Aff(V) is naturally isomorphic to a subgroup of \( \operatorname{GL}(V \oplus K), with V embedded as the affine plane \( \{(v,1) | v \in V\} \) , namely the stabilizer of this affine plane; the above matrix formulation is the (transpose of) the realization of this, with the (n × n and 1 × 1) blocks corresponding to the direct sum decomposition V \oplus K.

A similar representation is any (n + 1)×(n + 1) matrix in which the entries in each column sum to 1.[1] The similarity P for passing from the above kind to this kind is the (n + 1)×(n + 1) identity matrix with the bottom row replaced by a row of all ones.

Each of these two classes of matrices is closed under matrix multiplication.

Planar affine group

According to Artzy,[2] "The linear part of each affinity [of the real affine plane] can be brought into one of the following standard forms by a coordinate transformation followed by a dilation from the origin:

\( x \mapsto a x + b y, \quad y \mapsto - b x + a y, \quad a, b \ne 0, \quad a^2 + b^2 = 1, \)
\( x \mapsto x + by, \quad y \mapsto y, \quad b \ne 0, \)
\( x \mapsto a x, \quad y \mapsto y/a, \quad a \ne 0 \) , where the coefficients a, b, c, and d are real numbers."

Case (1) corresponds to similarity transformations which generate a subgroup of similarities. Euclidean geometry corresponds to the subgroup of congruencies. It is characterized by Euclidean distance or angle, which are invariant under the subgroup of rotations.

Case (2) corresponds to shear mappings. An important application is absolute time and space where Galilean transformations relate frames of reference. They generate the Galilean group.

Case (3) corresponds to squeeze mapping. These transformations generate a subgroup, of the planar affine group, called the Lorentz group of the plane. The geometry associated with this group is characterized by hyperbolic angle, which is a measure that is invariant under the subgroup of squeeze mappings.

Using the above matrix representation of the affine group on the plane, the matrix M is a 2 × 2 real matrix. Accordingly, a non-singular M must have one of three forms that correspond to the trichotomy of Artzy.
Other affine groups
General case

Given any subgroup G < GL(V) of the general linear group, one can produce an affine group, sometimes denoted \( \operatorname{Aff}(G) \) analogously as \( \operatorname{Aff}(G) := V \rtimes G. \)

More generally and abstractly, given any group G and a representation of G on a vector space V, \( \rho\colon G \to \operatorname{GL}(V) \) one gets[3] an associated affine group \( V \rtimes_\rho G \) : one can say that the affine group obtained is “a group extension by a vector representation”, and as above, one has the short exact sequence:

\( 1 \to V \to V \rtimes_\rho G \to G \to 1. \)

Special affine group

Main article: Special affine group

The subset of all invertible affine transformations preserving a fixed volume form, or in terms of the semi-direct product, the set of all elements (M,v) with M of determinant 1, is a subgroup known as the special affine group.

Projective subgroup

Presuming knowledge of projectivity and the projective group of projective geometry, the affine group can be easily specified. For example, Günter Ewald wrote:.[4]

The set \( \mathfrak{P} \) of all projective collineations of Pn is a group which we may call the projective group of Pn. If we proceed from Pn to the affine space An by declaring a hyperplane ω to be a hyperplane at infinity, we obtain the affine group \( \mathfrak{A} \) of An as the subgroup of \( \mathfrak{P} \) consisting of all elements of \( \mathfrak{P} \) that leave ω fixed.

\( \mathfrak{A} \subset \mathfrak{P} \)

Poincaré group
Main article: Poincaré group

The Poincaré group is the affine group of the Lorentz group \( O(1,3): \mathbf{R}^{1,3}\rtimes \operatorname{O}(1,3) \)

This example is very important in relativity.

See also

Related articles on a diagram


David G. Poole, "The Stochastic Group'", American Mathematical Monthly, volume 102, number 9 (November, 1995), pages 798–801
Artzy p 94
Since \operatorname{GL}(V) < \operatorname{Aut}(V). Note that this containment is in general proper, since by “automorphisms” one means group automorphisms, i.e., they preserve the group structure on V (the addition and origin), but not necessarily scalar multiplication, and these groups differ if working over R.

Günter Ewald (1971) Geometry: An Introduction, p. 241, Belmont: Wadsworth ISBN0-534-0034-7

Rafael Artzy (1965) Linear Geometry, Chapter 2-6 Subgroups of the Plane Affine Group over the Real Field, Addison-Wesley.
Roger Lyndon (1985) Groups and Geometry, Section VI.1, Cambridge University Press, ISBN 0-521-31694-4.

Mathematics Encyclopedia

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