Examples of groups


Some elementary examples of groups in mathematics are given on Group.
Further examples are listed here.

Permutations of a set of three elements

Consider three colored blocks, initially placed in the order RGB. Let a be the operation "swap the first block and the second block", and b be the operation "swap the second block and the third block".
We can write xy for the operation "first do y, then do x"; so that ab is the operation RGB → RBG → BRG, which could be described as "move the first two blocks one position to the right and put the third block into the first position". If we write e for "leave the blocks as they are", then we can write the six permutations of the three blocks as follows:
Note that aa has the effect RGB → GRB → RGB; so we can write aa = e. Similarly, bb = = e; = = e; so every element has an inverse.
By inspection, we can determine associativity and closure; note in particular that b = bab = b.
Since it is built up from the basic operations a and b, we say that the set generates this group. The group, called the symmetric group S3, has order 6, and is non-abelian.

The group of translations of the plane

A translation of the plane is a rigid movement of every point of the plane for a certain distance in a certain direction.
For instance "move in the North-East direction for 2 miles" is a translation of the plane.
If you have two such translations a and b, they can be composed to form a new translation ab as follows: first follow the prescription of b, then that of a.
For instance, if
and
then
.
The set of all translations of the plane with composition as operation forms a group:
  1. If a and b are translations, then ab is also a translation.
  2. Composition of translations is associative: ∘ c = a ∘.
  3. The identity element for this group is the translation with prescription "move zero miles in whatever direction you like".
  4. The inverse of a translation is given by walking in the opposite direction for the same distance.
This is an abelian group and our first example of a Lie group: a group which is also a manifold.

The [symmetry group] of a square: [dihedral group] of order 8


Dih4 as 2D point group, D4, ,, order 4, with a 4-fold rotation and a mirror generator.

Dih4 in 3D dihedral group D4, +,, order 4, with a vertical 4-fold rotation generator order 4, and 2-fold horizontal generator

of Dih4
Groups are very important to describe the symmetry of objects, be they geometrical or algebraic.
As an example, we consider a glass square of a certain thickness.
In order to describe its symmetry, we form the set of all those rigid movements of the square that don't make a visible difference.
For instance, if you turn it by 90° clockwise, then it still looks the same, so this movement is one element of our set, let's call it a.
We could also flip it horizontally so that its underside becomes its top side, while the left edge becomes the right edge.
Again, after performing this movement, the glass square looks the same, so this is also an element of our set and we call it b.
Then there's of course the movement that does nothing; it's denoted by e.
Now if you have two such movements x and y, you can define the composition xy as above: you first perform the movement y and then the movement x.
The result will leave the slab looking like before.
The point is that the set of all those movements, with composition as operation, forms a group.
This group is the most concise description of the square's symmetry.
Chemists use symmetry groups of this type to describe the symmetry of crystals and molecules.

Generating the group

Let's investigate our squares symmetry group some more.
Right now, we have the elements a, b and e, but we can easily form more:
for instance aa, also written as a2, is a 180° degree turn.
a3 is a 270° clockwise rotation.
We also see that b2 = e and also a4 = e.
Here's an interesting one: what does ab do?
First flip horizontally, then rotate.
Try to visualize that ab = ba3.
Also, a2b is a vertical flip and is equal to ba2.
We say that elements a, b and e generate the group.
This group of order 8 has the following Cayley table:
oebaa2a3aba2ba3b
eebaa2a3aba2ba3b
bbea3ba2baba3a2a
aaaba2a3ea2ba3bb
a2a2a2ba3eaa3bbab
a3a3a3beaa2baba2b
abababa3ba2bea3a2
a2ba2ba2abba3baea3
a3ba3ba3a2babba2ae

For any two elements in the group, the table records what their composition is.
Here we wrote "a3b" as a shorthand for a3b.
In mathematics this group is known as the dihedral group of order 8, and is either denoted Dih4, D4 or D8, depending on the convention.
This was an example of a non-abelian group: the operation ∘ here is not commutative, which you can see from the table; the table is not symmetrical about the main diagonal.
The dihedral group of order 8 is isomorphic to the :File:Dihedral group of order 8; Cayley table ; subgroup of S4.svg|permutation group generated by and.

Normal subgroup

This version of the Cayley table shows that this group has one normal subgroup shown with a red background. In this table r means rotations, and f means flips. Because the subgroup in normal, the left coset is the same as the right coset.

Free group on two generators

The free group with two generators a and b consists of all finite strings that can be formed from the four symbols a, a−1, b and b−1 such that no a appears directly next to an a−1 and no b appears directly next to a b−1.
Two such strings can be concatenated and converted into a string of this type by repeatedly replacing the "forbidden" substrings with the empty string.
For instance: "abab−1a−1" concatenated with
"abab−1a" yields "abab−1a−1abab−1a", which gets reduced to "abaab−1a".
One can check that the set of those strings with this operation forms a group with neutral element the empty string ε := "".
This is another infinite non-abelian group.
Free groups are important in algebraic topology; the free group in two generators is also used for a proof of the Banach–Tarski paradox.

The set of maps

The sets of maps from a set to a group

Let G be a group and S a nonempty set.
The set of maps M is itself a group; namely for two maps f,g of S into G we define fg to be the map such that = f'g for every xS and f−1 to be the map such that f−1 = f−1.
Take maps f, g, and h in M.
For every x in S, f and g are both in G, and so is.
Therefore, fg is also in M, or M is closed.
For = h = g)h = f
'h) = f = ,
M is associative.
And there is a map i such that i = e where e is the unit element of G.
The map i makes all the functions f in M such that
if = fi = f, or i is the unit element of M.
Thus, M is actually a group.
If G is commutative, then = f'g = g'f = .
Therefore, so is M.

Automorphism groups

Groups of permutations

Let G be the set of bijective mappings of a set S onto itself. Then G forms a group under ordinary composition of mappings. This group is called the symmetric group, and is commonly denoted Sym, ΣS, or. The unit element of G is the identity map of S. For two maps f and g in G are bijective, fg is also bijective. Therefore, G is closed. The composition of maps is associative; hence G is a group. S may be either finite or infinite.

Matrix groups

If n is some positive integer, we can consider the set of all invertible n by n matrices over the reals, say.
This is a group with matrix multiplication as operation. It is called the general linear group, GL.
Geometrically, it contains all combinations of rotations, reflections, dilations and skew transformations of n-dimensional Euclidean space that fix a given point.
If we restrict ourselves to matrices with determinant 1, then we get another group, the special linear group, SL.
Geometrically, this consists of all the elements of GL that preserve both orientation and volume of the various geometric solids in Euclidean space.
If instead we restrict ourselves to orthogonal matrices, then we get the orthogonal group O.
Geometrically, this consists of all combinations of rotations and reflections that fix the origin.
These are precisely the transformations which preserve lengths and angles.
Finally, if we impose both restrictions, then we get the special orthogonal group SO, which consists of rotations only.
These groups are our first examples of infinite non-abelian groups. They are also happen to be Lie groups. In fact, most of the important Lie groups can be expressed as matrix groups.
If this idea is generalised to matrices with complex numbers as entries, then we get further useful Lie groups, such as the unitary group U.
We can also consider matrices with quaternions as entries; in this case, there is no well-defined notion of a determinant, but we can still define a group analogous to the orthogonal group, the symplectic group Sp.
Furthermore, the idea can be treated purely algebraically with matrices over any field, but then the groups are not Lie groups.
For example, we have the general linear groups over finite fields. The group theorist J. L. Alperin has written that "The typical example of a finite group is GL, the general linear group of n dimensions over the field with q elements. The student who is introduced to the subject with other examples is being completely misled." of the American Mathematical Society, 10

Some more finite groups