a4103
| 3 |
|---|
Group of translations :
Consider 2d space (x,y). In such space a translation is defined by translation vector (Dx,Dy). We use to write :
(27) x' = x + Dx y' = y + Dy
To get the new values x' and y' we use addition. Could we get the same results through a .....multiplication ?
Consider the following matrices :
(28)
Notice they are defined by two independent parameters Dx and Dy. Then the dimension of the group is 2.
Form :
(29)
Notice this is basically different from the simple matricial multiplication
(30) g x r
It is a peculiar group's action.
(31)
By the way, notice we can consider translations in 3d or 4d spaces. The corresponding square matrices, forming groups, are
(32)
(33)
The corresponding action is :
(34)
The group of translations is commutative. Its neutral element is the null-translation.
Groups of matrices : why ?
...With matrices' groups we can combine several operations into a single one, into a single action. Consider the following matrices and the following action :
(35-1)
...We combine two things : a rotation (angle a), plus a translation (Dx,Dy).
The element g of the group G acts on space r = (x,y), not "directly" but through some more refined "action". This group
(35-2)
called "Special Euclid's group SE(2)", acts on 2d space. This name will be explained further.
What is its dimension ? It depends on three free parameters : (a, Dx, Dy), so that its dimension is three. We may write :
gSE (a, Dx, Dy)
Sub-groups.
For us, a group is a set of square matrices. Among this set we can find sub-sets.
gSE (0, Dx, Dy) is the sub-group of translations. gSE (a, 0, 0) is the sub-group of rotations around the origin 0. gSE (0, Dx, 0) is the sub-group of translation parallel to the axis OX.
The above group carries points. These points own no peculiar characteristics. They are... points, nothing else.
...But, later, other groups, which describe physical world, will carry points which will have different characteristics, "attributes" : mass, energy, impulsion, spin....
With the above group only sets of points are interesting to carry. Here appears the fundamental concept of :
Species.
...Our first group carries geometrical objects, which are sets of points, geometrical ("rigid") figures. The most simple set is composed by two points. Consider couples of points in a 2d space :
(35-3)
...On figure (35-3) two couples of points (A,B) and (A',B') have been figured. I can find an element of the group that transforms (A,B) into (A',B') : combining a rotation around the point O and a translation. See figure (35-4).
(35-4)
Now consider the two couples :
(35-5)
Impossible to find any element g (square matrix) of my group G which can carry (A,B) on (A",B"). I will say that:
(A,B) and (A',B') belong to a same species.
(A,B) and (A",B") belong to different species.
The characteristic of a species of couples of points is called length .
This is the definition of length in terms of group theory.
...How can you affirm that two segments have the same length ? Because you can compare them, putting one onto the other one.
...In our group two segments, whose lengths, are different belong to different species, because our group does not rule dilatations or contractions (homothetic transforms). The group which takes that in charge is a different one ("Special Descartes' group" ):
(35-6)
with respect to such group all couples of points form the same species. The dimension of this group is four.
Instead two points, we could consider three or four, these last forming squares, for an example.
(36)
...With respect to the group (35-1), squares whose sides have the same length belong to the same species. But if the sides of two squares are basically different :
(37)
they belong to different species.
This group, ruling 2d translation and rotations around a fixed point of a plane is the Special Euclid's group : SE(2).
Now we imagine easily a similar group acting on a 3d space. The group of 3d and 4d translations were given in (32), (33).
We can imagine easily a group describing translations in a n-dimensional space. But what about rotations ?
...We can imagine rotation in a 3d space. We can even write it with a matrix which contains three angles, the Euler angles : then its dimension is three.
