I have a 2D polygon and a 2D transformation matrix ** M** that I use to transform the vertices of the polygon. The matrix may describe...

- rotation around
axis,*z* - scaling along
and*x*,*y* - sheering along
and*x*axis,*y* - translation along
and*x*axis.*y*

Since we are in 2D the transformation matrix is of type ** 3x3**. Here as an example a translation matrix by vector

**and a rotation by angle**

*t***:**

*a*```
M_t = |1 0 t2| M_r = | cos(a) sin(a) 0|
|0 1 t1| |-sin(a) cos(a) 0|
|0 0 1 | | 0 0 1|
```

In my custom framework I don't have any access to the matrix values but can apply other matrixes in a row:

```
vertice = ( M_r * M_t ) * vertice
```

The above formula rotates the vertice around (0, 0) by angle ** a** and then translates it by vector

**. I know that matrix multiplications aren't commutative. So the order of multiplications is important.**

*t***My problem** is now that I want to get a transformation matrix ** N** that reflects a rotation

**around the new center of the polygon, followed by a translation**

*R***, after applying an unknown transformation matrix**

*T***. Or in other words: I want to rotate and translate the polygon relative to its position and rotation given by**

*M***.**

*M*I can imagine this way of doing it, incorporating an unknown rotation and translation as part of ** M**:

```
N = R * M * T
```

My questions are:

- Is that mathematically correct?
- What about an unknown sheering and scaling as part of
?*M* - Is there a better way of doing this?