Since you have more points than is needed, you can use all of the points and solve the over-complete system to get a potentially more accurate transformation matrix (this is useful if you are not positive about the accuracy of the transformed coordinates).

In more details, you can can represent the transformation matrix as

```
a b c
-b a d
0 0 1
```

for some parameters a, b, and c (if you really need to, you can work out the angle and xy-translations from these a, b, and c). Then we have these two equations from each of the four points (x_i, y_i) and result (x_i', y_i'):

```
a x_i + b y_i + c = x_i'
a y_i + -b x_i + d = y_i'
```

Then you can rewrite the eight equations as a system of linear equations with variables (a, b, c, d) as follows (in matrix form):

```
x_1 y_1 1 0 x_1'
y_1 -x_1 0 1 a y_1'
x_2 y_2 1 0 b x_2'
y_2 -x_2 0 1 * c = y_2'
x_3 y_3 1 0 d x_3'
y_3 -x_3 0 1 y_3'
x_4 y_4 1 0 x_4'
y_4 -x_4 0 1 y_4'
```

or Ax = B, where A is the matrix on the left, x = [a b c d]', and B = the vector on the right.

Now, decompose A using SVD to get UDV'. Then x can be found as VD^{-1}U'B, where D^{-1} is the inverse of the diagonal matrix D. For more information on SVD, look at Singular Valude Decomposition (SVD).