Usually, an affine transormation of 2D points is experssed as

```
x' = A*x
```

Where `x`

is a three-vector `[x; y; 1]`

of original 2D location and `x'`

is the transformed point. The affine matrix `A`

is

```
A = [a11 a12 a13;
a21 a22 a23;
0 0 1]
```

This form is useful when `x`

and `A`

are *knowns* and you wish to recover `x'`

.

However, you can express this relation in a different way.
Let

```
X = [xi yi 1 0 0 0;
0 0 0 xi yi 1 ]
```

and `a`

is a column vector

```
a = [a11; a12; a13; a21; a22; a23]
```

Then

```
X*a = [xi'; yi']
```

Holds for all pairs of corresponding points `x_i, x_i'`

.

This alternative form is very useful when you know the correspondence between pairs of points and you wish to recover the paramters of `A`

.

Stacking all your points in a large matrix `X`

(two rows for each point) you'll have 2*n-by-6 matrix `X`

multiplyied by 6-vector of unknowns `a`

equals a 2*n-by-1 column vector of the stacked corresponding points (denoted by `x_prime`

):

```
X*a = x_prime
```

Solving for `a`

:

```
a = X \ x_prime
```

Recovers the parameters of `a`

in a least-squares sense.

Good luck and stop skipping class!