Another question about computer vision.

A camera matrix (also known as projection matrix) maps a 3D point **X** (e.g. in the real world) to an image point **x** (in a photograph, for example) via the following relation:

```
l **x** = P **X**
```

P describes some external and internal characteristics of the camera (its orientation, position and projection properties). When we refer to the projection properties, we use a calibration matrix K. Likewise, R represents the rotation of the camera and t its translation, so we can write P as:

```
P = K [ R | t ]
```

[ R | t ] means the concatenation of the matrix R and t.

```
R is a matrix 3 X 3
t is a vector 3 X 1
K is a matrix 3 X 3
[R | t ] is a matrix 3 X 4
As a consequence, P is a matrix 3 X 4
```

Well, enough introductions. I want to find the translation of the camera matrix P. According to the code in the book Computer Vision with Python, it can be found like this:

```
def rotation_matrix(a):
""" Creates a 3D rotation matrix for rotation
around the axis of the vector a. """
a = array(a).astype('float')
R = eye(4)
R[:3,:3] = linalg.expm([[0,-a[2],a[1]],[a[2],0,-a[0]],[-a[1],a[0],0]])
return R
tmp = rotation_matrix([0,0,1])[:3,:3]
Rt = hstack((tmp,array([[50],[40],[30]])))
P = dot(K, Rt)
K, R = linalg.rq(P[:,:3])
# This part gets rid of some ambiguity in the solutions of K and R
T = diag(sign(diag(K)))
if linalg.det(T) < 0:
T[1,1] *= -1
K = dot(K, T)
R = dot(T, R) # T is its own inverse
t = dot(linalg.inv(K), P[:,3])
```

The code is self-contained. There we have `Rt`

that is the matrix `[R | t]`

. `P`

is calculated as usual and an RQ factorization is performed. However, I don't understand that part. Why are we taking only the first 3 columns? Then we obtain the translation vector as the dot product of `K^{-1}`

and the first 3 columns of P. Why? I haven't found a justification but maybe it's something obvious I'm missing.

By the way, the code seems to be a bit off. When I run it, I get a translation vector `[ 50. -40. 30.]`

instead of `array([[50],[40],[30]])`

that we used as input. We should get exactly the same. I don't know if this is due to the rotation matrix. I would also appreciate any help on that.

Thanks!