# Is it possible to obtain fronto-parallel view of image or camera position by 2d-3d points relation?

Is it possible to obtain front-parallel view of image or camera position by 2d-3d points relation using `OpenCV`?

For this I have intrinsic and extrinsic parameters. I have also 3d coordinates of set of control points (which lies in one plane) on image (relation 2d-3d).

In fact I need location and orientation of camera, but it is not difficult to find it if I can convert image to fronto-parallel view.

If it is not possible to do with OpenCV, are the other libraries which can solve this task?

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By the way, is it good idea to write comments which are unrelated with question? – sergtk Jan 12 '12 at 16:22
If you solved the problem but the specific answer isn't there, you should add the right answer yourself and accept it to let others know how to deal with that problem. That's the appropriate protocol. – karlphillip Jan 12 '12 at 16:24
ok, thanks, will keep in mind this in future (anyway I try to add my correct answers) – sergtk Jan 12 '12 at 16:25
I don't think it's unrelated. Users with low AR have a hard time getting answers. By letting you know your AR is starting to get low and you can fix it, I'm preserving your integrity and helping you get help from us. – karlphillip Jan 12 '12 at 16:26
thanks. I fully agree with you, and track what you are speaking about, but it is not always easy to follow. – sergtk Jan 12 '12 at 16:27

Solution is based on the formulas in the OpenCV documentation Camera Calibration and 3D Reconstruction

Let's consider numerical form without distortion coefficient (in contrast with matrix form).

We have `u` and `v`.
It is easy to calculate `x'` and `y'`.
But `x` and `y` can not be calculate because we can choose any non-zero `z`.
Line in 3d corresponds to one point in 2d image.

To solve this we take two points for `z=1` and `z=2`. Then we find 2 points in 3d space which specify line `(x1,y1,z1)` and `(x2,y2,z2)`.

Then we can apply `R`-1 to `(x1,y1,z1)` and `(x2,y2,z2)` which results in line determined by two points `(X1, Y1, Z1)` and `(X1, Y1, Z1)`.

Since our control points lie in one plane (let plane is Z=0 for simplicity) we can find corresponding `X` and `Y` point which is a point in 3d.

After applying normalization from `mm` to pixels we obtain fronto-parallel image.

(If we have input image distorted we should undistort it first)

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