# OpenCV - 3D real world coordinates from two perpendicular 2D images

There probably are answers, but I simply did not understand what I found. Maybe it's the language barrier. So I've decided to finally ask. What I need is to find 3D coordinates from two videos recorded by two cameras. The setup is like this: I can't seem to grasp how to do this. What I have is

• Pixel coordinates on both pictures (relative to 0,0 point on the picture)
• Focal lengths
• distance of both cameras from the 0,0,0 real world point (Ax and By)
• size of the pixel
• I know the angle between cameras is 90 degrees

What now? OpenCV docs contain this formula: I don't know what 's' is, nor the [R|T] matrix, the extrinsic parameters. I don't know where the principal point is and how to find it (cx, cy) and I can only assume setting it to 0 won't be catastrophic. Also, this looks like it's using only one of the 2D images, not both.

I know of `calibrateCamera`, `solvePnP`. and `stereoCalibrate` functions, but I don't know how to use them.

I know just how complex it gets when you have cameras as two "eyes", I hoped it'd be easier in a situation when the cameras are shooting perpendicular images. I now have a formula to calculate the 3D coordinates, but it's not exactly precise. The error is under 1 inch, but 1 inch too much.

``````xa, ya, xb, yb - pixel coordinates from pictures
focalAB - focal length
W = -(Ax*xb*pixelSize - focalB*By)/(xa*pixelSize*xb*pixelSize - focalA*focalB)
X = Ax + W*xa*pixelSize
Y = W*focalA
Z = W*xa*pixelSize
``````

Errors: Those are for focal lengths and pixel size provided by the manafacturer. 5400um and 1,75um. However, the errors are the smallest for the values 4620um and 1,69um, where the biggest one is for 3# X axis, 2,3cm, height errors amost disappear (0,2cm max), and the rest are either 0,1cm or 1-1,5cm.

• You should read a book about stereo vision and learn the basic concept first. – Yang Kui Jul 6 '15 at 9:46
• @YangKui I know, unfortunetly I am pressed for time. I can do the math, I just need the explanation of these few points. Mainly what are the extrinsic parameters and how to find the principal point. The problem is I don't know of any literature on this subject in my language, and the English texts are a tough read. I even tried to do the math myself, and I got pretty close (error under 2cm), except for the Z axis, where the error is quite big – Petersaber Jul 6 '15 at 10:11
• "I can do the math" - ok, then read the section of this tutorial that covers Two View Geometry. The realise that it's not quite so easy, then buy the book, read it and start again ;-). BTW, what is your native language? Maybe there is a suitable reference that has been translated that we could recommend. – Roger Rowland Jul 6 '15 at 10:17
• In order to get the principal point and the extrinsic parameters, you have to calibrate your camera system first. That can be done using the opencv function stereoCalibrate, or use the famous matlab calibration toolbox. Besides, cx cy are definitely not 0s. If the size of your image is [sx, sy], [cx, cy] will be close to [sx / 2, sy / 2]. – Yang Kui Jul 6 '15 at 10:52
• @YangKui I know. And the cx, cy of a 1000x1000 picture would be equal (more or less) to (500, 500) as opposed to (0, 0). So the coordinates are "counted" from top-left, as usual, instead of the center (where we'd have a negative half, 0 at the center, and positive half) – Petersaber Jul 6 '15 at 11:23

The equation you quote is the (single camera) 3D to 2D projection equation. This is a projective geometry equation (hence the 1s as the last coordinates) and everything is up to some scale `s`.

• `s` is this scale factor.
• `R` is the 3x3 Rotation of the camera relative to the world/chosen coordinate system.
• `t` is the translation of the camera origin from the world/chosen coordinate system origin.
• `cx` and `cy` are the principle points in the image - the point of the image plane in pixel units that the Z axis intersects. It is often assumed to be as the center of the image.
• 3D to 2D... so I basicly took a reverse equation to what I want to do? Also, if the camera is perfectly level, will R basicly contain only zeros and ones? And what exactly is a translation of the camera origin? Does that mean the distance from the origin point, (where x y and z intersect on my picture)? A (Ax, 0, 0) matrix? – Petersaber Jul 6 '15 at 11:30
• Yes. But you have to dig more deeply into two-camera reconstruction. In this case it is common to choose one camera at the origin and the other in relation to the first. – Adi Shavit Jul 6 '15 at 11:32

One approach, which I find provides intuition if not a high-performance implementation, is to construct the camera matrix for both cameras and then use nonlinear optimization to solve for `M` minimizing "reprojection error".

So come up with the camera matrices: A's camera matrix will map A's camera center in world coordinates to (0, 0, 0) in A's camera coordinates. The rotation part of A's camera matrix will map (0, 1, 0) in world coordinates to (0, 0, 1) in camera coordinates.

Now you can map world coordinates to A and B image coordinates, so for any (x, y, z) you have a corresponding 4-vector: (x_A, y_A, x_B, y_B). If you throw in the point (A_x, B_y, 0), you get out a 4-vector. The difference between that 4-vector and the measured position is your reprojection error. Throw that at a solver and it should quickly converge on an answer.

You might try ''Multiple View Geometry in Computer Vision'' by Hartley and Zisserman.