I am trying to triangulate some points with OpenCV and I found this cv::triangulatePoints() function. The problem is that there is almost no documentation or examples of it.

I have some doubts about it.

  1. What method does it use? I've making a small research about triangulations and there are several methods (Linear, Linear LS, eigen, iterative LS, iterative eigen,...) but I can't find which one is it using in OpenCV.

  2. How should I use it? It seems that as an input it needs a projection matrix and 3xN homogeneous 2D points. I have them defined as std::vector<cv::Point3d> pnts, but as an output it needs 4xN arrays and obviously I can't create a std::vector<cv::Point4d> because it doesn't exist, so how should I define the output vector?

For the second question I tried: cv::Mat pnts3D(4,N,CV_64F); and cv::Mat pnts3d;, neither seems to work (it throws an exception).

  • Did you look on OpenCV documentation website?
    – sgarizvi
    Apr 30 '13 at 8:41
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    @sgar91 indeed I did, but that documentation does not solve any of my questions! Apr 30 '13 at 8:42
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    @Willy checked and tested already :D. I came prepared! That code is not completely correct. In the function InterativeLinearLStraingulation() the iterations always breaks at the second time, because variables u,u1,P and P1 are not updated, making the condition to be true and break the loop. I am triying to read the original book and correct the code, but it is not straightforward :S Apr 30 '13 at 11:03
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    @Willy also checked the result without iteration (it should work) but it seems it doesnt work. The results I get are not crazy, but sure not correct. Apr 30 '13 at 11:04
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    Read the source for more info: opencv\modules\calib3d\src\triangulate.cpp
    – LovaBill
    Apr 30 '13 at 11:56

1.- The method used is Least Squares. There are more complex algorithms than this one. Still it is the most common one, as the other methods may fail in some cases (i.e. some others fails if points are on plane or on infinite).

The method can be found in Multiple View Geometry in Computer Vision by Richard Hartley and Andrew Zisserman (p312)

2.-The usage:

cv::Mat pnts3D(1,N,CV_64FC4);
cv::Mat cam0pnts(1,N,CV_64FC2);
cv::Mat cam1pnts(1,N,CV_64FC2);

Fill the 2 chanel point Matrices with the points in images.

cam0 and cam1 are Mat3x4 camera matrices (intrinsic and extrinsic parameters). You can construct them by multiplying A*RT, where A is the intrinsic parameter matrix and RT the rotation translation 3x4 pose matrix.


NOTE: pnts3D NEEDs to be a 4 channel 1xN cv::Mat when defined, throws exception if not, but the result is a cv::Mat(4,N,cv_64FC1) matrix. Really confusing, but it is the only way I didn't got an exception.

UPDATE: As of version 3.0 or possibly earlier, this is no longer true, and pnts3D can also be of type Mat(4,N,CV_64FC1) or may be left completely empty (as usual, it is created inside the function).

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    Thanks, a good starting point. Man, OpenCV's documentation is BAD. I mean, it's better than no documentation at all, but still...
    – user312650
    Jun 26 '13 at 9:02
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    This reply was very useful thanks...opencv documentation lacks such an example
    – mkuse
    Oct 9 '14 at 15:28
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    Very nice answer. OpenCV docs suck. Great elaboration on such poor documentation.
    – rayryeng
    Mar 4 '15 at 15:28
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    The last paragraph is not true anymore; in the current version (I have 3.0 rc installed), Mat pnts3D(4, N, CV_64FC1) also works.
    – oarfish
    Jun 28 '15 at 18:35
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    Still can't understand why triangulation methods aren't well implemented in OpenCV yet. Jul 14 '15 at 6:59

A small addition to @Ander Biguri's answer. You should get your image points on a non-undistorted image, and invoke undistortPoints() on the cam0pnts and cam1pnts, because cv::triangulatePoints expects the 2D points in normalized coordinates (independent from the camera) and cam0 and cam1 should be only [R|t^T] matricies you do not need to multiple it with A.

  • I am not sure if they changed the code or not, but I am pretty sure you needed to at the moment of the answer. A moderator did modify my answer adding a bit more of explanation there, agreeing with me. Apr 23 '15 at 10:07
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    Dunno, but I could not make it work the way you posted (however it does make perfectly sense), and wanted to share the way I did, maybe someone will bump into this again. ;) Apr 24 '15 at 11:38
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    I would agree Bálint Kriván as Ander Biruis' solution is using distorted points. Multiplying the camera matrix A does only transfer those points into the camera system not dealing with any distortion at all. In my opinion this could work well with small distortion but undistorted points should definitely be used. Jul 14 '15 at 6:54
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    So how is it in the end? Do I need to multiply with A if I run my point detection on undistorted images? Thanks. May 4 '16 at 10:10
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    you should do undistortPoints() instead of undistort() on the image, then you don't need A. May 10 '16 at 19:10

Thanks to Ander Biguri! His answer helped me a lot. But I always prefer the alternative with std::vector, I edited his solution to this:

std::vector<cv::Point2d> cam0pnts;
std::vector<cv::Point2d> cam1pnts;
// You fill them, both with the same size...

// You can pick any of the following 2 (your choice)
// cv::Mat pnts3D(1,cam0pnts.size(),CV_64FC4);
cv::Mat pnts3D(4,cam0pnts.size(),CV_64F);


So you just need to do emplace_back in the points. Main advantage: you do not need to know the size N before start filling them. Unfortunately, there is no cv::Point4f, so pnts3D must be a cv::Mat...

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    Fortunately this fucntion seem to accept better inputs now (2017), when I wrote the question/answer (2013) it was a mess! May 8 '17 at 7:18
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    The doc is still a little bit messy, so your answer helped me doing it! thanks! May 8 '17 at 12:38
  • Much cleaner. Thanks for the answer.
    – rayryeng
    Sep 24 '18 at 1:30

I tried cv::triangulatePoints, but somehow it calculates garbage. I was forced to implement a linear triangulation method manually, which returns a 4x1 matrix for the triangulated 3D point:

Mat triangulate_Linear_LS(Mat mat_P_l, Mat mat_P_r, Mat warped_back_l, Mat warped_back_r)
    Mat A(4,3,CV_64FC1), b(4,1,CV_64FC1), X(3,1,CV_64FC1), X_homogeneous(4,1,CV_64FC1), W(1,1,CV_64FC1);
    W.at<double>(0,0) = 1.0;
    A.at<double>(0,0) = (warped_back_l.at<double>(0,0)/warped_back_l.at<double>(2,0))*mat_P_l.at<double>(2,0) - mat_P_l.at<double>(0,0);
    A.at<double>(0,1) = (warped_back_l.at<double>(0,0)/warped_back_l.at<double>(2,0))*mat_P_l.at<double>(2,1) - mat_P_l.at<double>(0,1);
    A.at<double>(0,2) = (warped_back_l.at<double>(0,0)/warped_back_l.at<double>(2,0))*mat_P_l.at<double>(2,2) - mat_P_l.at<double>(0,2);
    A.at<double>(1,0) = (warped_back_l.at<double>(1,0)/warped_back_l.at<double>(2,0))*mat_P_l.at<double>(2,0) - mat_P_l.at<double>(1,0);
    A.at<double>(1,1) = (warped_back_l.at<double>(1,0)/warped_back_l.at<double>(2,0))*mat_P_l.at<double>(2,1) - mat_P_l.at<double>(1,1);
    A.at<double>(1,2) = (warped_back_l.at<double>(1,0)/warped_back_l.at<double>(2,0))*mat_P_l.at<double>(2,2) - mat_P_l.at<double>(1,2);
    A.at<double>(2,0) = (warped_back_r.at<double>(0,0)/warped_back_r.at<double>(2,0))*mat_P_r.at<double>(2,0) - mat_P_r.at<double>(0,0);
    A.at<double>(2,1) = (warped_back_r.at<double>(0,0)/warped_back_r.at<double>(2,0))*mat_P_r.at<double>(2,1) - mat_P_r.at<double>(0,1);
    A.at<double>(2,2) = (warped_back_r.at<double>(0,0)/warped_back_r.at<double>(2,0))*mat_P_r.at<double>(2,2) - mat_P_r.at<double>(0,2);
    A.at<double>(3,0) = (warped_back_r.at<double>(1,0)/warped_back_r.at<double>(2,0))*mat_P_r.at<double>(2,0) - mat_P_r.at<double>(1,0);
    A.at<double>(3,1) = (warped_back_r.at<double>(1,0)/warped_back_r.at<double>(2,0))*mat_P_r.at<double>(2,1) - mat_P_r.at<double>(1,1);
    A.at<double>(3,2) = (warped_back_r.at<double>(1,0)/warped_back_r.at<double>(2,0))*mat_P_r.at<double>(2,2) - mat_P_r.at<double>(1,2);
    b.at<double>(0,0) = -((warped_back_l.at<double>(0,0)/warped_back_l.at<double>(2,0))*mat_P_l.at<double>(2,3) - mat_P_l.at<double>(0,3));
    b.at<double>(1,0) = -((warped_back_l.at<double>(1,0)/warped_back_l.at<double>(2,0))*mat_P_l.at<double>(2,3) - mat_P_l.at<double>(1,3));
    b.at<double>(2,0) = -((warped_back_r.at<double>(0,0)/warped_back_r.at<double>(2,0))*mat_P_r.at<double>(2,3) - mat_P_r.at<double>(0,3));
    b.at<double>(3,0) = -((warped_back_r.at<double>(1,0)/warped_back_r.at<double>(2,0))*mat_P_r.at<double>(2,3) - mat_P_r.at<double>(1,3));
    return X_homogeneous;

the input parameters are two 3x4 camera projection matrices and a corresponding left/right pixel pair (x,y,w).


Alternatively you could use the method from Hartley & Zisserman implemented here: http://www.morethantechnical.com/2012/01/04/simple-triangulation-with-opencv-from-harley-zisserman-w-code/

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    The code from Chris linking to morethantechnical is quite working with some adjustments. The guy from morethantechnical is one of the authors of the Mastering OpenCV book. But it should be said that there are some bugs in it. Jul 14 '15 at 6:58

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