9

I have a number of calibrated cameras taking a pictures of planar scene. For simplicity let's assume there are 3 cameras. Those cameras are undergoing general motion but mostly translation plus some mild rotation. Example positions of cameras

The task is to stitch them altogether. I have no knowledge about 3D coordinates, just a set of images taken with calibrated cameras.

What I do:

I detect features with SURF/SIFT implementations in OpenCV to get initial homographies by using findHomography between each pair of images (1->2, 2->3, 1->3). From those homographies I get initial esitimation of poses of each camera (similiar procedure to this)

Then I try to use bundle adjustment technique to minimize reprojection error for each matching pair. Optimized parameters are three translations values and three rotations values (obtained from Rodrigues' rotation formula) though I can add intrinsic parameters later (focals, principal points, etc).

Assuming image #2 will be reference frame (by having the most amount of matches to other two images) its rotation and translation matrices are identity and zero matrices respectively.

I calculate reprojection of keypoint (visible in both image #2 and image #1) from image #2 to image #1 as (pseudocode)

[x1_; y1_; z1_] = K1*R1*inv(K2)*[x2; y2; 1] + K1*T1/Z2;
x1 = x1_/z1_;
y1 = y1_/z1_;

or

x1 = ((f1/f2)*r11*x2 + (f1/f2)*r12*y2 + f1*r13 + f1*tx/Z2) / ((1/f2)*r31*x2 + (1/f2)*r32*y2 + r33 + tx/Z2)
y1 = ((f1/f2)*r21*x2 + (f1/f2)*r22*y2 + f1*r23 + f1*ty/Z2) / ((1/f2)*r31*x2 + (1/f2)*r32*y2 + r33 + ty/Z2)

where r__ are elements of R1 matrix and both intrinsic matrices are in the form of

[f 0 0]
[0 f 0]
[0 0 1]

I'm assuming Z2 coordinate of reference frame as 1.

Next stage is to warp images #1 and #3 into common coordinate system of image #2 using obtained camera matrices (K1,R1,T1,K3,R3,T3).

The issue is that I have no knowledge about Z1 and Z3 needed for correct reprojection into reference frame of image #2 because invert reprojection from image #1->#2 looks like this:

x2 = ((f2/f1)*R11*x1 + (f2/f1)*R12*y1 + f2*R13 - f0/Z1*(R11*tx + R12*ty + R13*tz)) / ((1/f1)*R31*x1 + (1/f1)*R32*y1 + R33 - 1/Z1*(R31*tx + R32*ty + R33*tz))
y2 = ((f2/f1)*R21*x1 + (f2/f1)*R22*y1 + f2*R23 - f0/Z1*(R21*tx + R22*ty + R23*tz)) / ((1/f1)*R31*x1 + (1/f1)*R32*y1 + R33 - 1/Z1*(R31*tx + R32*ty + R33*tz))

where R__ are elements of inv(R1) matrix.

Is there a better way of calculating reprojection error for bundle adjustment (2d->2d) and then warping images into common coordinates system? I noticed that OpenCV has very similiar framework in their stitching module but it operates under assumption of pure rotation motion which is not the case here.

1
  • Did you thought about 3D triangulation ? You could for example triangulate a point with all but one cameras and reproject it in the last one.
    – cedrou
    Mar 18 '13 at 14:19
1

I autoanswered that question in my post How to get points in stereo image from extrinsic parameters

Note that the method I use (Tested and working!) it is only valid if the object in 3D coordinates (real world!) is planar and it is at Z=0 (the point where you calibrated the extrinsic parameters of the cameras). In that case this method is as precise as your calibration is. Note: for the best calibration check openCVs circle calibrations, it has a reproyection error of 0.018 pixels (tested by a PhD student working in my university).

1

You probably have discovered a bug on the repojection error. It has to do with this line:

[x1_; y1_; z1_] = K1*R1*inv(K2)*[x2; y2; 1] + K1*T1/Z2;

The point [x2; y2; 1] is ambiguous up to a scale constant, C*[x2; y2; 1] and here you are setting C=1 when it is generally unknown. The locus of possibilities manifests itself as an epipolar line in the first view. You can use least-squares triangulation to find the most likely point along this line that the 3D point exists, and then compute the re-projected point as:

[x1_; y1_; z1_] = K1*(R1*X + T1);

and proceed from there as you have above. The 3D coordinates of each such point X in your point cloud can be computed using its corresponding normalized coordinates (x1,y1), (x2,y2),..., as well as the corresponding rotation matrices and translation vectors, by formatting them into the matrix problem:

A X = b

and then solving least-squares:

min |A X - b|_2

which is illustrated on pages 3 and 4 here.

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.