Lets say I have
image2 obtained from a webcam. For taking the
image2, the webcam undergoes a rotation (yaw, pitch, roll) and a translation.
What I want: Remove the rotation from
image2 so that only the translation remains (to be precise: my tracked points
image2 will be rotated to the the same values as in
image1 so that only the translation component remains).
What I have done/tried so far:
- I tracked corresponding features from
- Calculated the fundamental matrix
RANSACto remove outliers.
- Calibrated the camera so that I got a
CAM_MATRIX(fx, fy and so on).
- Calculated Essential Matrix from
E = cam_matrix^t * F * cam_matrix)
- Decomposed the E matrix with OpenCV's SVD function so that I have a rotation matrix and translation vector. -I know that there are 4 combinations and only 1 is the right translation vector/rotation matrix.
So my thought was: I know that the camera movement from
image2 won't be more than lets say about 20°/AXIS so I can eliminate at least 2 possibilities where the angles are too far off.
For the 2 remaining I have to triangulate the points and see which one is the correct one (I have read that I only need 1 , but due possible errors/outliers it should be done with some more to be sure which one is the right). I think I could use the OpenCV's triangulation function for this? Is my thought right so far? Do I need to calculate the projection error?
Let's move on and assume that I finally obtained the right
How do I continue? I tried to multiply the normal, as well as transposed rotation matrix which should reverse the rotation (?) (for testing purpose I just tried both possible combinations of R|t, I have not done the triangulation in code yet) with a tracked point in
image2. but the calculated point is way too far off from what it should be. Do I need the calibration matrix here as well?
So how can I invert the rotation applied to
image2? (to be exact, apply the inverse rotation to my
std::vector<cv::Point2f> array which contains the tracked (x,y) points from
Displaying the de-rotated image would be also nice to have. This is done with
warpPerspective function? Like in this post ?
(I just don't fully understand what the purpose of A1/A2 and dist in the T matrix is or how I can adopt this solution to solve my problem.)