# Tag Info

38

Disparity map refers to the apparent pixel difference or motion between a pair of stereo image. To experience this, try closing one of your eyes and then rapidly close it while opening the other. Objects that are close to you will appear to jump a significant distance while objects further away will move very little. That motion is the disparity. In a pair ...

25

Disparity Disparity refers to the distance between two corresponding points in the left and right image of a stereo pair. If you look at the image below you see a labelled point X (ignore X1, X2 & X3). By following the dotted line from X to OL you see the intersection point with the left hand plane at XL. The same principal applies with the right-hand ...

12

Extract from opencv doc : " The function stereoRectify computes the rotation matrices for each camera that (virtually) make both camera image planes the same plane. Consequently, that makes all the epipolar lines parallel and thus simplifies the dense stereo correspondence problem. On input the function takes the matrices computed by stereoCalibrate() and ...

10

5

One of the easiest methods to understand the disparity would be to blink your eyes, one at a time, alternating between your left and right eye. If you observe, the objects closer to you would appear to jump about their position more than the objects further away. This shift is would be negligible as the objects move away. Therefore, in the disparity map, the ...

4

To answer your question, the Q matrix required by reprojectImageTo3D represents the mapping from a pixel position and associated disparity (i.e. of the form [u; v; disp; 1]) to the corresponding 3D point [X; Y; Z; 1]. Unfortunately, you cannot derive this relation without knowing the cameras' intrinsics (matrix K) and extrinsics (rotation & translation ...

4

EDIT: Admittedly, this is only a partial answer, since I am only explaining why this is even possible with these fitting methods and not how to improve the input keypoints to avoid this problem from the start. There are problems with the distribution of your keypoint matches, as noted in the other answers, and there are ways to address that at the stage of ...

4

The simple formula is valid if and only if the motion from left camera to right one is a pure translation (in particular, parallel to the horizontal image axis). In practice this is hardly ever the case. It is common, for example, to perform the matching after rectifying the images, i.e. after warping them using a known Fundamental Matrix, so that ...

3

your code initially crashed for me in gemm(), changing T to a 3x1 vec seemed to help: // Mat_<double> used here for easy << initialization cv::Mat_<double> cameraMatrix1(3,3); // 3x3 matrix cv::Mat_<double> distCoeffs1(5,1); // 5x1 matrix for five distortion coefficients cv::Mat_<double> cameraMatrix2(3,3); // 3x3 matrix ...

3

I don't think that there is in OpenCV, but you do have alternatives. There is C++ code available, and it wouldn't be hard to make it interact with OpenCV: In the Middlebury stereo website that include graph cut and belief propagation for stereo There is also Graphcut code from the University of Western Ontario which is really good.

3

The Otto-Chau stereo matching algorithm is very effective and combines adaptive least squares patch matching with sub-pixel precision together with region growing over the matched images: Otto, G. P., Chau, T. K. W., 1989. ‘Region-growing’ algorithm for matching of terrain images. Image Vision Computing, 7(2), pp. 83-94. It's an area based approach so does ...

3

I know its too late for your answer, but I guess it would be useful for someone in the future. Actually, the problem in your case is two fold, Degenerate location of features, i.e., The location of features is mostly localized (on you :P) and not well-spread throughout the image. These matches are sort of on the same plane. I know you would argue that your ...

2

I still haven't found the problem, but I did see some things you might want to change. You're not checking the return value of _mm_malloc, though. If it's failing, that would explain it. (Maybe it doesn't like allocating 32-byte aligned memory?) If you're running your code under a memory checker or something, then maybe it doesn't like reading from ...

2

Another way to get better SURF features is to set 'NumOctaves' in detectSURFFeatures(rgb2gray(I1),'NumOctaves',5); to larger values. I am facing the same problem and this has helped (a little bit).

2

If you have rectified images, finding disparity is a matter of calculating costs between pixels in left and right images on the same horizontal line. You can take a few selected points in the images (for example the ones that have high gradient or feature points coming from SIFT), set those as roots/seeds of your regions and calculate cost for a range of ...

2

I have made a simple comparison between OpenCV's reprojectImageTo3D() and my own (see below), and also run a test for a correct disparity and Q matrix. // Reproject image to 3D void customReproject(const cv::Mat& disparity, const cv::Mat& Q, cv::Mat& out3D) { CV_Assert(disparity.type() == CV_32F && !disparity.empty()); ...

2

Before you go and do platform specific optimizations, there are plenty of portable optimizations that could be performed. Extract loop invariants, convert index multiplies to increment additions, etc... This may not be exact, but gets the general idea across: int MAXCOST = 32000, numDispXcstep = numDisp*cstep; for (int i = maskRadius; i < rstep - ...

2

Besides possible calibration problems, your images clearly lack some texture for the stereo block matching to work. This algorithm will see many ambiguities and too large disparities on flat (non-tetxured) parts. Note however that the keypoints seem to match well, so even if the rectification output seems weird it is probably correct. You can test your ...

2

Like you said, you have to convert the unit into mm. And for that you need this formulas z = (b*F) / (d*s) mm = (mm * mm) / (pixel * (mm/pixel)) Where z = depth in mm b = baseline in mm F = focal length in mm d = depth in pixel s = sensor size in mm/pixel. (Normally it provide in um, so do conversion before). EDIT Sometime your focal is in pixel ...

2

What you're talking about is depth mapping, or 'disparity mapping', which is the basis of stereoscopic computer vision. The OpenCV project has libraries which do this. I don't know if they directly convert into a rotatable 3D object, which may be what you are looking for, but they probably come close. http://opencv.willowgarage.com/wiki/ ...

2

The form of the Q matrix is given here: http://i.stack.imgur.com/JgW7P.gif. (I would have posted the image directly but don't have enough reputation) In that image, c_x and c_y are the coordinates of the principal point in the left camera (if you did stereo matching with the left camera dominant), c_x' is the x-coordinate of the principal point in the ...

1

I found this write up on a method for calculating a dense disparity map, and if you follow the links you can get the PDF describing their method in detail. Unfortunately my image processing experience doesn't include stereoscopy so I can't comment on the quality of the algorithm presented. http://serdis.dis.ulpgc.es/~lalvarez/research/demos/StereoFlow/ ...

1

A popular and effective way to compute disparities involves graph cuts. Essentially, a graph is created from two images and then cut in such a way as to minimize the energy that results from depth discontinuities in the image. Ramin Zabih at Cornell has many papers on the topic: http://www.cs.cornell.edu/~rdz/graphcuts.html I suggest "Fast Approximate ...

1

The function interp2 interpolates values on a regularly spaced grid, such as a bitmap image. If your pixels didn't lie on a regular grid, then you would use griddata.

1

I assume that matrix A is an image, which means that the pixels are regularly spaced, which means you can use INTERP2. I also assume that you calculate for each pixel individually the interpolated value from A. You can, however, perform the lookup in one step, which will be quite a bit faster. Say A is a 100x100 image, and B is a 10000-by-2 array with ...

1

Yes if the camera (or scene) is moving

1

Disparity map, on stereo systems, is used to obtain depth information - distance to objects in scene. For that, you need the distance between cameras, to be able to convert disparity info to real dimensions. On the other hand, if you have consecutive frames from a static camera, I suppose you want the differences between them. You can obtain it with an ...

1

Yes, " Output 3-channel floating-point image of the same size as disparity . Each element of _3dImage(x,y) contains 3D coordinates of the point (x,y) computed from the disparity map." So it's the floating pointing x,y,z at each pixel coordinate see http://docs.opencv.org/modules/calib3d/doc/camera_calibration_and_3d_reconstruction.html

1

OpenCV's StereoVar object would probably be a good starting point. You can create a StereoVar object like this: StereoVar myStereoVar(int levels, double pyrScale, int nIt, int minDisp, int maxDisp, int poly_n, double poly_sigma, float fi, float lambda, int ...

1

gpu::StereoBM_GPU is the GPU version of cv::StereoBM (documentation link). cv::StereoSGBM uses another algorithm (documentation link), hence the different results. In order to determine why the result of gpu::StereoBM_GPU is wrong, it would be useful to know how you rectified your pair of images.

Only top voted, non community-wiki answers of a minimum length are eligible