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The following picture will tell you what I want.

I have the information of the rectangles in the image, width, height, center point and rotation degree. Now, I want to write a script to cut them out and save them as image, but straighten them. As in I want to go from the rectangle shown inside the image to the rectangle that is shown outside.

I am using OpenCV python, please tell me a way to accomplish this.

Kindly show some code as examples of OpenCV Python are hard to find.

Example Image

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If converting form C++ to Python is not of a problem, the above link should be exactly what you're looking for –  sammy Jul 24 '12 at 9:01
@vasile Actually, I don't need perspective transformation. I just need the pixels in the rotated rectangle map to the straight rectangle one by one. –  hakunami Jul 24 '12 at 9:06
If you want just the corner positions, use perspectiveTransform(). If you want all the pixels, this is warpAffine() or warpPerspective() for –  sammy Jul 24 '12 at 9:09
@vasile warpAffine is what I need. Thank you. By the way, do you have any knowledge of the resource for opencv python, you know, not only the offical document, but some thing like tutorial, open project etc. –  hakunami Jul 25 '12 at 5:49

3 Answers 3

up vote 23 down vote accepted

You can use the GetQuadrangleSubPix function to extract a rotated patch, after defining a suitable transformation matrix, as in the following function (where theta is defined in radians):

from cv2 import cv
import numpy as np

def subimage(image, centre, theta, width, height):
   output_image = cv.CreateImage((width, height), image.depth, image.nChannels)
   mapping = np.array([[np.cos(theta), -np.sin(theta), centre[0]],
                       [np.sin(theta), np.cos(theta), centre[1]]])
   map_matrix_cv = cv.fromarray(mapping)
   cv.GetQuadrangleSubPix(image, output_image, map_matrix_cv)
   return output_image

The GetQuadrangleSubPix function has also some options for how/whether to extrapolate when part of the desired patch lies outside the image (see here for details).

So to extract a patch from the following image (as illustrated on the right)

Start Image After finding the desired rectangle

the above function can be used as follows

im = cv.LoadImage('owl.jpg')
patch = subimage(im, (110, 125), np.pi / 6.0, 100, 200)
cv.SaveImage('patch.jpg', patch)

which leads to


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You are awesome! You know that? –  hakunami Jul 25 '12 at 5:37
How would one do this using the newer c++ interface of OpenCV? –  mcvz Sep 16 '13 at 13:38
@mcvz do you mean using the new Python bindings that mirror the C++ interface (i.e. cv2 rather than cv2.cv), or in C++ itself? –  rroowwllaanndd Sep 18 '13 at 17:30
@rroowwllaanndd in C++ itself. I actually implemented a function all ready. I'll post it as an answer. –  mcvz Sep 23 '13 at 7:44

This is my C++ version that performs the same task. I have noticed it is a bit slow. If anyone sees anything that would improve the performance of this function, then please let me know. :)

bool extractPatchFromOpenCVImage( cv::Mat& src, cv::Mat& dest, int x, int y, double angle, int width, int height) {

  // obtain the bounding box of the desired patch
  cv::RotatedRect patchROI(cv::Point2f(x,y), cv::Size2i(width,height), angle);
  cv::Rect boundingRect = patchROI.boundingRect();

  // check if the bounding box fits inside the image
  if ( boundingRect.x >= 0 && boundingRect.y >= 0 &&
       (boundingRect.x+boundingRect.width) < src.cols &&  
       (boundingRect.y+boundingRect.height) < src.rows ) { 

    // crop out the bounding rectangle from the source image
    cv::Mat preCropImg = src(boundingRect);

    // the rotational center relative tot he pre-cropped image
    int cropMidX, cropMidY;
    cropMidX = boundingRect.width/2;
    cropMidY = boundingRect.height/2;

    // obtain the affine transform that maps the patch ROI in the image to the
    // dest patch image. The dest image will be an upright version.
    cv::Mat map_mat = cv::getRotationMatrix2D(cv::Point2f(cropMidX, cropMidY), angle, 1.0f);
    map_mat.at<double>(0,2) += static_cast<double>(width/2 - cropMidX);
    map_mat.at<double>(1,2) += static_cast<double>(height/2 - cropMidY);

    // rotate the pre-cropped image. The destination image will be
    // allocated by warpAffine()
    cv::warpAffine(preCropImg, dest, map_mat, cv::Size2i(width,height)); 

    return true;
  } // if
  else {
    return false;
  } // else
} // extractPatch
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In the examples I have seen you do not have to allocate memory for the destination matrix when you do warpAffine i.e. this line dest.create(width, height, src.type()); is simply cv::Mat dest; Do you know if this is best practice to do this? Does warpAffine automatically allocated the matrix at the correct size if you miss this step out? –  Robert Oct 18 '13 at 18:57
@Robert Apologies for a delayed response. Which examples are you referring to? As far as I know, the destination matrix has to be pre-allocated before calling the function cv::warpAffine(). I will check for you. –  mcvz Dec 30 '13 at 9:50
@Robert The c++ warpAffine() takes a minimum of 4 arguments. The src and dst images, the affine transform matrix and the size of the destination matrix. When the dest matrix is unallocated and we pass dest.size() = (0,0) as the size argument of warpAffine(), the output dest matrix will have the same size as the input matrix. Otherwise, if the size argument of warpAffine() is anything else, the output matrix will be that size. I have no answer for you regarding the best practice in this case. Hope it helps. –  mcvz Dec 30 '13 at 11:22

I had problems of wrong offsets with the here and in similar questions posted solutions. So I did the math and came up with the following solution that works:

def subimage(self,image, center, theta, width, height):
    theta *= 3.14159 / 180 # convert to rad

    v_x = (cos(theta), sin(theta))
    v_y = (-sin(theta), cos(theta))
    s_x = center[0] - v_x[0] * (width / 2) - v_y[0] * (height / 2)
    s_y = center[1] - v_x[1] * (width / 2) - v_y[1] * (height / 2)

    mapping = np.array([[v_x[0],v_y[0], s_x],
                        [v_x[1],v_y[1], s_y]])

    return cv2.warpAffine(image,mapping,(width, height),flags=cv2.WARP_INVERSE_MAP,borderMode=cv2.BORDER_REPLICATE)

For reference here is an image that explains the math behind it:

If there are questions about the math, ask them as comments and I will try to answer them.

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