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if the squares has connected region in image, how can I detect them.

I have tested the method mentioned in OpenCV C++/Obj-C: Advanced square detection

It did not work well.

Any good ideas ?

squares that has Connected region

import cv2
import numpy as np

def angle_cos(p0, p1, p2):
    d1, d2 = (p0-p1).astype('float'), (p2-p1).astype('float')
    return abs(, d2) / np.sqrt(, d1)*, d2) ) )

def find_squares(img):
    squares = []
    gray = cv2.cvtColor(img, cv2.COLOR_BGR2GRAY)
    # cv2.imshow("gray", gray)

    gaussian = cv2.GaussianBlur(gray, (5, 5), 0)

    temp,bin = cv2.threshold(gaussian, 80, 255, cv2.THRESH_BINARY)
    # cv2.imshow("bin", bin)

    contours, hierarchy = cv2.findContours(bin, cv2.RETR_CCOMP, cv2.CHAIN_APPROX_SIMPLE)

    cv2.drawContours( gray, contours, -1, (0, 255, 0), 3 )

    #cv2.imshow('contours', gray)
    for cnt in contours:
        cnt_len = cv2.arcLength(cnt, True)
        cnt = cv2.approxPolyDP(cnt, 0.02*cnt_len, True)
        if len(cnt) == 4 and cv2.contourArea(cnt) > 1000 and cv2.isContourConvex(cnt):
            cnt = cnt.reshape(-1, 2)
            max_cos = np.max([angle_cos( cnt[i], cnt[(i+1) % 4], cnt[(i+2) % 4] ) for i in xrange(4)])
            if max_cos < 0.1:
    return squares

if __name__ == '__main__':
    img = cv2.imread('123.bmp')

    #cv2.imshow("origin", img)

    squares = find_squares(img)  
    print "Find %d squres" % len(squares)
    cv2.drawContours( img, squares, -1, (0, 255, 0), 3 )
    cv2.imshow('squares', img)


I use some method in the opencv example, but the result is not good.

share|improve this question

3 Answers 3

up vote 9 down vote accepted

Applying a Watershed Transform based on the Distance Transform will separate the objects:

enter image description here

Handling objects at the border is always problematic, and often discarded, so that pink rectangle at top left not separated is not a problem at all.

Given a binary image, we can apply the Distance Transform (DT) and from it obtain markers for the Watershed. Ideally there would be a ready function for finding regional minima/maxima, but since it isn't there, we can make a decent guess on how we can threshold DT. Based on the markers we can segment using Watershed, and the problem is solved. Now you can worry about distinguishing components that are rectangles from those that are not.

import sys
import cv2
import numpy
import random
from scipy.ndimage import label

def segment_on_dt(img):
    dt = cv2.distanceTransform(img, 2, 3) # L2 norm, 3x3 mask
    dt = ((dt - dt.min()) / (dt.max() - dt.min()) * 255).astype(numpy.uint8)
    dt = cv2.threshold(dt, 100, 255, cv2.THRESH_BINARY)[1]
    lbl, ncc = label(dt)

    lbl[img == 0] = lbl.max() + 1
    lbl = lbl.astype(numpy.int32)
    cv2.watershed(cv2.cvtColor(img, cv2.COLOR_GRAY2BGR), lbl)
    lbl[lbl == -1] = 0
    return lbl

img = cv2.cvtColor(cv2.imread(sys.argv[1]), cv2.COLOR_BGR2GRAY)
img = cv2.threshold(img, 0, 255, cv2.THRESH_OTSU)[1]
img = 255 - img # White: objects; Black: background

ws_result = segment_on_dt(img)
# Colorize
height, width = ws_result.shape
ws_color = numpy.zeros((height, width, 3), dtype=numpy.uint8)
lbl, ncc = label(ws_result)
for l in xrange(1, ncc + 1):
    a, b = numpy.nonzero(lbl == l)
    if img[a[0], b[0]] == 0: # Do not color background.
    rgb = [random.randint(0, 255) for _ in xrange(3)]
    ws_color[lbl == l] = tuple(rgb)

cv2.imwrite(sys.argv[2], ws_color)

From the above image you can consider fitting ellipses in each component to determine rectangles. Then you can use some measurement to define whether the component is a rectangle or not. This approach has a greater chance to work for rectangles that are fully visible, and will likely produce bad results for partially visible ones. The following image shows the result of such approach considering that a component is a rectangle if the rectangle from the fitted ellipse is within 10% of component's area.

enter image description here

# Fit ellipse to determine the rectangles.
wsbin = numpy.zeros((height, width), dtype=numpy.uint8)
wsbin[cv2.cvtColor(ws_color, cv2.COLOR_BGR2GRAY) != 0] = 255

ws_bincolor = cv2.cvtColor(255 - wsbin, cv2.COLOR_GRAY2BGR)
lbl, ncc = label(wsbin)
for l in xrange(1, ncc + 1):
    yx = numpy.dstack(numpy.nonzero(lbl == l)).astype(numpy.int64)
    xy = numpy.roll(numpy.swapaxes(yx, 0, 1), 1, 2)
    if len(xy) < 100: # Too small.

    ellipse = cv2.fitEllipse(xy)
    center, axes, angle = ellipse
    rect_area = axes[0] * axes[1]
    if 0.9 < rect_area / float(len(xy)) < 1.1:
        rect = numpy.round(numpy.float64(
        color = [random.randint(60, 255) for _ in xrange(3)]
        cv2.drawContours(ws_bincolor, [rect], 0, color, 2)

cv2.imwrite(sys.argv[3], ws_bincolor)
share|improve this answer
+1 - Nice work. –  Abid Rahman K Feb 21 '13 at 16:42
yep, true, really nice approach, +1. Its horribly fiddly to get the image indices into the correct format, I used to use the same zip unpack method you show here, but I recently realised it can be a lot slower than transposing and copying (should speed be important..) Unfortunetly, copying seems to be required to avoid an opencv exception (for me at least).. –  fraxel Feb 21 '13 at 19:59
The difference is that numpy works by default with (y, x) coords, and OpenCV expects (x, y). @fraxel I didn't measure the performance, but it is likely that the updated code is better in that specific point. –  mmgp Feb 21 '13 at 21:11
@mmgp - yeah I know, its damn annoying - But thanks again, your update helps me out! Its is a good deal quicker than your previous approach, and mine too. I will be using that,.. and watershed (should I ever need it..) in future :) –  fraxel Feb 22 '13 at 3:28
The method is amazing !!! But the speed is too slow. –  Yang Feb 23 '13 at 8:01

Solution 1:

Dilate your image to delete connected components. Find contours of detected components. Eliminate contours which are not rectangles by introducing some measure (ex. ratio perimeter / area).

This solution will not detect rectangles connected to borders.

Solution 2:

Dilate to delete connected components. Find contours. Approximate contours to reduce their points (for rectangle contour should be 4 points). Check if angle between contour lines is 90 degrees. Eliminate contours which have no 90 degrees.

This should solve problem with rectangles connected to borders.

share|improve this answer

You have three problems:

  1. The rectangles are not very strict rectangles (the edges are often somewhat curved)
  2. There are a lot of them.
  3. They are often connected.

It seems that all your rects are essentially the same size(?), and do not greatly overlap, but the pre-processing has connected them.

For this situation the approach I would try is:

  1. dilate your image a few times (as also suggested by @krzych) - this will remove the connections, but result in slightly smaller rects.
  2. Use scipy to label and find_objects - You now know the position and slice for every remaining blob in the image.
  3. Use minAreaRect to find the center, orientation, width and height of each rectangle.

You can use step 3. to test whether the blob is a valid rectangle or not, by its area, dimension ratio or proximity to the edge..

This is quite a nice approach, as we assume each blob is a rectangle, so minAreaRect will find the parameters for our minimum enclosing rectangle. Further we could test each blob using something like humoments if absolutely neccessary.

Here is what I was suggesting in action, boundary collision matches shown in red.

enter image description here


import numpy as np
import cv2
from cv2 import cv
import scipy
from scipy import ndimage

im_col = cv2.imread('jdjAf.jpg')
im = cv2.imread('jdjAf.jpg',cv2.CV_LOAD_IMAGE_GRAYSCALE)

im = np.where(im>100,0,255).astype(np.uint8)
im = cv2.erode(im, None,iterations=8)
im_label, num = ndimage.label(im)
for label in xrange(1, num+1):
    points = np.array(np.where(im_label==label)[::-1]).T.reshape(-1,1,2).copy()
    rect = cv2.minAreaRect(points)
    lines = np.array(
    if any([np.any(lines[:,0]<=0), np.any(lines[:,0]>=im.shape[1]-1), np.any(lines[:,1]<=0), np.any(lines[:,1]>=im.shape[0]-1)]):


I think the Watershed and distanceTransform approach demonstrated by @mmgp is clearly superior for segmenting the image, but this simple approach can be effective depending upon your needs.

share|improve this answer
Thank you very much, I think the method is faster then the watershed method, Can you give some comment on the code? like what does "ndimage.label" mean? also "np.array(np.where(im_label==label)[::-1]).T.reshape(-1,1,2).copy()" ? Thank you for aswer ~ –  Yang Feb 23 '13 at 8:00
Also "any([np.any(lines[:,0]<=0), np.any(lines[:,0]>=im.shape[1]-1), np.any(lines[:,1]<=0), np.any(lines[:,1]>=im.shape[0]-1)])" I can not understand easily.Thanks! –  Yang Feb 23 '13 at 8:02
@Yang - hey, sure heres a shot: ndimage.label(im) is used to segment the image: every unconnected blobs values are replaced sequentially by an integer, resulting in a new labelled image im_label. np.where(im_label==label) takes this new labelled image and returns the indices of every pixel in that image that equals label - ie. all of the index values for a single blob - note that we are iterating through the blobs, by only considering one label value at a time. The .T.reshape(-1,1,2).copy() is a fiddle to get the data into the correct format to be accepted by minAreaRect –  fraxel Feb 23 '13 at 10:11
@Yang - any is a logical operator, equivalent to chained or's. The conditions within it are checking to see if any of the rectangle points fall on or beyond the areas of the image, because if they do then we know its a bordering rectangle, so we colour it red, or can discard it, or whatever... hope that helps ;) –  fraxel Feb 23 '13 at 10:13
Thanks very much for your help !!! You method is the thing what I need~ –  Yang Feb 23 '13 at 11:00

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