How to remove convexity defects in a Sudoku square?

I was doing a fun project: Solving a Sudoku from an input image using OpenCV (as in Google goggles etc). And I have completed the task, but at the end I found a little problem for which I came here.

I did the programming using Python API of OpenCV 2.3.1.

Below is what I did :

2. Find the contours
3. Select the one with maximum area, ( and also somewhat equivalent to square).
4. Find the corner points.

e.g. given below:

(Notice here that the green line correctly coincides with the true boundary of the Sudoku, so the Sudoku can be correctly warped. Check next image)

5. warp the image to a perfect square

eg image:

6. Perform OCR ( for which I used the method I have given in Simple Digit Recognition OCR in OpenCV-Python )

And the method worked well.

Problem:

Check out this image.

Performing the step 4 on this image gives the result below:

The red line drawn is the original contour which is the true outline of sudoku boundary.

The green line drawn is approximated contour which will be the outline of warped image.

Which of course, there is difference between green line and red line at the top edge of sudoku. So while warping, I am not getting the original boundary of the Sudoku.

My Question :

How can I warp the image on the correct boundary of the Sudoku, i.e. the red line OR how can I remove the difference between red line and green line? Is there any method for this in OpenCV?

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You're doing your detection based on corner points, which the red and green lines agree on. I don't know OpenCV, but presumably you'll want to detect the lines between those corner points and warp based on that. – Dougal Apr 17 '12 at 17:43
Perhaps force the lines that connect the corner points to coincide with heavy black pixels in the image. That is, instead of letting the green lines just find a straight line between corner points, force them to traverse heavy black pixels. This will make your problem substantially more difficult, I think, and I don't know of any OpenCV built-ins that will be immediately useful for you. – Mr. F Apr 17 '12 at 17:45
@ Dougal : I think the green line drawn is the approximated straight line of red line. so it is the line between those corner points. When i warp according to green line, i get curved red line at the top of warped image. ( i hope you understand, my explanation seems a little bad) – Abid Rahman K Apr 17 '12 at 17:46
@ EMS : i think red line drawn is exactly on the border of sudoku. But problem is, how to warp the image exactly on the border of sudoku. ( i mean, problem is with warping, ie converting those curved border to an exact square, as i have shown in second image) – Abid Rahman K Apr 17 '12 at 17:52

I have a solution that works, but you'll have to translate it to OpenCV yourself. It's written in Mathematica.

The first step is to adjust the brightness in the image, by dividing each pixel with the result of a closing operation:

``````src = ColorConvert[Import["http://davemark.com/images/sudoku.jpg"], "Grayscale"];
white = Closing[src, DiskMatrix[5]];
``````

The next step is to find the sudoku area, so I can ignore (mask out) the background. For that, I use connected component analysis, and select the component that's got the largest convex area:

``````components =
ComponentMeasurements[
2]];
largestComponent = Image[SortBy[components, First][[-1, 2]]]
``````

By filling this image, I get a mask for the sudoku grid:

``````mask = FillingTransform[largestComponent]
``````

Now, I can use a 2nd order derivative filter to find the vertical and horizontal lines in two separate images:

``````lY = ImageMultiply[MorphologicalBinarize[GaussianFilter[srcAdjusted, 3, {2, 0}], {0.02, 0.05}], mask];
``````

I use connected component analysis again to extract the grid lines from these images. The grid lines are much longer than the digits, so I can use caliper length to select only the grid lines-connected components. Sorting them by position, I get 2x10 mask images for each of the vertical/horizontal grid lines in the image:

``````verticalGridLineMasks =
SortBy[ComponentMeasurements[
lX, {"CaliperLength", "Centroid", "Mask"}, # > 100 &][[All,
2]], #[[2, 1]] &][[All, 3]];
SortBy[ComponentMeasurements[
lY, {"CaliperLength", "Centroid", "Mask"}, # > 100 &][[All,
2]], #[[2, 2]] &][[All, 3]];
``````

Next I take each pair of vertical/horizontal grid lines, dilate them, calculate the pixel-by-pixel intersection, and calculate the center of the result. These points are the grid line intersections:

``````centerOfGravity[l_] :=
ComponentMeasurements[Image[l], "Centroid"][[1, 2]]
gridCenters =
Table[centerOfGravity[
ImageData[Dilation[Image[h], DiskMatrix[2]]]*
ImageData[Dilation[Image[v], DiskMatrix[2]]]], {h,
``````

The last step is to define two interpolation functions for X/Y mapping through these points, and transform the image using these functions:

``````fnX = ListInterpolation[gridCenters[[All, All, 1]]];
fnY = ListInterpolation[gridCenters[[All, All, 2]]];
transformed =
ImageTransformation[
srcAdjusted, {fnX @@ Reverse[#], fnY @@ Reverse[#]} &, {9*50, 9*50},
PlotRange -> {{1, 10}, {1, 10}}, DataRange -> Full]
``````

All of the operations are basic image processing function, so this should be possible in OpenCV, too. The spline-based image transformation might be harder, but I don't think you really need it. Probably using the perspective transformation you use now on each individual cell will give good enough results.

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Quite nice pipeline +1 – Matthias Odisio Apr 19 '12 at 13:19
Wow. Can I give this a +10?? :) Nice job. – Jonathan M Apr 19 '12 at 14:18
Wow, what a fantastic piece of Mathematica code. – Eli Lansey Apr 19 '12 at 14:36
Oh my god !!!!!!!!! That was marvelous. This is really really great. I will try to make it in OpenCV. Hope you would help me with details on certain functions and terminology... Thank you. – Abid Rahman K Apr 19 '12 at 16:13
Amazing answer! Where did you get the idea of dividing by the closing to normalize the image brightness? I'm trying to improve the speed of this method, since floating-point division is painfully slow on mobile phones. Do you have any suggestions? @AbidRahmanK – 1'' Mar 22 '13 at 23:19

Nikie's answer solved my problem, but his answer was in Mathematica. So I thought I should give its OpenCV adaptation here. But after implementing I could see that OpenCV code is much bigger than nikie's mathematica code. And also, I couldn't find interpolation method done by nikie in OpenCV ( although it can be done using scipy, i will tell it when time comes.)

1. Image PreProcessing ( closing operation )

``````import cv2
import numpy as np

img = cv2.GaussianBlur(img,(5,5),0)
gray = cv2.cvtColor(img,cv2.COLOR_BGR2GRAY)
kernel1 = cv2.getStructuringElement(cv2.MORPH_ELLIPSE,(11,11))

close = cv2.morphologyEx(gray,cv2.MORPH_CLOSE,kernel1)
div = np.float32(gray)/(close)
res = np.uint8(cv2.normalize(div,div,0,255,cv2.NORM_MINMAX))
res2 = cv2.cvtColor(res,cv2.COLOR_GRAY2BGR)
``````

Result :

2. Finding Sudoku Square and Creating Mask Image

``````thresh = cv2.adaptiveThreshold(res,255,0,1,19,2)
contour,hier = cv2.findContours(thresh,cv2.RETR_TREE,cv2.CHAIN_APPROX_SIMPLE)

max_area = 0
best_cnt = None
for cnt in contour:
area = cv2.contourArea(cnt)
if area > 1000:
if area > max_area:
max_area = area
best_cnt = cnt

``````

Result :

3. Finding Vertical lines

``````kernelx = cv2.getStructuringElement(cv2.MORPH_RECT,(2,10))

dx = cv2.Sobel(res,cv2.CV_16S,1,0)
dx = cv2.convertScaleAbs(dx)
cv2.normalize(dx,dx,0,255,cv2.NORM_MINMAX)
ret,close = cv2.threshold(dx,0,255,cv2.THRESH_BINARY+cv2.THRESH_OTSU)
close = cv2.morphologyEx(close,cv2.MORPH_DILATE,kernelx,iterations = 1)

contour, hier = cv2.findContours(close,cv2.RETR_EXTERNAL,cv2.CHAIN_APPROX_SIMPLE)
for cnt in contour:
x,y,w,h = cv2.boundingRect(cnt)
if h/w > 5:
cv2.drawContours(close,[cnt],0,255,-1)
else:
cv2.drawContours(close,[cnt],0,0,-1)
close = cv2.morphologyEx(close,cv2.MORPH_CLOSE,None,iterations = 2)
closex = close.copy()
``````

Result :

4. Finding Horizontal Lines

``````kernely = cv2.getStructuringElement(cv2.MORPH_RECT,(10,2))
dy = cv2.Sobel(res,cv2.CV_16S,0,2)
dy = cv2.convertScaleAbs(dy)
cv2.normalize(dy,dy,0,255,cv2.NORM_MINMAX)
ret,close = cv2.threshold(dy,0,255,cv2.THRESH_BINARY+cv2.THRESH_OTSU)
close = cv2.morphologyEx(close,cv2.MORPH_DILATE,kernely)

contour, hier = cv2.findContours(close,cv2.RETR_EXTERNAL,cv2.CHAIN_APPROX_SIMPLE)
for cnt in contour:
x,y,w,h = cv2.boundingRect(cnt)
if w/h > 5:
cv2.drawContours(close,[cnt],0,255,-1)
else:
cv2.drawContours(close,[cnt],0,0,-1)

close = cv2.morphologyEx(close,cv2.MORPH_DILATE,None,iterations = 2)
closey = close.copy()
``````

Result :

Of course, this one is not so good.

5. Finding Grid Points

``````res = cv2.bitwise_and(closex,closey)
``````

Result :

6. Correcting the defects

Here, nikie does some kind of interpolation, about which I don't have much knowledge. And i couldn't find any corresponding function for this OpenCV. (may be it is there, i don't know).

Check out this SOF which explains how to do this using SciPy, which I don't want to use : Image transformation in OpenCV

So, here I took 4 corners of each sub-square and applied warp Perspective to each.

For that, first we find the centroids.

``````contour, hier = cv2.findContours(res,cv2.RETR_LIST,cv2.CHAIN_APPROX_SIMPLE)
centroids = []
for cnt in contour:
mom = cv2.moments(cnt)
(x,y) = int(mom['m10']/mom['m00']), int(mom['m01']/mom['m00'])
cv2.circle(img,(x,y),4,(0,255,0),-1)
centroids.append((x,y))
``````

But resulting centroids won't be sorted. Check out below image to see their order:

So we sort them from left to right, top to bottom.

``````centroids = np.array(centroids,dtype = np.float32)
c = centroids.reshape((100,2))
c2 = c[np.argsort(c[:,1])]

b = np.vstack([c2[i*10:(i+1)*10][np.argsort(c2[i*10:(i+1)*10,0])] for i in xrange(10)])
bm = b.reshape((10,10,2))
``````

Now see below their order :

Finally we apply the transformation and create a new image of size 450x450.

``````output = np.zeros((450,450,3),np.uint8)
for i,j in enumerate(b):
ri = i/10
ci = i%10
if ci != 9 and ri!=9:
src = bm[ri:ri+2, ci:ci+2 , :].reshape((4,2))
dst = np.array( [ [ci*50,ri*50],[(ci+1)*50-1,ri*50],[ci*50,(ri+1)*50-1],[(ci+1)*50-1,(ri+1)*50-1] ], np.float32)
retval = cv2.getPerspectiveTransform(src,dst)
warp = cv2.warpPerspective(res2,retval,(450,450))
output[ri*50:(ri+1)*50-1 , ci*50:(ci+1)*50-1] = warp[ri*50:(ri+1)*50-1 , ci*50:(ci+1)*50-1].copy()
``````

Result :

The result is almost same as nikie's, but code length is large. May be, better methods are available out there, but until then, this works OK.

Regards ARK.

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+1 Great answer! Deserves more upvotes – Viktor Sehr Jul 10 '12 at 14:57
"I prefer my application crashing than getting wrong answers." <- I also agree to this 100% – Viktor Sehr Jul 10 '12 at 14:58
Thanks, Its real answer is given by Nikie. But that was in mathematica, so i just converted it to OpenCV. So the real answer has got enough upvotes, I think – Abid Rahman K Jul 10 '12 at 14:58
Yes I know, still the effort was worth more than one upvote – Viktor Sehr Jul 10 '12 at 16:27
Ah didnt see you also posted the question :) – Viktor Sehr Jul 10 '12 at 16:28

You could try to use some kind of grid based modeling of you arbitrary warping. And since the sudoku already is a grid, that shouldn't be too hard.

So you could try to detect the boundaries of each 3x3 subregion and then warp each region individually. If the detection succeeds it would give you a better approximation.

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