9

I have images that are noised with some random lines like the following one:
enter image description here
I want to apply on them some preprocessing in order to remove the unwanted noise ( the lines that distort the writing) so that I can use them with OCR (Tesseract).
The idea that came to my mind is to use dilation to remove the noise then use erosion to fix the missing parts of the writing in a second step.
For that, I used this code:

import cv2
import numpy as np

img = cv2.imread('linee.png', cv2.IMREAD_GRAYSCALE)
kernel = np.ones((5, 5), np.uint8)
img = cv2.dilate(img, kernel, iterations=1)
img = cv2.erode(img, kernel, iterations=1)
cv2.imwrite('delatedtest.png', img)

Unfortunately, the dilation didn't work well, The noise lines are still existing.

enter image description here
I tried changing the kernel shape, but it got worse: the writing were partially or completely deleted.
I also found an answer saying that it is possible to remove the lines by

turning all black pixels with two or less adjacent black pixels to white.

That seems a bit complicated for me since I am beginner to computer vision and opencv.
Any help would be appreciated, thank you.

  • 2
    erode removes the thinnest parts first ... you can see that if you look carefully. The lines are about as thick as your text - if you erode/dilatate them away, your text will be gone. generally you erode first to get rid of tiny things, then dilatate again to make survivers thicker again ... you use them the other way round. why? – Patrick Artner Jan 3 '19 at 19:32
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    Despite the image being defaced, have you tried running it through the OCR to check the results? – Wayne Phipps Jan 3 '19 at 19:39
  • @PatrickArtner I tried using dilation first then erosion and I also tried using erosion first then dilation, but didn't work too. – test Jan 3 '19 at 19:54
  • @WaynePhipps yeah I tried, but it gave nothing, the output was empty – test Jan 3 '19 at 19:56
8

Detecting lines like these is what the path opening was invented for. PyDIP has an implementation (disclosure: I implemented it there; also note that you'll have to install PyDIP from sources as we haven't yet created a binary distribution). As an alternative, you can try using the implementation by the authors of the paper that I linked above. That implementation does not have the "constrained" mode that I use below.

Here is a quick demo for how you can use it:

import PyDIP as dip
import matplotlib.pyplot as pp

img = 1 - pp.imread('/home/cris/tmp/DWRTF.png')
lines = dip.PathOpening(img, length=300, mode={'constrained'})

Here we first inverted the image because that makes other things later easier. If not inverting, use a path closing instead. The lines image:

lines

Next we subtract the lines. A small area opening removes the few isolated pixels of the line that were filtered out by the path opening:

text = img - lines
text = dip.AreaOpening(text, filterSize=5)

text

However, we've now made gaps in the text. Filling these up is not trivial. Here is a quick-and-dirty attempt, which you can use as a starting point:

lines = lines > 0.5
text = text > 0.5
lines -= dip.BinaryPropagation(text, lines, connectivity=-1, iterations=3)
img[lines] = 0

final result

  • This is really perfect, thank you! – test Jan 3 '19 at 23:54
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    @test: “Image is not scalar” means that the image has more than one channel, but only scalar (single-channel) images are allowed in morphological functions at the moment. I presume you have an RGB image. You should convert it to gray-scale, for example by dip.ColorSpaceManager.Convert(img, 'gray'). – Cris Luengo Jan 4 '19 at 1:16
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    @test: Do img = dip.Image(img). Now what does img.TensorElements() return? And what does img.ColorSpace() return? Maybe you have 3 tensor elements (==channels) but the color space is an empty string? If so, do img.SetColorSpace('RGB'), then you'll be able to convert to gray. The other option is to do img=img.TensorElement(0) to just extract the first channel. -- Obviously this area hadn't been user-tested very extensively yet. :) I'll look into improving the usability. Thanks for pointing this out! – Cris Luengo Jan 4 '19 at 8:14
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    @test: Awesome! You should be able to directly use the image as read by OpenCV in PyDIP too, no need to first save it. Just use OpenCV imread instead of pyplot imread. – Cris Luengo Jan 4 '19 at 13:44
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    @singrium: I haven't seen that before. Please open an issue in the issue tracker, were there's space for more details. Include the output of CMake and also of ldd /usr/local/lib/libDIPviewer.so. Thanks! – Cris Luengo Oct 24 '19 at 16:21
4

You can do that using createLineSegmentDetector(), a function from opencv

import cv2

#Read gray image
img = cv2.imread("lines.png",0)

#Create default parametrization LSD
lsd = cv2.createLineSegmentDetector(0)

#Detect lines in the image
lines = lsd.detect(img)[0] #Position 0 of the returned tuple are the detected lines

#Draw the detected lines
drawn_img = lsd.drawSegments(img,lines)

#Save the image with the detected lines
cv2.imwrite('lsdsaved.png', drawn_img)

enter image description here
The next part of the code will delete only the lines which their length is more than 50 pixels:

for element in lines:

#If the length of the line is more than 50, then draw a white line on it
if (abs(int(element[0][0]) - int(element[0][2])) > 50 or abs(int(element[0][1]) - int(element[0][3])) > 50): 

#Draw the white line
cv2.line(img, (int(element[0][0]), int(element[0][1])), (int(element[0][2]), int(element[0][3])), (255, 255, 255), 12)

#Save the final image
cv2.imwrite('removedzz.png', img)

enter image description here

Well, it didn't work perfectly with the current image, but it may give better results with different images. You can adjust the length of the lines to remove and the thickness of the white lines to draw insteaad of the removed lines.
I hope it helps.

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