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I'm trying to extract letters from a game board for a project. Currently, I can detect the game board, segment it into the individual squares and extract images of every square.

The input I'm getting is like this (these are individual letters):

enter image description hereenter image description hereenter image description hereenter image description hereenter image description hereenter image description here

At first, I was counting the number of black pixels per image and using that as a way of identifying the different letters, which worked somewhat well for controlled input images. The problem I have, though, is that I can't make this work for images that differ slightly from these.

I have around 5 samples of each letter to work with for training, which should be good enough.

Does anybody know what would be a good algorithm to use for this?

My ideas were (after normalizing the image):

  • Counting the difference between an image and every letter image to see which one produces the least amount of error. This won't work for large datasets, though.
  • Detecting corners and comparing relative locations.
  • ???

Any help would be appreciated!

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Welcome to OCR. – delnan Apr 4 '12 at 20:14
Heh, I tried Tessearact on the test images after dilating them a little bit, but it failed miserably (even after setting the segmentation mode to "one word"). OCR seems like an overkill for this specific case, IMO, as the images are really similar in every case. – Blender Apr 4 '12 at 20:17
what about scale and rotation invariance? – moooeeeep Apr 4 '12 at 20:36
The rotation is negligible and doesn't distort the letters any more than a horizontal compression does. As for scale, I normalize every image to a fixed size. – Blender Apr 4 '12 at 20:40

5 Answers 5

up vote 11 down vote accepted

I think this is necessarily some sort of Supervised Learning. You need to do some feature extraction on the images and then do your classification on the basis of the feature vector you've computed for each image.

Feature Extraction

On the first sight, that Feature Extraction part looks like a good scenario for Hu-Moments. Just calculate the image moments, then compute cv::HuMoments from these. Then you have a 7 dimensional real valued feature space (one feature vector per image). Alternatively, you could omit this step and use each pixel value as seperate feature. I think the suggestion in this answer goes in this direction, but adds a PCA compression to reduce the dimensionality of the feature space.


As for the classification part, you can use almost any classification algorithm you like. You could use an SVM for each letter (binary yes-no classification), you could use a NaiveBayes (what is the maximal likely letter), or you could use a k-NearestNeighbor (kNN, minimum spatial distance in feature space) approach, e.g. flann.

Especially for distance-based classifiers (e.g. kNN) you should consider a normalization of your feature space (e.g. scale all dimension values to a certain range for euclidean distance, or use things like mahalanobis distance). This is to avoid overrepresenting features with large value differences in the classification process.


Of course you need training data, that is images' feature vectors given the correct letter. And a process, to evaluate your process, e.g. cross validation.

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Thank you very much for your help! I got as far as computing the Hu moments for the individual images, but after that the classification has stumped me with loads of errors. Hopefully I can get it to work within the next day or so and see how well it works! – Blender Apr 5 '12 at 7:56
Just got the classifier to work! It's 100% accurate for my training data (duh) but has some trouble with new input. I'm going to train it some more with more accurate samples. – Blender Apr 5 '12 at 8:26
@Blender - glad this helped! – moooeeeep Apr 5 '12 at 8:49
Just as a status update, I found out that having high-quality training data and images isn't a good idea. My accuracy increased to 100% when I resized my images to (oddly enough) 5px by 5px. – Blender Apr 6 '12 at 4:22
@Blender that is a rather odd result. How do you compute your accuracy? Anyway, if it is a study project and you are not able to explain why is it working, it might be a problem for you. – Simon Apr 6 '12 at 7:58

This is a recognition problem. I'd personally use a combination of PCA and a machine learning technique (likely SVM). These are fairly large topics so I'm afraid I can't really elaborate too much, but here's the very basic process:

  1. Gather your training images (more than one per letter, but don't go crazy)
  2. Label them (could mean a lot of things, in this case it means group the letters into logical groups -- All A images -> 1, All B images -> 2, etc.)
  3. Train your classifier
    • Run everything through PCA decomposition
    • Project all of your training images into PCA space
    • Run the projected images through an SVM (if it's a one-class classifier, do them one at a time, otherwise do them all at once.)
    • Save off your PCA eigenvector and SVM training data
  4. Run recognition
    • Load in your PCA space
    • Load in your SVM training data
    • For each new image, project it into PCA space and ask your SVM to classify it.
    • If you get an answer (a number) map it back to a letter (1 -> A, 2 -> B, etc).
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Thank you! I'm reading up on PCA right now. Finally a use for Linear Algebra... – Blender Apr 4 '12 at 20:40
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I read through the second one and I seem to be doing this already (comparing differing pixels and finding the image which minimizes that error). The first one is a bit covert and doesn't explain what happens very well, but thank you for the links! I'll do some research into how the first one works. – Blender Apr 4 '12 at 21:09

I had a similar problem few days back. But it was digit recognition. Not for alphabets.

And i implemented a simple OCR for this using kNearestNeighbour in OpenCV.

Below is the link and code :

Simple Digit Recognition OCR in OpenCV-Python

Implement it for alphabets. Hopes it works.

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This answer was really helpful when I was actually coding the algorithms. Thank you! – Blender Apr 5 '12 at 9:01

Please look at these two answers related to OCR

Scoreboard digit recognition using OpenCV

and here

OCR of low-resolution text from screenshots

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