Your task is simpler in several respects than the ones the general computer vision algorithms you'll find were designed for: you know exactly what to look for and you know exactly where to look for it. As such I think involving an external library is an unnecessary complication, *unless* you're already familiar with it and can use it effectively as a tool to solve your own problem. In this post I will only use PIL.

First, distinguish the task into two simpler tasks:

- Given a tile, determine whether there's a ball there.
- Given a tile where we're pretty sure that there's a ball, identify the colour of the ball.

The second task should be simple and I won't spend time on it here. Basically, sample some pixels where the ball's main colour will be visible and compare the colours you find to the known ball colours.

So let's look at the first task.

First off, note that the balls don't extend to the edge of the tiles. Thus you can find a fairly representative sample of the *background* of a tile, whether or not there's a ball there, by sampling the pixels along the edge of the tile.

A simple way to proceed is to compare every pixel in a tile with this sample of the tile background, and to obtain some sort of measure of whether it's generally similar (no ball) or dissimilar (ball).

The following is one way to do this. The basic approach used here is to calculate the mean and the standard deviation of the background pixels -- separately for the red, green, and blue channels. For every pixel, we then calculate the number of standard deviations we are from the mean in every channel. We take this value for the most dissimilar channel as our measure of dissimilarity.

```
import Image
import math
def fetch_pixels(col, row):
img = Image.open( "image.png" )
img = img.crop( (col*32,row*32,(col+1)*32,(row+1)*32) )
return img.load()
def border_pixels( a ):
rv = [ a[x,y] for x in range(32) for y in (0,31) ]
rv.extend( [ a[x,y] for x in (0,31) for y in range(1,31) ] )
return rv
def mean_and_stddev( xs ):
mean = float(sum( xs )) / len(xs)
dev = math.sqrt( float(sum( [ (x-mean)**2 for x in xs ] )) / len(xs) )
return mean, dev
def calculate_deviations(cols = 7, rows = 8):
outimg = Image.new( "L", (cols*32,rows*32) )
pixels = outimg.load()
for col in range(cols):
for row in range(rows):
rv = calculate_deviations_for( col, row, pixels )
print rv
outimg.save( "image_output.png" )
def calculate_deviations_for( col, row, opixels ):
a = fetch_pixels( col, row )
border = border_pixels( a )
bru, brd = mean_and_stddev( map( lambda x : x[0], border ) )
bgu, bgd = mean_and_stddev( map( lambda x : x[1], border ) )
bbu, bbd = mean_and_stddev( map( lambda x : x[2], border ) )
rv = []
for y in range(32):
for x in range(32):
r, g, b = a[x,y]
dr = (bru-r) / brd
dg = (bgu-g) / bgd
db = (bbu-b) / bbd
t = max(abs(dr), abs(dg), abs(db))
opixel = 0
limit, span = 2.5, 8.0
if t > limit:
v = min(1.0, (t - limit) / span)
print t,v
opixel = 127 + int( 128 * v )
opixels[col*32+x,row*32+y] = opixel
rv.append( t )
return (sum(rv) / float(len(rv)))
```

A visualization of the result is here:

Note that most of the non-ball pixels are pure black. It should now be possible to determine whether a ball is present or not by simply counting the black pixels. (Or more reliably: count the size of the largest single blob of non-black pixels.)

Now, this is a very ad-hoc method and I certainly don't make any claim that it's the best method. The "limit" value was determined by experimentation -- essentially, by trial and error. It's included here to illustrate the sort of method I think you should be exploring, and to give you a starting point to tweak from. (If you want a place to start experimenting, you could try to make it give a better result for the top purple ball. Can you think of weaknesses in the approach above that might make it give a result like that? Always keep in mind, however, that you don't need a perfect-looking result, just one that's good enough. The final answer you want is "ball" or "no ball", and you just want to be able to answer that reliably.)

Note that:

- You need to make sure you take the screengrab when the balls have finished rolling and are lying still in the center of their tiles. This simplifies the problem immensely.
- The game's background affects the problem -- if there are ocean-themed or desert-themed levels coming up, you will need to test and possibly tweak the recognizer to make sure it still reliably works.
- Special effects and/or GUI elements that cover the playing field will complicate the problem. (E.g. consider if the game has a 'cloud' or 'smoke' effect that sometimes floats over the playing field.) You may want to tweak the recognizer to be able to return "no result" if it's not sure -- then you can try another screengrab later. You may want to take several screengrabs and average the results.
- I have assumed that there are only balls and non-balls. If later levels have other kinds of objects, you will have to experiment more to find out how to best recognize those.
- I haven't used the 'reference picture' approach. However, if you have an image containing all the objects in the game and you can exactly align the pixels with your tiles, that's likely going to be the most reliable approach. Instead of comparing the foreground to the sampled background, compare the foreground to a set of known foreground images.