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I am working on a project that requires me to separate out each color in a CYMK image and generate a halftone image that will be printed on a special halftone printer. The method used is analogues to silk screening in that the process is almost identical. Take a photo and break out each color channel. Then produce a screen for the half tone. Each color screen must have it's screen skewed by 15-45 (adjustable) degrees. Dot size and LPI must be calculated from user configurable values to achieve different effects. This process I am told is used in silk screening but I have been unable to locate any information that explains CYMK halftoning. I find plenty for reducing to a single color and generating new print style b/w halftone image.

I would guess that I need to: 1. split the file into it's color channels. 2. generate a monochrome halftone image for that channel. 3. Skew the resultant halftone image by the number of degrees * channel number. Does anyone know if this is the correct approach?

Does anyone know of any existing python code for this? Or of any good explanations for this process or algorithms?

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updated my code, hope its helpful ;) –  fraxel May 14 '12 at 17:20

2 Answers 2

up vote 12 down vote accepted

I used to run a screen printing studio (it was a fairly small one), and although I have never actually done colour separation printing, I am reasonably familiar with the principles. This is how I would approach it:

  1. Split the image into C, M, Y, K.
  2. Rotate each separated image by 0, 15, 30, and 45 degrees respectively.
  3. Take the half-tone of each image (dot size will be proportional to the intensity).
  4. Rotate back each half-toned image.

Now you have your colour separated images. As you mention, the rotation step reduces dot alignment issues (which would mess everything up), and things like Moiré pattern effects will be reasonably minimized.

This should be pretty easy to code using PIL.

Update 2:

I wrote some quick code that will do this for you, it also includes a GCA function (described below):

import Image, ImageDraw, ImageStat

def gcr(im, percentage):
    '''basic "Gray Component Replacement" function. Returns a CMYK image with 
       percentage gray component removed from the CMY channels and put in the
       K channel, ie. for percentage=100, (41, 100, 255, 0) >> (0, 59, 214, 41)'''
    cmyk_im = im.convert('CMYK')
    if not percentage:
        return cmyk_im
    cmyk_im = cmyk_im.split()
    cmyk = []
    for i in xrange(4):
    for x in xrange(im.size[0]):
        for y in xrange(im.size[1]):
            gray = min(cmyk[0][x,y], cmyk[1][x,y], cmyk[2][x,y]) * percentage / 100
            for i in xrange(3):
                cmyk[i][x,y] = cmyk[i][x,y] - gray
            cmyk[3][x,y] = gray
    return Image.merge('CMYK', cmyk_im)

def halftone(im, cmyk, sample, scale):
    '''Returns list of half-tone images for cmyk image. sample (pixels), 
       determines the sample box size from the original image. The maximum 
       output dot diameter is given by sample * scale (which is also the number 
       of possible dot sizes). So sample=1 will presevere the original image 
       resolution, but scale must be >1 to allow variation in dot size.'''
    cmyk = cmyk.split()
    dots = []
    angle = 0
    for channel in cmyk:
        channel = channel.rotate(angle, expand=1)
        size = channel.size[0]*scale, channel.size[1]*scale
        half_tone = Image.new('L', size)
        draw = ImageDraw.Draw(half_tone)
        for x in xrange(0, channel.size[0], sample):
            for y in xrange(0, channel.size[1], sample):
                box = channel.crop((x, y, x + sample, y + sample))
                stat = ImageStat.Stat(box)
                diameter = (stat.mean[0] / 255)**0.5
                edge = 0.5*(1-diameter)
                x_pos, y_pos = (x+edge)*scale, (y+edge)*scale
                box_edge = sample*diameter*scale
                draw.ellipse((x_pos, y_pos, x_pos + box_edge, y_pos + box_edge), fill=255)
        half_tone = half_tone.rotate(-angle, expand=1)
        width_half, height_half = half_tone.size
        xx=(width_half-im.size[0]*scale) / 2
        yy=(height_half-im.size[1]*scale) / 2
        half_tone = half_tone.crop((xx, yy, xx + im.size[0]*scale, yy + im.size[1]*scale))
        angle += 15
    return dots

im = Image.open("1_tree.jpg")

cmyk = gcr(im, 0)
dots = halftone(im, cmyk, 10, 1)
new = Image.merge('CMYK', dots)

This will turn this:

enter image description here

into this (blur your eyes and move away from the monitor):

enter image description here

Note that the image sampling can be pixel by pixel (thus preserving the resolution of the original image, in the final image). Do this by setting sample=1, in which case you need to set scale to a larger number so that there are a number of possible dot sizes. This will also result in a larger output image size (original image size * scale ** 2, so watch out!).

By default when you convert from RGB to CMYK the K channel (the black channel) is empty. Whether you need the K channel or not depends upon your printing process. There are various possible reasons you might want it: getting a better black than the overlap of CMY, saving ink, improving drying time, reducing ink bleed, etc. Anyhow I've also written a little Grey component replacement function GCA, so you can set the percentage of K channel you want to replace CMY overlap with (I explain this a little further in the code comments).

Here is a couple of examples to illustrate. Processing the letter F from the image, with sample=1 and scale=8, so fairly high resolution.

The 4 CMYK channels, with percentage=0, so empty K channel:

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

combines to produce:

enter image description here

CMYK channels, with percentage=100, so K channel is used. You can see the cyan channel is fully supressed, and the magenta and yellow channels use a lot less ink, in the black band at the bottom of the image:

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

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neat solution ! –  andrew cooke May 13 '12 at 23:37
+1 Outstanding. –  Li-aung Yip May 14 '12 at 2:33
@user69333 - Cool, good luck with that! By the way I'm fraxel (different from Andrew, who also answered..). I would appreciate it if you could 'accept my answer', by clicking the tick, its the way that stackoverflow works (we both get points... whoop), cheers. –  fraxel May 14 '12 at 17:37
Thanks again Andrew. Your grey scale component may come in handy. Most of what I've learned here has come from T-Shirt sites. Now it's got me thinking about doing some OSS for t-shirt printing. However, I noticed that the commercial software seems to use the RGB as well as the CMYK channels and other screens as well. I read a tut on using Photoshop for screen printing t-shirts and it seems their is a lot to it. As for my printer project you got me off to a very good start. I'm going to add your grey scale code and make a few more mods. –  user693336 May 14 '12 at 17:42
I played around with some angles I found on the net ranging from 10 degrees to 60 degrees per channel and found that some combinations result in really bad moire pattern effects while others reduce these effects. My code allows me to set specific angles for each channel so I can use angles that are not incremental. This seems to help reduce the effects but can also change the the perceived color. It's kind of cool to mess around with ;-) –  user693336 May 14 '12 at 17:42

My solution also uses PIL, but relies on the internal dithering method (Floyd-Steinberg) supported internally. Creates artifacts, though, so I am considering rewriting its C code.

    from PIL import Image

    im  = Image.open('tree.jpg')             # open RGB image
    cmyk= im.convert('CMYK').split()         # RGB contone RGB to CMYK contone
    c = cmyk[0].convert('1').convert('L')    # and then halftone ('1') each plane
    m = cmyk[1].convert('1').convert('L')    # ...and back to ('L') mode
    y = cmyk[2].convert('1').convert('L')
    k = cmyk[3].convert('1').convert('L')

    new_cmyk = Image.merge('CMYK',[c,m,y,k]) # put together all 4 planes
    new_cmyk.save('tree-cmyk.jpg')           # and save to file

The implicit GCR PIL applies can also be expanded with a more generic one, but I have tried to describe a simple solution, where also resolution and sampling are ignored.

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