I'm trying to, given a random image and using NumPy, detect whether it's a photo vs a "rendered" image (like a map). The images can be colour or black & white, and gradients in rendered images might easily use 0-255, so counting colours won't help for greyscale. I can't use EXIF/etc metadata.
Approaches I've quickly tried so far, without anything jumping out:
- Converting to greyscale, then looking at a histogram
- 2D FFT then looking at histograms of the frequencies per band (as RGB and YUV)
- Looking at the means & standard deviation of the luminance
- Edge detection using Canny and Sobel filters
- Comparing GLCM properties for random 21x21 patches from each image
- Compress images as either JPEG (good for photos) or Deflate (aka. PNG) (good for maps) and compare bits-per-pixel
(feel free to suggest I go back and have another look)
I'm generally analysing random samples of larger areas rather than small crops like the examples shown below, so approaches that ignore occasional edge cases should work.
Current promising leads are described below, ideas I haven't looked at yet are:
- None left
Are there any algorithms/approaches that I should be looking at?
Still a Work in Progress for black and white images :) -- but the hue & saturation of all the rendered images is much spikier than the photographs, and generally has a 2-5x higher maxima as well.
image_hsv = skimage.color.rgb2hsv(image_rgb) hue_band, sat_band, val_band = np.squeeze(np.dsplit(image_hsv, 3)) band_hist, _ = np.histogram(hue_band.ravel(), bins=256) peak_idx = np.signal.argrelmax(band_hist, order=20) peaks = band_hist[peak_idx]
Examining the contrast seems to be slightly better, calculated via the code below. Photos generally seem to be <= 130, and maps generally are >= 150. Though black and white maps have a very low contrast (eg. 11 for the image below):
# image_rgb is a 3D numpy array: [ # [ [r,g,b], [r,g,b], ... ], # [ [r,g,b], [r,g,b], ... ], # ... # ] # these constants from http://en.wikipedia.org/wiki/Relative_luminance rgb2lum = numpy.array([0.2126, 0.7152, 0.0722]) luminance = numpy.dot(image_rgb, rgb2lum) # for B&W images, luminance == image_bw already rms_contrast = numpy.sqrt(numpy.mean(numpy.square(luminance)))
What I've currently gone with is:
- Analysing up to 8x 512x512px random patches from images, which all vote for a result:
- For RGB images, convert the patch to HSV colour
- Creating a histogram (256 bins) of either the B&W data or the Hue band (
- Count the non-empty bins in the histogram, if less than 100 the vote is 'map'.
- Get the peaks of the histogram (
- If the maximum peak is >9% of the total pixels in the band and the maximum peak is >=2x as large as the mean of the peaks, then the vote is 'map'.
- Otherwise, the vote is 'photo'
- If 50% of the votes from patches are 'map', the result is 'map'
Is pretty good when run across colour images, and the results get better again if you have multiple images in a dataset and can re-vote again on a per-image level.
B&W images are still a bit hit or miss.
High-contrast colour photo. Some can be quite over-exposed:
Low-contrast colour photo:
High-contrast B&W photo. Again, some can be quite over-exposed:
Low-contrast B&W photo:
Low-contrast colour map: