# Which SSIM is correct : skimage.metrics.structural_similarity()?

Stackoverflow comunity,

I'm trying to compute SSIM (Structural SIMilarity) between two `bmp` images on Python. I've found structural_similarity() function implemented in the `skimage` python library and the equivalent code from the original `MatLab` implementation which is hosted here. The implimentation is right bellow:

``````def structuralSimilarityIndex(ref_image, impaired_image, cs_map=False):

window = Metric.fSpecialGauss(constant.SSIM_FILTER_SIZE,
constant.SSIM_FILTER_SIGMA)
C1 = (constant.SSIM_Constant_1 * constant.PIXEL_MAX) ** 2
C2 = (constant.SSIM_Constant_2 * constant.PIXEL_MAX) ** 2

mu1 = signal.fftconvolve(window, ref_image, mode='valid')
mu2 = signal.fftconvolve(window, impaired_image, mode='valid')

mu1_sq = mu1 * mu1
mu2_sq = mu2 * mu2
mu1_mu2 = mu1 * mu2

sigma1_sq = signal.fftconvolve(
window, ref_image*ref_image, mode='valid') - mu1_sq
sigma2_sq = signal.fftconvolve(
window, impaired_image*impaired_image, mode='valid') - mu2_sq
sigma12 = signal.fftconvolve(
window, ref_image*impaired_image, mode='valid') - mu1_mu2

if cs_map:
return (((2 * mu1_mu2 + C1) * (2 * sigma12 + C2)) / ((mu1_sq + mu2_sq + C1) * (sigma1_sq + sigma2_sq + C2)), (2.0 * sigma12 + C2) / (sigma1_sq + sigma2_sq + C2))
else:
return np.mean(((2 * mu1_mu2 + C1) * (2 * sigma12 + C2)) / ((mu1_sq + mu2_sq + C1) * (sigma1_sq + sigma2_sq + C2)))
``````

I'm reading the images using this piece of code :

``````ref_image = np.asfarray(Image.open('ref_image.bmp').convert('L'))
impaired_image = np.asfarray(Image.open('impaired_image.bmp').covert('L)
``````

The input images shape and `dtype` of both `ref_image` and `impaired_image` are respectively:

(512, 512) float64

(512, 512) float64

I've tested both using the same condition and same input images as follow:

``````# Using the above code
structuralSimilarityIndex(ref_image, impaired_image, cs_map=False)

# Using the function imported from skimage.metrics
structural_similarity(ref_image, impaired_image, gaussian_weights=False, use_sample_covariance=False)
``````

the result was so much different, here the results:

The SSIM from the `Skimage` python library:

SSIM : 0.38135154028457885

The SSIM from the code above:

SSIM : 0.8208087737160036

EDIT:

The above Python code was from the signal processing library, which is according to the author, the function attempts to mimic precisely the functionality of ssim.m a MATLAB provided by the author's of SSIM

Update :

I've tested the original code which is writing in MatLab on the same images and the result is as follow :

SSIM : 0.8424

Which is not far from the result of the Python implementation given above.

• You’ve found the implementation by the authors of the paper presenting SSIM, and you are wondering if it is correct? Surely that must be the reference. Why not directly post a bug report to the skimage project? – Cris Luengo Oct 29 at 13:10
• Did you check to see that the constants used are the same? – Cris Luengo Oct 29 at 13:15
• The Python implementation is provided by the author himself. – SenDjasni Oct 29 at 13:16
• I did check the constants, they used the same. – SenDjasni Oct 29 at 13:18
• @CrisLuengo there is a lot of things I couldn't understand ins the skimage implementation since the variables and the commands were really confusing. – SenDjasni Oct 29 at 13:26

I've opened an issue on the scikit-image Github repository and I got an answer. Here the answer, I've change nothing to the answer and you can find it here:

I think the primary issue here is that the way you computed images from PIL results in floating point images, but ones where the values are in the range [0, 255.0]. skimage will assume a range [-1.0, 1.0] for data_range when the input is floating-point, so you will need to manually specify data_range=255.

Also, see the Notes section of the docstring for recommendations to set gaussian_weights=True, sigma=1.5 to more closely match the Matlab script by Wang et. al. (I think recent Matlab also has its own built-in SSIM implementation, but I haven't tried comparing to that case and don't know if it is exactly the same).

``````ref_image = np.asfarray(Image.open('avion.bmp').convert('L'))
impaired_image = np.asfarray(Image.open('avion_jpeg_r5.bmp').convert('L'))
structural_similarity(ref_image, impaired_image, multichannel=True, gaussian_weights=True, sigma=1.5, use_sample_covariance=False, data_range=255)
``````

gives `0.8292` when I tried it.

Alternatively you can use skimage.io.imread and rgb2gray to read in the data and convert it to grayscale. In that case, values will have been scaled within [0, 1.0] for you and data_range should be set to 1.0.

``````from skimage.io import imread
from skimage.color import rgb2gray
gives `0.8265`
I think the small difference between the two cases above is probably due to `rgb2gray` using a different luminance conversion than PIL's `convert` method.