The question's title suggests you have two exact images to compare, and that is trivially done. Now, if you have similar images to compare then that explains why you didn't find a fully satisfactory answer: there is no metric applicable to every problem that gives the expected results (note that expected results varies between applications). One of the problems is that it is hard -- in the sense that there is no common agreement -- to compare images with multiple bands, like color images. To handle that, I will consider the application of a given metric in each band, and the result of that metric will be the lowest resulting value. This assumes the metric has a well established range, like [0, 1], and the maximum value in this range means the images are identical (by the given metric). Conversely, the minimum value means the images are totally different.

So, all I will do here is give you two metrics. One of them is SSIM and the other one I will call as NRMSE (a normalization of the root of the mean squared error). I choose to present the second one because it is a very simple method, and it may be enough for your problem.

Let us get started with examples. The images are in this order: f = original image in PNG, g1 = JPEG at 50% quality of `f`

(made with `convert f -quality 50 g`

), g2 = JPEG 1% quality of `f`

, h = "lightened" g2.

Results (rounded):

- NRMSE(f, g1) = 0.96
- NRMSE(f, g2) = 0.88
- NRMSE(f, h) = 0.63
- SSIM(f, g1) = 0.98
- SSIM(f, g2) = 0.81
- SSIM(f, h) = 0.55

In a way, both metrics handled well the modifications but `SSIM`

showed to be a more sensible by reporting lower similarities when images were in fact visually distinct, and by reporting a higher value when the images were visually very similar. The next example considers a color image (f = original image, and g = JPEG at 5% quality).

- NRMSE(f, g) = 0.92
- SSIM(f, g) = 0.61

So, it is up to you to determine what is the metric you prefer and a threshold value for it.

Now, the metrics. What I denominated as NRMSE is simply 1 - [RMSE / (`maxval`

- `minval`

)]. Where `maxval`

is the maximum intensity from the two images being compared, and respectively the same for `minval`

. RMSE is given by the square root of MSE: sqrt[(sum(A - B) ** 2) / |A|], where |A| means the number of elements in A. By doing this, the maximum value given by RMSE is `maxval`

. If you want to further understand the meaning of MSE in images, see, for example, https://ece.uwaterloo.ca/~z70wang/publications/SPM09.pdf. The metric SSIM (Structural SIMilarity) is more involved, and you can find details in the earlier included link. To easily apply the metrics, consider the following code:

```
import numpy
from scipy.signal import fftconvolve
def ssim(im1, im2, window, k=(0.01, 0.03), l=255):
"""See https://ece.uwaterloo.ca/~z70wang/research/ssim/"""
# Check if the window is smaller than the images.
for a, b in zip(window.shape, im1.shape):
if a > b:
return None, None
# Values in k must be positive according to the base implementation.
for ki in k:
if ki < 0:
return None, None
c1 = (k[0] * l) ** 2
c2 = (k[1] * l) ** 2
window = window/numpy.sum(window)
mu1 = fftconvolve(im1, window, mode='valid')
mu2 = fftconvolve(im2, window, mode='valid')
mu1_sq = mu1 * mu1
mu2_sq = mu2 * mu2
mu1_mu2 = mu1 * mu2
sigma1_sq = fftconvolve(im1 * im1, window, mode='valid') - mu1_sq
sigma2_sq = fftconvolve(im2 * im2, window, mode='valid') - mu2_sq
sigma12 = fftconvolve(im1 * im2, window, mode='valid') - mu1_mu2
if c1 > 0 and c2 > 0:
num = (2 * mu1_mu2 + c1) * (2 * sigma12 + c2)
den = (mu1_sq + mu2_sq + c1) * (sigma1_sq + sigma2_sq + c2)
ssim_map = num / den
else:
num1 = 2 * mu1_mu2 + c1
num2 = 2 * sigma12 + c2
den1 = mu1_sq + mu2_sq + c1
den2 = sigma1_sq + sigma2_sq + c2
ssim_map = numpy.ones(numpy.shape(mu1))
index = (den1 * den2) > 0
ssim_map[index] = (num1[index] * num2[index]) / (den1[index] * den2[index])
index = (den1 != 0) & (den2 == 0)
ssim_map[index] = num1[index] / den1[index]
mssim = ssim_map.mean()
return mssim, ssim_map
def nrmse(im1, im2):
a, b = im1.shape
rmse = numpy.sqrt(numpy.sum((im2 - im1) ** 2) / float(a * b))
max_val = max(numpy.max(im1), numpy.max(im2))
min_val = min(numpy.min(im1), numpy.min(im2))
return 1 - (rmse / (max_val - min_val))
if __name__ == "__main__":
import sys
from scipy.signal import gaussian
from PIL import Image
img1 = Image.open(sys.argv[1])
img2 = Image.open(sys.argv[2])
if img1.size != img2.size:
print "Error: images size differ"
raise SystemExit
# Create a 2d gaussian for the window parameter
win = numpy.array([gaussian(11, 1.5)])
win2d = win * (win.T)
num_metrics = 2
sim_index = [2 for _ in xrange(num_metrics)]
for band1, band2 in zip(img1.split(), img2.split()):
b1 = numpy.asarray(band1, dtype=numpy.double)
b2 = numpy.asarray(band2, dtype=numpy.double)
# SSIM
res, smap = ssim(b1, b2, win2d)
m = [res, nrmse(b1, b2)]
for i in xrange(num_metrics):
sim_index[i] = min(m[i], sim_index[i])
print "Result:", sim_index
```

Note that `ssim`

refuses to compare images when the given `window`

is larger than them. The `window`

is typically very small, default is 11x11, so if your images are smaller than that, there is no much "structure" (from the name of the metric) to compare and you should use something else (like the other function `nrmse`

). Probably there is a better way to implement `ssim`

, since in Matlab this run much faster.