# Euclidean distances between several images and one base image

I have a matrix `X` of dimensions `(30x8100)` and another one `Y` of dimensions `(1x8100)`. I want to generate an array containing the difference between them `(X[1]-Y, X[2]-Y,..., X[30]-Y)` Can anyone help?

-

All you need for that is

``````X - Y
``````

Since several people have offered answers that seem to try to make the shapes match manually, I should explain:
Numpy will automatically expand `Y`'s shape so that it matches with that of `X`. This is called broadcasting, and it usually does a very good job of guessing what should be done. In ambiguous cases, an `axis` keyword can be applied to tell it which direction to do things. Here, since `Y` has a dimension of length 1, that is the axis that is expanded to be length `30` to match with `X`'s shape.

For example,

``````In [87]: import numpy as np

In [88]: n, m = 3, 5

In [89]: x = np.arange(n*m).reshape(n,m)

In [90]: y = np.arange(m)[None,...]

In [91]: x.shape
Out[91]: (3, 5)

In [92]: y.shape
Out[92]: (1, 5)

In [93]: (x-y).shape
Out[93]: (3, 5)

In [106]: x
Out[106]:
array([[ 0,  1,  2,  3,  4],
[ 5,  6,  7,  8,  9],
[10, 11, 12, 13, 14]])

In [107]: y
Out[107]: array([[0, 1, 2, 3, 4]])

In [108]: x-y
Out[108]:
array([[ 0,  0,  0,  0,  0],
[ 5,  5,  5,  5,  5],
[10, 10, 10, 10, 10]])
``````

But this is not really a euclidean distance, as your title seems to suggest you want:

``````df = np.asarray(x - y)                # the difference between the images
dst = np.sqrt(np.sum(df**2, axis=1))  # their euclidean distances
``````
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I am getting `ValueError: input must be a square array ` –  user2229953 Apr 17 '13 at 19:20
@user2229953 Oh, because your `x` and `y` have type `matrix`, use `np.asarray` so that the squaring will be element-wise, see my edit. –  askewchan Apr 17 '13 at 19:21
Thank you ! But the results are wired ! `dst [ 11368.09117391 7238.28732897 5975.85568237 6516.33956578 4690.22604361 4727.27377993 5210.6757694 4917.37040654 4315.19124481 4351.23160123 4219.13923247 4003.55476258 4175.54212706 4102.91009999 4330.4599796 4184.70386037 4134.89623796 4162.12512307 3828.49532333 3930.67847956 3766.93023507 3666.34224248 4040.05576148 3848.65880709 3845.35577393 3869.77351631 3836.28039808 3801.06876888 3799.32736535 3646.77473834]` –  user2229953 Apr 17 '13 at 19:48
@user2229953 Did you have something else in mind? It makes sense that the shape of `dst` is `(30,)`, because it's how different each image is from the base image. The units of that 'distance' is basically pixel brightness (assuming grayscale image). Then, `dst[i]` says how different is the brightness of image `images[i]` from the base (input?) image. Finding `imin = argmin(dst)` will say `images[imin]` is the most similar image to the input image. –  askewchan Apr 17 '13 at 19:51
Well, similar to our eyes (and possibly for your application) is not necessarily the same thing as closest in the euclidean distance. Euclidean distance compares each pixel at a given location, as in, `image1[i,j]` is compared to `image2[i,j]`. The 'closest' image in euclidean distance is the one for which all these comparisons, in total, are the least. Note that the same image, rotated by a bit, might be very 'far' in this sense from itself. –  askewchan Apr 17 '13 at 20:14
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Just iterate rows from your numpy array and you can actually just subtract them and numpy will make a new array with the differences!

``````import numpy as np
final_array = []
#X is a numpy array that is 30X8100 and Y is a numpy array that is 1X8100
for row in X:
output = row - Y
final_array.append(output)
``````

output will be your resulting array of X[0] - Y, X[1] - Y etc. Now your final_array will be an array with 30 arrays inside, each that have the values of the X-Y that you need! Simple as that. Just make sure you convert your matrices to a numpy arrays first

Edit: Since numpy broadcasting will do the iteration, all you need is one line once you have your two arrays:

``````final_array = X - Y
``````

And then that is your array with the differences!

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The looping is done automatically by numpy broadcasting. –  askewchan Apr 17 '13 at 19:39
@askewchan Oh, didn't know that...then it's incredibly simple, I made the edits! –  Ryan Saxe Apr 17 '13 at 19:46

use `array` and use `numpy` broadcasting in order to subtract it from `Y`

init the matrix:

``````>>> from numpy import *
>>> a = array([[1,2,3],[4,5,6]])
``````

Accessing the second row in `a`:

``````>>> a[1]
array([4, 5, 6])
``````

Subtract array from `Y`

``````>>> Y = array([3,9,0])
>>> a - Y

array([[-2, -7,  3],
[ 1, -4,  6]])
``````
-
The looping is done automatically by numpy broadcasting. –  askewchan Apr 17 '13 at 19:24
@askewchan Thanks, I updated the answer –  0x90 Apr 17 '13 at 19:27
``````a1 = numpy.array(X) #make sure you have a numpy array like [[1,2,3],[4,5,6],...]
This `a2 = [a2] * len(a1[0]) #make a2 as wide as a1` is done automatically by numpy broadcasting. –  askewchan Apr 17 '13 at 19:27