How can a list of vectors be elegantly normalized, in NumPy?

Here is an example that does not work:

from numpy import *

vectors = array([arange(10), arange(10)])  # All x's, then all y's
norms = apply_along_axis(linalg.norm, 0, vectors)

# Now, what I was expecting would work:
print vectors.T / norms  # vectors.T has 10 elements, as does norms, but this does not work

The last operation yields "shape mismatch: objects cannot be broadcast to a single shape".

How can the normalization of the 2D vectors in vectors be elegantly done, with NumPy?

Edit: Why does the above not work while adding a dimension to norms does work (as per my answer below)?

  • FYI, a commenter may have a faster method, I edited my answer with more detail. – Geoff Oct 26 '13 at 15:21

Well, unless I missed something, this does work:

vectors / norms

The problem in your suggestion is the broadcasting rules.

vectors  # shape 2, 10
norms  # shape 10

The shape do not have the same length! So the rule is to first extend the small shape by one on the left:

norms  # shape 1,10

You can do that manually by calling:

vectors / norms.reshape(1,-1)  # same as vectors/norms

If you wanted to compute vectors.T/norms, you would have to do the reshaping manually, as follows:

vectors.T / norms.reshape(-1,1)  # this works
  • why not just do (vectors/norms).T if the OP wants this transposed. It seems both simple and elegant to me. – Justin Peel May 17 '10 at 18:58
  • Ah, ah! so the dimension extension is done on the left: this indeed explains the observed behavior. Thanks! – Eric O Lebigot May 17 '10 at 19:58

Computing the magnitude

I came across this question and became curious about your method for normalizing. I use a different method to compute the magnitudes. Note: I also typically compute norms across the last index (rows in this case, not columns).

magnitudes = np.sqrt((vectors ** 2).sum(-1))[..., np.newaxis]

Typically, however, I just normalize like so:

vectors /= np.sqrt((vectors ** 2).sum(-1))[..., np.newaxis]

A time comparison

I ran a test to compare the times, and found that my method is faster by quite a bit, but Freddie Witherdon's suggestion is even faster.

import numpy as np    
vectors = np.random.rand(100, 25)

# OP's
%timeit np.apply_along_axis(np.linalg.norm, 1, vectors)
# Output: 100 loops, best of 3: 2.39 ms per loop

# Mine
%timeit np.sqrt((vectors ** 2).sum(-1))[..., np.newaxis]
# Output: 10000 loops, best of 3: 13.8 us per loop

# Freddie's (from comment below)
%timeit np.sqrt(np.einsum('...i,...i', vectors, vectors))
# Output: 10000 loops, best of 3: 6.45 us per loop

Beware though, as this StackOverflow answer notes, there are some safety checks not happening with einsum, so you should be sure that the dtype of vectors is sufficient to store the square of the magnitudes accurately enough.

  • 1
    Interesting timing results (I obtain respectively 0.8 s and 1.4 s, with the more robust %timeit function of IPython), thanks! – Eric O Lebigot Oct 8 '12 at 8:53
  • 2
    I have found np.sqrt(np.einsum('...i,...i', vectors, vectors)) to be ~4 times faster than Method 1 as given above. – Freddie Witherden Sep 27 '13 at 23:07
  • @FreddieWitherden - Thanks for the comment, I didn't know about einsum. There's in interesting related SO question here: stackoverflow.com/questions/18365073/… It will typically be faster, but may not be safe (depending on the dtype of the vector). – Geoff Oct 26 '13 at 15:04
  • @FreddieWitherden, your method gives different (but np.allclose) values to mine. – Geoff Oct 26 '13 at 15:19
  • @EOL - Thanks, I switched to ipython, and updated my answer. It turns out my HUGE array was giving some serious overhead. With a smaller one (in my new answer) the speed difference is much more noticeable. – Geoff Oct 26 '13 at 15:21

Alright: NumPy's array shape broadcast adds dimensions to the left of the array shape, not to its right. NumPy can however be instructed to add a dimension to the right of the norms array:

print vectors.T / norms[:, newaxis]

does work!

  • 3
    Just a note, I use norms[..., np.newaxis] in case the matrix is not just 2D. It would work with a 3D (or more) tensor as well. – Geoff Oct 26 '13 at 15:22

there is already a function in scikit learn:

import sklearn.preprocessing as preprocessing
norm =preprocessing.normalize(m, norm='l2')*

More info at:


  • Interesting information, but the question is explicitly about NumPy. It would be better put it in a comment to the original question. – Eric O Lebigot Nov 28 '13 at 11:39

My preferred way to normalize vectors is by using numpy's inner1d to calculate their magnitudes. Here's what's been suggested so far compared to inner1d

import numpy as np
from numpy.core.umath_tests import inner1d
COUNT = 10**6 # 1 million points

points = np.random.random_sample((COUNT,3,))
A      = np.sqrt(np.einsum('...i,...i', points, points))
B      = np.apply_along_axis(np.linalg.norm, 1, points)   
C      = np.sqrt((points ** 2).sum(-1))
D      = np.sqrt((points*points).sum(axis=1))
E      = np.sqrt(inner1d(points,points))

print [np.allclose(E,x) for x in [A,B,C,D]] # [True, True, True, True]

Testing performance with cProfile:

import cProfile
cProfile.run("np.sqrt(np.einsum('...i,...i', points, points))**0.5") # 3 function calls in 0.013 seconds
cProfile.run('np.apply_along_axis(np.linalg.norm, 1, points)')       # 9000018 function calls in 10.977 seconds
cProfile.run('np.sqrt((points ** 2).sum(-1))')                       # 5 function calls in 0.028 seconds
cProfile.run('np.sqrt((points*points).sum(axis=1))')                 # 5 function calls in 0.027 seconds
cProfile.run('np.sqrt(inner1d(points,points))')                      # 2 function calls in 0.009 seconds

inner1d computed the magnitudes a hair faster than einsum. So using inner1d to normalize:

n = points/np.sqrt(inner1d(points,points))[:,None]
cProfile.run('points/np.sqrt(inner1d(points,points))[:,None]') # 2 function calls in 0.026 seconds

Testing against scikit:

import sklearn.preprocessing as preprocessing
n_ = preprocessing.normalize(points, norm='l2')
cProfile.run("preprocessing.normalize(points, norm='l2')") # 47 function calls in 0.047 seconds
np.allclose(n,n_) # True

Conclusion: using inner1d seems to be the best option

  • For reference, the question actually calls for calculating the norm along the first dimension, not the second (see the caveat added to Geoff's answer). How would this change the results? There might be an impact, because of the way memory is accessed, especially if you have a larger second dimension (instead of 3 in your example). – Eric O Lebigot Feb 23 '16 at 17:12

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