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What is the difference between

import numpy as np


import numpy as np

all examples I tried returned the same result. Wikipedia has the same article for both?! In the description of inner() it says, that its behavior is different in higher dimensions, but I couldn't produce any different output. Which one should I use?

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up vote 22 down vote accepted


For 2-D arrays it is equivalent to matrix multiplication, and for 1-D arrays to inner product of vectors (without complex conjugation). For N dimensions it is a sum product over the last axis of a and the second-to-last of b:


Ordinary inner product of vectors for 1-D arrays (without complex conjugation), in higher dimensions a sum product over the last axes.

(Emphasis mine.)

As an example, consider this example with 2D arrays:

>>> a=np.array([[1,2],[3,4]])
>>> b=np.array([[11,12],[13,14]])
>>> np.dot(a,b)
array([[37, 40],
       [85, 92]])
>>> np.inner(a,b)
array([[35, 41],
       [81, 95]])

Thus, the one you should use is the one that gives the correct behaviour for your application.

Performance testing

(Note that I am testing only the 1D case, since that is the only situation where .dot and .inner give the same result.)

>>> import timeit
>>> setup = 'import numpy as np; a=np.random.random(1000); b = np.random.random(1000)'

>>> [timeit.timeit('np.dot(a,b)',setup,number=1000000) for _ in range(3)]
[2.6920320987701416, 2.676928997039795, 2.633111000061035]

>>> [timeit.timeit('np.inner(a,b)',setup,number=1000000) for _ in range(3)]
[2.588860034942627, 2.5845699310302734, 2.6556360721588135]

So maybe .inner is faster, but my machine is fairly loaded at the moment, so the timings are not consistent nor are they necessarily very accurate.

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@MillaWell, they are different even for 2D arrays: they are only the same in 1D. I don't know any performance difference, there are two ways of testing this: reading the source (not easy) or doing some profiling with timeit (much easier). – huon Jun 14 '12 at 13:35
I think in general I understood everything. For instance in your example you compute the .dot's first value as (1*11+2*13). How would you compute the .inner's first value of your example? – Milla Well Jun 14 '12 at 14:03
@MillaWell, you are correct. Let c = np.dot(a,b) and d = np.inner(a,b) then c[i,j] == sum(a[i,:] * b[:,j]) and d[i,j] == sum(a[i,:] * b[j,:]). – huon Jun 14 '12 at 14:11
Another way of expressing the difference would be to say that they're the same for vectors, but for 2-d arrays, np.dot(a, b) == np.inner(a, b.T) and np.dot(a, b.T) == np.inner(a, b). – senderle Jul 19 '14 at 17:08

np.dot and np.inner are identical for 1-dimensions arrays, so that is probably why you aren't noticing any differences. For N-dimension arrays, they correspond to common tensor operations.

np.inner is sometimes called a "vector product" between a higher and lower order tensor, particularly a tensor times a vector, and often leads to "tensor contraction". It includes matrix-vector multiplication.

np.dot corresponds to a "tensor product", and includes the case mentioned at the bottom of the Wikipedia page. It is generally used for multiplication of two similar tensors to produce a new tensor. It includes matrix-matrix multiplication.

If you're not using tensors, then you don't need to worry about these cases and they behave identically.

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inner is not working properly with complex 2D arrays, Try to multiply

and its transpose

array([[ 1.+1.j,  4.+4.j,  7.+7.j],
       [ 2.+2.j,  5.+5.j,  8.+8.j],
       [ 3.+3.j,  6.+6.j,  9.+9.j]])

you will get

array([[ 0. +60.j,  0. +72.j,  0. +84.j],
       [ 0.+132.j,  0.+162.j,  0.+192.j],
       [ 0.+204.j,  0.+252.j,  0.+300.j]])

effectively multiplying the rows to rows rather than rows to columns

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For 1 and 2 dimensional arrays numpy.inner works as transpose the second matrix then multiply. So for:

A = [[a1,b1],[c1,d1]]
B = [[a2,b2],[c2,d2]]
array([[a1*a2 + b1*b2, a1*c2 + b1*d2],
       [c1*a2 + d1*b2, c1*c2 + d1*d2])

I worked this out using examples like:

A=[[1  ,10], [100,1000]]
B=[[1,2], [3,4]]
array([[  21,   43],
       [2100, 4300]])

This also explains the behaviour in one dimension, numpy.inner([a,b],[c,b]) = ac+bd and numpy.inner([[a],[b]], [[c],[d]]) = [[ac,ad],[bc,bd]]. This is the extent of my knowledge, no idea what it does for higher dimensions.

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