# Compute outer product of arrays with arbitrary dimensions

I have two arrays `A,B` and want to take the outer product on their last dimension, e.g. `result[:,i,j]=A[:,i]*B[:,j]` when `A,B` are 2-dimensional.

How can I do this if I don't know whether they will be 2 or 3 dimensional?

In my specific problem `A,B` are slices out of a bigger 3-dimensional array `Z`, Sometimes this may be called with integer indices `A=Z[:,1,:], B=Z[:,2,:]` and other times with slices `A=Z[:,1:3,:],B=Z[:,4:6,:]`. Since scipy "squeezes" singleton dimensions, I won't know what dimensions my inputs will be.

The array-outer-product I'm trying to define should satisfy

``````array_outer_product( Y[a,b,:], Z[i,j,:] ) == scipy.outer( Y[a,b,:], Z[i,j,:] )
array_outer_product( Y[a:a+N,b,:], Z[i:i+N,j,:])[n,:,:] == scipy.outer( Y[a+n,b,:], Z[i+n,j,:] )
array_outer_product( Y[a:a+N,b:b+M,:], Z[i:i+N, j:j+M,:] )[n,m,:,:]==scipy.outer( Y[a+n,b+m,:] , Z[i+n,j+m,:] )
``````

for any rank-3 arrays `Y,Z` and integers `a,b,...i,j,k...n,N,...`

The kind of problem I'm dealing with involves a 2-D spatial grid, with a vector-valued function at each grid point. I want to be able to calculate the covariance matrix (outer product) of these vectors, over regions defined by slices in the first two axes.

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Can you post some example input and output? –  user545424 Jul 24 '12 at 6:27

You may have some luck with einsum :

http://docs.scipy.org/doc/numpy/reference/generated/numpy.einsum.html

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I did not know about this function. Looks very useful. Thanks. –  mlgill Jul 24 '12 at 14:03
I'd try this if I were using numpy >1.6.0 (I'm not) –  Dave Jul 24 '12 at 22:41

Assuming I've understood you correctly, I encountered a similar issue in my research a couple weeks ago. I realized that the Kronecker product is simply an outer product which preserves dimensionality. Thus, you could do something like this:

``````import numpy as np

# Generate some data
a = np.random.random((3,2,4))
b = np.random.random((2,5))

# Now compute the Kronecker delta function
c = np.kron(a,b)

# Check the shape
np.prod(c.shape) == np.prod(a.shape)*np.prod(b.shape)
``````

I'm not sure what shape you want at the end, but you could use array slicing in combination with `np.rollaxis`, `np.reshape`, `np.ravel` (etc.) to shuffle things around as you wish. I guess the downside of this is that it does some extra calculations. This may or may not matter, depending on your limitations.

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After discovering the use of ellipsis in numpy/scipy arrays I ended up implementing it as a recursive function:

``````def array_outer_product( A, B, result=None ):
''' Compute the outer-product in the final two dimensions of the given arrays.
If the result array is provided, the results are written into it.
'''
assert( A.shape[:-1] == B.shape[:-1] )
if result is None:
result=scipy.zeros( A.shape+B.shape[-1:], dtype=A.dtype )
if A.ndim==1:
result[:,:]=scipy.outer( A, B )
else:
for idx in xrange( A.shape[0] ):
array_outer_product( A[idx,...], B[idx,...], result[idx,...]
return result
``````
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