# Convert an array of arrays into a matrix

In my application, it makes a lot of sense to carry around matrices of matrices. Because numpy doesn't like it, and because working with arrays is most of the times lighter, I ended up with arrays of arrays. I am quite happy with them.

It looks like that:

[ [S11hh S11hv] [S12hh S12hv] ]
[ [S11vh S11vv] [S12vh S12vv] ]
S = [                             ]
[ [S21hh S21hv] [S22hh S22hv] ]
[ [S21vh S21vv] [S22vh S22vv] ]

(This is for coefficients of reflection and transmission in horizontal and vertical polarizations, it's optics.)

However, at some point in my code I need to do a matrix multiplication using all of S, instead of only parts of it:

M = S.dot(L)

where L looks like:

[ [L1hh L1hv] ]
[ [L1vh L1vv] ]
L = [             ]
[ [L2hh L2hv] ]
[ [L2vh L2vv] ]

If I naively run

M = S.dot(L)

I end up with something in 6 dimensions which is not what I want. Actually I expect the result to be exactly similar to what would happen if my arrays of arrays were just matrices :

[ S11hh S11hv S12hh S12hv ]
[ S11vh S11vv S12vh S12vv ]
S = [ S21hh S21hv S22hh S22hv ]
[ S21vh S21vv S22vh S22vv ]

[ L1hh L1hv ]
[ L1vh L1vv ]
L = [ L2hh L2hv ]
[ L2vh L2vv ]

Then I would re-group the elements 4 by 4.

What is an elegant numpyic way of making matrices out of these arrays ? I tried bmat, but bmat isn't happy with what I have; it works well with a list of list of matrices, but not with a 4D array, for some reason.

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You can create one big matrix instead of the array of arrays (you can use bmat for that). This will enable the big dot product. Then you can reference each sub-matrix with a sliced view.

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That was the way I wrote my code first, and I walked away from that once I realized it forced me to slice and transpose all over the place. Only in one place I do need a matrix. And as I said, bmat doesn't work out of the box for this task. –  Niriel Dec 2 '11 at 15:43

Since there is a trick about transposition (the transpose of a matrix or matrix is NOT the transpose of the big equivalent matrix), and since bmat frowns upon the original data structure, I came up with that code:

def ArrayOfArrayToMatrix(a, transpose=False):
"""
>>> a1 = np.array([[1, 2], [3, 4]])
>>> a2 = np.array([[5, 6], [7, 8]])
>>> a3 = np.array([[9, 10], [11, 12]])
>>> a4 = np.array([[13, 14], [15, 16]])

With 4D arrays (matrix of matrices):

>>> a = np.array([[a1, a2], [a3, a4]])
>>> print ArrayOfArrayToMatrix(a)
[[ 1  2  5  6]
[ 3  4  7  8]
[ 9 10 13 14]
[11 12 15 16]]
>>> a = np.array([[a1, a2]])
>>> print ArrayOfArrayToMatrix(a)
[[ 1  2  5  6]
[ 3  4  7  8]]
>>> print ArrayOfArrayToMatrix(a, True)
[[ 1  2]
[ 3  4]
[ 5  6]
[ 7  8]]

With 3D arrays (vector of matrices):

>>> a = np.array([a1, a2])
>>> print ArrayOfArrayToMatrix(a)
[[ 1  2  5  6]
[ 3  4  7  8]]
>>> print ArrayOfArrayToMatrix(a, True)
[[ 1  2]
[ 3  4]
[ 5  6]
[ 7  8]]

"""
# bmat doesn't like arrays so we feed it python lists.
dim = len(a.shape)
if dim == 3:
if transpose:
lst = [elem.T for elem in a]
else:
lst = [elem for elem in a]
elif dim == 4:
if transpose:
lst = [[elem.T for elem in row] for row in a]
else:
lst = [[elem for elem in row] for row in a]
else:
raise TypeError("Only accepts 3D or 4D arrays.")
mat = np.bmat(lst)
if transpose:
mat = mat.T
return mat

Am I reinventing the wheel?

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