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I have a 3d array of position data, which I'd like to take 2-d slices from. However the slices vary in the z depth with x (and y eventually).

E.g. An array 100x100x100, and I want the first slice to be the parallelogram starting at

x=0,y=0 => x=100,y=100 containing the points in the z direction 0-25 when at x=0, and changing linearly to z=25-50 by the time x=100. So a sort of diagonal slice.

Is there an efficient way to do this in numpy. Ideally something like

    newarray = oldarray[z> x/100*25.0 && z < 25+x/100*25.0]
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Could you give an example (I don't quite follow), like what you expect this to look like as a 3x3? – Andy Hayden Oct 2 '12 at 14:48
If you think of the data as a cube, then a simple slice would be to take a flat section off the top. OK - in 2-d it would be [[6, 5, 4], [1, 2, 3], [5, 7, 9]] a 1 deep slice would be [ 6, 5, 4]. However I want a semi diagonal slice, which might be [6, 5, 3] (the 3 coming from the 2nd row). Followed by [1, 2, 9]. Now scale it up to 100x100, and take a slanting cut starting on first row, to include the subsequent 25 rows, on the LHS, but on the RHS of the array taking rows 25-50 and interpolating between. – Julian Oct 2 '12 at 15:03

2 Answers 2

up vote 1 down vote accepted

Because your desired data will probably not be representable as a strided view of the original, you will have to use advanced indexing to pull out the coordinates you want.

c = np.r_[:100]
xi = c.reshape((100, 1, 1))
yi = c.reshape((1, 100, 1))
zi = np.empty((100, 100, 25), dtype=int)
for x in xrange(100):
    for y in xrange(100):
        zi[x,y] = np.arange(x*25/100, x*25/100+25) # or whatever other function

newarray = oldarray[xi, yi, zi]

Slicing oldarray using the numpy arrays xi, yi, zi triggers advanced indexing. Numpy will create a new array having the same shape as that formed by broadcasting xi, yi, zi (so in this case, since xi is (100, 1, 1), yi is (1, 100, 1), and zi is (100, 100, 25), the output will be (100, 100, 25)).

Numpy then fills that array using corresponding elements of xi, yi and zi (with broadcasting), so that newarray[i, j, k] = oldarray[xi[i, 0, 0], yi[0, j, 0], zi[i, j, k]]

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I've read this through a few times, and can't see how it works conceptually! – Julian Oct 3 '12 at 11:53
Yeah, advanced indexing can be a bit of a headbreaker. It's quite different from standard indexing. I'll add an explanation... – nneonneo Oct 3 '12 at 15:43

You can do this using map_coordinates. Here is a small example for a 3x3x3 volume:

a = np.arange(27).reshape(3,3,3)
xi,yi = np.meshgrid(range(3),range(3))
zi = xi*.25+yi*.25
inds = np.array([xi.reshape(1,9),yi.reshape(1,9),zi.reshape(1,9)])
>> array([[ 0,  9, 18],
       [ 3, 12, 22],
       [ 6, 16, 25]])

Note there may be a better way to do this without all the reshaping.

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