# numpy: operating on multidimensional arrays

Sorry for title's vagueness. I have two related questions.

First, let's say I have a function "hessian" that given two parameters (x, y) returns a matrix. I now want to compute that matrix for (x,y) running over a two dimensional space. I'd like to do something like:

x = linspace(1, 4, 100).reshape(-1,1)
y = linspace(1, 4, 100).reshape(1,-1)
H = vectorize(hessian)(x, y)


with the resulting H of shape (100,100,2,2). The above doesn't work (ValueError: setting an array element with a sequence). The only thing I came up with is

H = array([ hessian(xx, yy) for xx in x.flat for yy in y.flat ]).reshape(100,100,2,2)


is there a better, more direct, way ?

Second, now H has shape (100,100,2,2) and dominant_eigenvector(X) does exactly what you think.

U, V = hsplit(array(map(dominant_eigenvector, H.reshape(10000,2,2))), 2)


I again need to use list comprehension to do the iteration and repack the result in an array specifying manually the shape. Is there a more direct way to achieve the same result ?

Thanks!

edit: as suggested by Paul and JoshAdel, I implemented a version of hessian that works with arrays, here it is

def hessian(w1, w2):
w1 = atleast_1d(w1)[...,newaxis,newaxis]
w2 = atleast_1d(w2)[...,newaxis,newaxis]
o1, o2 = ix_(*map(xrange, Z.shape))
W = Z * pow(w1, o1) * pow(w2, o2)
A = (W).sum()
B = (W * o1).sum()
C = (W * o2).sum()
D = (W * o1 * o1).sum()
E = (W * o1 * o2).sum()
F = (W * o2 * o2).sum()
return array([[ D/A - B/A*B/A, E/A - B/A*C/A ],
[ E/A - B/A*C/A, F/A - C/A*C/A ]])


Z can be considered a global array of roughly 250x150. o1 and o2 index the two dimensions of Z to compute things like $\sum_{i,j} Z_{ij} * i * j$.

The problem with this version is that intermediate arrays are just too big. If w1 and w2 are arrays like w1_k w2_l W becomes W_{k,l,i,j} on which numpy gives ValueError: too big.

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Is there a reason hessian cannot be modified to accept arrays? –  Paul Mar 15 '11 at 3:44
uhm, hessian does its computations on something which already has three indices. Yes, in principle it would be possible to rewrite it to accept arrays I think, just ... big headaches ahead –  andreabedini Mar 15 '11 at 4:01
I bet if you post what hessian is doing, there are several of us who could help you with re-write it in a compact way that takes and works on arrays directly. –  JoshAdel Mar 15 '11 at 18:13
yes, I made a version that works with arrays too, but since the number of dimensions increases the size gets quite limited, but I'll post the code anyway –  andreabedini Mar 15 '11 at 23:13
Did you find a way to handle this? I am running into a similar issue. –  dtlussier Nov 13 '12 at 4:32
x = linspace(1, 4, 100)