# SciPy interpolation of large matrix

I have a ndarray (Z) with some 500000 elements on a rectangular grid (X, Y).

Now I want to interpolate values at some 100 locations in x,y which are not necessarily on the grid.

I have some code working in Matlab:

``````data = interp2(X,Y,Z, x,y);
``````

However, when I try to use the same approach with scipy.interpolate I get various errors depending on the method. For example interp2d fails with MemoryError if i specify `kind = 'linear'` and "OverflowError: Too many data points to interpolate" if I specify `kind='cubic'`. I also tried `Rbf` and `bisplev` but they also fail.

So the question is: Is there an interpolation function which allows for interpolations of large matrices? Is there another solution to the problem? (Or do I have to code a function which picks the suitable area around the points to interpolate and calls then interp2d?)

In addition: How to do this with complex numbers?

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Care to show your code? 500000 is not so big. Thanks – eat Mar 16 '11 at 16:18

As your data is on a grid, you can use RectBivariateSpline.

To work with complex numbers, you can interpolate `data.real` and `data.imag` separately (the FITPACK routines IIRC don't handle complex data).

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edit: Whoops. Just realized the OP suggested this solution in the question!

I don't know why the interpolation routines take so much time and memory to find the knots of structured data, but since you are only using a small parts of the full grid, you could break up your interpolation into patches to make things more efficient.

``````from scipy import interpolate
import numpy as np

def my_interp(X, Y, Z, x, y, spn=3):
xs,ys = map(np.array,(x,y))
z = np.zeros(xs.shape)
for i,(x,y) in enumerate(zip(xs,ys)):
# get the indices of the nearest x,y
xi = np.argmin(np.abs(X[0,:]-x))
yi = np.argmin(np.abs(Y[:,0]-y))
xlo = max(xi-spn, 0)
ylo = max(yi-spn, 0)
xhi = min(xi+spn, X[0,:].size)
yhi = min(yi+spn, Y[:,0].size)
# make slices of X,Y,Z that are only a few items wide
nX = X[xlo:xhi, ylo:yhi]
nY = Y[xlo:xhi, ylo:yhi]
nZ = Z[xlo:xhi, ylo:yhi]
intp = interpolate.interp2d(nX, nY, nZ)
z[i] = intp(x,y)[0]
return z

N = 1000
X,Y = np.meshgrid(np.arange(N), np.arange(N))
Z = np.random.random((N, N))

print my_interp(X, Y, Z, [13.2, 999.9], [0.01, 45.3])
``````
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Thanks for the example code! – Joma Apr 5 '11 at 15:18