I have a 3D array holding voxels from a mri dataset. The model could be clinched along one or more directions. E.g. the voxel size (x,y,z) could be 0.5,0.5,2 mm. Now I want to resample the 3D array into an array holding 1,1,1 mm voxels. For this I need to make the x/y dimensions smaller and the z dimension bigger and interpolate the voxel values. My question is: Is there a simple function in numpy or scipy for doing such a resampling of a simple 3d array?

Loading model from *.nii file:

img = nib.load(sFileName)
array = np.array(img.dataobj).astype("uint8") # 3d array with e.g. 0.5,0.5,2 mm
# TODO resample
  • scipy.interpolate.RegularGridInterpolator probably works for your case. – Paul Brodersen Dec 12 '17 at 15:36
  • I will try it out. – dgrat Dec 12 '17 at 15:50


This is probably the best approach, the zoom method is designed for precisely this kind of task.

from scipy.ndimage import zoom
new_array = zoom(array, (0.5, 0.5, 2))

changes the size in each dimension by the specified factor. If the original shape of array was, say, (40, 50, 60), the new one will be (20, 25, 120).


SciPy has a large set of methods for signal processing. Most relevant here are decimate and resample_poly. I use the latter below

from scipy.signal import resample_poly
factors = [(1, 2), (1, 2), (2, 1)]
for k in range(3):
    array = resample_poly(array, factors[k][0], factors[k][1], axis=k)

The factors (which must be integers) are of up- and down-sampling. That is:

  • (1, 2) means size divided by 2
  • (2, 1) means size multiplied by 2
  • (2, 3) would mean up by 2 then down by 3, so the size is multiplied by 2/3

Possible downside: the process happens independently in each dimension, so the spatial structure may not be taken into account as well as by ndimage methods.


This is more hands-on, but also more laborious and without the benefit of filtering: straightforward downsampling. We have to make a grid for the interpolator, using original step sizes in each direction. After the interpolator is created, it needs to be evaluated on a new grid; its call method takes a different kind of grid format, prepared with mgrid.

values = np.random.randint(0, 256, size=(40, 50, 60)).astype(np.uint8)  # example

steps = [0.5, 0.5, 2.0]    # original step sizes
x, y, z = [steps[k] * np.arange(array.shape[k]) for k in range(3)]  # original grid
f = RegularGridInterpolator((x, y, z), values)    # interpolator

dx, dy, dz = 1.0, 1.0, 1.0    # new step sizes
new_grid = np.mgrid[0:x[-1]:dx, 0:y[-1]:dy, 0:z[-1]:dz]   # new grid
new_grid = np.moveaxis(new_grid, (0, 1, 2, 3), (3, 0, 1, 2))  # reorder axes for evaluation
new_values = f(new_grid)

Downside: e.g., when a dimension is reduced by 2, it will in effect drop every other value, which is simple downsampling. Ideally, one should average neighboring values in this case. In terms of signal processing, low-pass filtering precedes downsampling in decimation.

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