# interpolate missing values 2d python

I have a 2d array(or matrix if you prefer) with some missing values represented as `NaN`. The missing values are typically in a strip along one axis, eg:

``````1   2   3 NaN   5
2   3   4 Nan   6
3   4 Nan Nan   7
4   5 Nan Nan   8
5   6   7   8   9
``````

where I would like to replace the `NaN`'s by somewhat sensible numbers.

I looked into delaunay triangulation, but found very little documentation.

I tried using `astropy`'s convolve as it supports use of 2d arrays, and is quite straightforward. The problem with this is that convolution is not interpolation, it moves all values towards the average (which could be mitigated by using a narrow kernel).

This question should be the natural 2-dimensional extension to this post. Is there a way to interpolate over `NaN`/missing values in a 2d-array?

• There are many ways you could interpolate this. One difficulty is that your data is no longer rectangular, and many simple 2d interpolation algorithms require this, but it is still possible. Do you have any particular requirements for the interpolation? – Jeremy West Jun 6 '16 at 16:17
• For example, this docs.scipy.org/doc/scipy-0.14.0/reference/generated/… probably does what you need. Just pass in the data points that aren't NaN and then resample at the NaN ones after constructing the interpolation. – Jeremy West Jun 6 '16 at 16:26
• Also, this question: stackoverflow.com/questions/5146025/… seems to be essentially the same. – Jeremy West Jun 6 '16 at 16:28
• @JeremyWest Thank you very much for the links, I think `griddata` is close to what I was looking for. – M.T Jun 6 '16 at 18:37

Yes you can use `scipy.interpolate.griddata` and masked array and you can choose the type of interpolation that you prefer using the argument `method` usually `'cubic'` do an excellent job:

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

#Let's create some random  data
array = np.random.random_integers(0,10,(10,10)).astype(float)
#values grater then 7 goes to np.nan
array[array>7] = np.nan
``````

That looks something like this using `plt.imshow(array,interpolation='nearest')` :

``````x = np.arange(0, array.shape[1])
y = np.arange(0, array.shape[0])
xx, yy = np.meshgrid(x, y)
#get only the valid values

GD1 = interpolate.griddata((x1, y1), newarr.ravel(),
(xx, yy),
method='cubic')
``````

This is the final result:

Look that if the nan values are in the edges and are surrounded by nan values thay can't be interpolated and are kept `nan`. You can change it using the `fill_value` argument.

# How would this work if there is a 3x3 region of NaN-values, would you get sensible data for the middle point?

It depends on your kind of data, you have to perform some test. You could for instance mask on purpose some good data try different kind of interpolation e.g. cubic, linear etc. etc. with the array with the masked values and calculuate the difference between the values interpolated and the original values that you had masked before and see which method return you the minor difference.

You can use something like this:

``````reference = array[3:6,3:6].copy()
array[3:6,3:6] = np.nan
method = ['linear', 'nearest', 'cubic']

for i in method:
GD1 = interpolate.griddata((x1, y1), newarr.ravel(),
(xx, yy),
method=i)
meandifference = np.mean(np.abs(reference - GD1[3:6,3:6]))
print ' %s interpolation difference: %s' %(i,meandifference )
``````

That gives something like this:

``````   linear interpolation difference: 4.88888888889
nearest interpolation difference: 4.11111111111
cubic interpolation difference: 5.99400137377
``````

Of course this is for random numbers so it's normal that the result may vary a lot. So the best thing to do is to test on "on purpose masked" piece of your dataset and see what happen.

• How would this work if there is a 3x3 region of NaN-values, would you get sensible data for the middle point? – M.T Sep 20 '16 at 18:00
• @M.T Hi, I have edited the answer, to answer this question. – G M Sep 21 '16 at 8:22

I'd actually manually go through this matrix row by row, and whenever you start encountering a list of Nans, keep track of the number immediately before the Nans and immediately after, and the number of Nans you saw before going back to ordinary numbers. Once those numbers are found, it would be possible to overwrite Nans with interpolated values yourself.