# NaN interpolation in 2D array. Sparsely populated

I have a 2D array with some NaN values. I would like to inpaint (interpolate) those values using the locations where I have data. The array looks like the one below.

If possible I would like to do the interpolation so that, as I move away from non-NaN values, I get increasingly closer to the value 0.

How can I do this?

I read about gridddata, but it seems to be designed to work with unstructured N-dim data. I also read the answers in other threads, but I think their starting point is different.

``````array([[        nan,         nan,         nan,         nan,         nan,
nan,         nan,         nan,         nan,         nan],
[        nan,         nan,         nan,         nan,         nan,
nan,         nan,         nan,         nan,         nan],
[        nan,         nan,         nan,         nan,         nan,
nan,         nan,         nan,         nan,         nan],
[        nan,         nan,         nan,         nan,         nan,
nan,         nan,         nan,         nan,         nan],
[ 1.        ,  0.        ,  1.        ,  0.        ,  0.25      ,
nan,  0.        ,         nan,         nan,         nan],
[        nan,  0.        ,         nan,  0.25      ,  0.66666667,
0.25      ,  0.66666667,  0.        ,  1.        ,         nan],
[ 0.        ,  0.5       ,  0.66666667,  0.8       ,  0.66666667,
0.8       ,  0.5       ,  0.83333333,         nan,         nan],
[ 0.625     ,  0.5625    ,  0.9       ,  0.8       ,  0.8       ,
0.83333333,  0.57142857,  0.66666667,  0.5       ,         nan],
[        nan,  1.        ,  0.71428571,  0.85714286,  1.        ,
1.        ,  1.        ,         nan,         nan,         nan],
[        nan,         nan,         nan,         nan,  1.        ,
1.        ,         nan,         nan,         nan,         nan]])
``````
-

There are dozens of possible approaches based on what kind of interpolation technique you would like to use. In fact, as your data is rather surrounded by NaNs I would rather think about it as a function smoothing then interpolating. If you want to get closer to zero the more away you are from the not NaNs in terms of euclidean distance on your 2d map I would suggest something like:

1. Consider each not NaN data point `X[i,j]` as a Gaussian centered in `[i,j]`, with variance=1, scaled so its `pdf( [i,j] ) = X[i,j]`, so `f_ij( [a,b] ) = X[i,j] * exp( -|| [a,b] - [i,j] ||^2/2 )`.
2. For each NaN data point `X[a,b]` set `X[a,b] = sum( f_ij( [a,b] ) )` where sumation is performed over all `[i,j]` indices of not NaN data points

As a result you get something like a "density estimation", and by changing the variance (which I suggested to use =1) you can modify the "speed of vanishing" the values.

So the code would be just a one loop over all NaNs, and for each of them you loop through all not NaNs and sum the gaussians values.

It would sth like this:

``````nans    = np.array( np.where(  np.isnan(X) ) ).T
notnans = np.array( np.where( ~np.isnan(X) ) ).T
for p in nans:
X[p[0],p[1]] = sum( X[q[0],q[1]]*np.exp(-(sum((p-q)**2))/2) for q in notnans )
``````
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If you do choose to go down this route, you should know that Scipy has a class for radial basis functions - see here, and this example here –  ali_m Oct 6 '13 at 16:27