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I have a 1 dimensional array A of floats that is mostly good but a few of the values are missing. Missing data is replace with nan(not a number). I have to replace the missing values in the array by linear interpolation from the nearby good values. So, for example:

F7(np.array([10.,20.,nan,40.,50.,nan,30.])) 

should return

np.array([10.,20.,30.,40.,50.,40.,30.]). 

What's the best of way of doing this using Python?

Any help would be much appreciated

Thanks

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3  
Do you really mean linear interpolation? Or do you actually mean average? -- I also assume that the first and last values are guaranteed to not be NaN? –  mgilson Oct 31 '12 at 20:29
    
It was just an average on the example. The linear interpolation should really just find the missing values in a linear equation. And yeah, the first and last values aren't NaN. –  user1789657 Oct 31 '12 at 20:43

2 Answers 2

I would go with pandas. A minimalistic approach with a oneliner:

from pandas import *
a=np.array([10.,20.,nan,40.,50.,nan,30.])
Series(a).interpolate()   

Out[219]:
0    10
1    20
2    30
3    40
4    50
5    40
6    30

Or if you want to keep it as an array:

Series(a).interpolate().values

Out[221]:
array([ 10.,  20.,  30.,  40.,  50.,  40.,  30.])
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@larsmans -- i was just going to suggest .values , that also returns an array :) –  root Oct 31 '12 at 20:46
    
Saw it, deleted my comment. Pandas is still on the "libraries to learn" list :) –  larsmans Oct 31 '12 at 22:44

You could use scipy.interpolate.interp1d:

>>> from scipy.interpolate import interp1d
>>> import numpy as np
>>> x = np.array([10., 20., np.nan, 40., 50., np.nan, 30.])
>>> not_nan = np.logical_not(np.isnan(x))
>>> indices = np.arange(len(x))
>>> interp = interp1d(indices[not_nan], x[not_nan])
>>> interp(indices)
array([ 10.,  20.,  30.,  40.,  50.,  40.,  30.])

EDIT: it took me a while to figure out how np.interp works, but that can do the job as well:

>>> np.interp(indices, indices[not_nan], x[not_nan])
array([ 10.,  20.,  30.,  40.,  50.,  40.,  30.])
share|improve this answer
    
I think I would use len(x) rather than *x.shape. It seems slightly more explicit since we're only doing 1D anyway (and this doesn't generalize to more dimensions) -- but +1 for a working interpolate solution. –  mgilson Oct 31 '12 at 20:36
    
Rather than generating np.arange(len(x)) twice, why not just do it once and store the result? Also, I don't think you need scipy for this. np.interp seems like it would do the same thing in this scenario –  mgilson Oct 31 '12 at 20:39
    
@mgilson: you were right three times. Thanks, updated the answer. –  larsmans Oct 31 '12 at 20:43
    
It's a good answer. I tend to be more picky about the answers I like ... –  mgilson Oct 31 '12 at 20:47

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