# How to make scipy.interpolate give an extrapolated result beyond the input range?

I'm trying to port a program which uses a hand-rolled interpolator (developed by a mathematician colleage) over to use the interpolators provided by scipy. I'd like to use or wrap the scipy interpolator so that it has as close as possible behavior to the old interpolator.

A key difference between the two functions is that in our original interpolator - if the input value is above or below the input range, our original interpolator will extrapolate the result. If you try this with the scipy interpolator it raises a `ValueError`. Consider this program as an example:

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

x = np.arange(0,10)
y = np.exp(-x/3.0)
f = interpolate.interp1d(x, y)

print f(9)
print f(11) # Causes ValueError, because it's greater than max(x)
``````

Is there a sensible way to make it so that instead of crashing, the final line will simply do a linear extrapolate, continuing the gradients defined by the first and last two points to infinity.

Note, that in the real software I'm not actually using the exp function - that's here for illustration only!

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`scipy.interpolate.UnivariateSpline` seems to extrapolate without issues. –  heltonbiker Dec 20 '12 at 19:01

### 1. Constant extrapolation

You can use `interp` function from scipy, it extrapolates left and right values as constant beyond the range:

``````>>> from scipy import interp, arange, exp
>>> x = arange(0,10)
>>> y = exp(-x/3.0)
>>> interp([9,10], x, y)
array([ 0.04978707,  0.04978707])
``````

### 2. Linear (or other custom) extrapolation

You can write a wrapper around an interpolation function which takes care of linear extrapolation. For example:

``````from scipy.interpolate import interp1d
from scipy import arange, array, exp

def extrap1d(interpolator):
xs = interpolator.x
ys = interpolator.y

def pointwise(x):
if x < xs[0]:
return ys[0]+(x-xs[0])*(ys[1]-ys[0])/(xs[1]-xs[0])
elif x > xs[-1]:
return ys[-1]+(x-xs[-1])*(ys[-1]-ys[-2])/(xs[-1]-xs[-2])
else:
return interpolator(x)

def ufunclike(xs):
return array(map(pointwise, array(xs)))

return ufunclike
``````

`extrap1d` takes an interpolation function and returns a function which can also extrapolate. And you can use it like this:

``````x = arange(0,10)
y = exp(-x/3.0)
f_i = interp1d(x, y)
f_x = extrap1d(f_i)

print f_x([9,10])
``````

Output:

``````[ 0.04978707  0.03009069]
``````
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Unfortunately that is not what I need, I want to extrapolate continuing the gradients defined by the first and last two points of the input data. –  Salim Fadhley Apr 30 '10 at 15:32
I updated the answer to include linear extrapolation example. –  sastanin Apr 30 '10 at 15:37
I like it! Did you write that just now, or did you obtain this from a trusted / tested source? –  Salim Fadhley Apr 30 '10 at 16:24
I wrote it just now, but it seems to be correct. –  sastanin Apr 30 '10 at 16:40
First of all thanks for this help. Just a couple of notes. 1) This won't work with all interpolators directly, since they don't call the parameters `x` and `y`, but `xi` and `di` or other way. 2) For large datasets (about 300000 points in my case) the algorithm is quite slow, since every point is checked. It is better to use boolean indexing for these cases (from 25.8 to 0.09 seconds). Check my answer below for an example. Hope this helps! –  Iñigo Hernáez Corres May 30 '13 at 11:06

You can take a look at InterpolatedUnivariateSpline

Here an example using it:

``````import matplotlib.pyplot as plt
import numpy as np
from scipy.interpolate import InterpolatedUnivariateSpline

# given values
xi = np.array([0.2, 0.5, 0.7, 0.9])
yi = np.array([0.3, -0.1, 0.2, 0.1])
# positions to inter/extrapolate
x = np.linspace(0,1,50)
# spline order: 1 linear, 2 quadratic, 3 cubic ...
order = 1
# do inter/extrapolation
s = InterpolatedUnivariateSpline(xi, yi, k=order)
y = s(x)

# example showing the interpolation for linear, quadratic and cubic interpolation
plt.figure()
plt.plot(xi,yi)
for order in range(1,4):
s = InterpolatedUnivariateSpline(xi, yi, k=order)
y = s(x)
plt.plot(x,y)
plt.show()
``````
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Here's an alternative method that uses only the numpy package. It takes advantage of numpy's array functions, so may be faster when interpolating/extrapolating large arrays:

``````import numpy as np

def extrap(x, xp, yp):
"""np.interp function with linear extrapolation"""
y = np.interp(x, xp, yp)
y = np.where(x<xp[0], yp[0]+(x-xp[0])*(yp[0]-yp[1])/(xp[0]-xp[1]), y)
y = np.where(x>xp[-1], yp[-1]+(x-xp[-1])*(yp[-1]-yp[-2])/(xp[-1]-xp[-2]), y)
return y

x = np.arange(0,10)
y = np.exp(-x/3.0)
xtest = np.array((8.5,9.5))

print np.exp(-xtest/3.0)
print np.interp(xtest, x, y)
print extrap(xtest, x, y)
``````

Edit: Mark Mikofski's suggested modification of the "extrap" function:

``````def extrap(x, xp, yp):
"""np.interp function with linear extrapolation"""
y = np.interp(x, xp, yp)
y[x < xp[0]] = yp[0] + (x[x<xp[0]]-xp[0]) * (yp[0]-yp[1]) / (xp[0]-xp[1])
y[x > xp[-1]]= yp[-1] + (x[x>xp[-1]]-xp[-1])*(yp[-1]-yp[-2])/(xp[-1]-xp[-2])
return y
``````
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+1 for an actual example, but you could also use boolean indexing and here `y[x < xp[0]] = fp[0] + (x[x < xp[0]] - xp[0]) / (xp[1] - xp[0]) * (fp[1] - fp[0])` and `y[x > xp[-1]] = fp[-1] + (x[x > xp[-1]] - xp[-1]) / (xp[-2] - xp[-1]) * (fp[-2] - fp[-1])` instead of `np.where`, since the `False` option, `y` doesn't change. –  Mark Mikofski Jun 13 '12 at 20:07
An excellent suggestion. Thanks, Mark! –  ryggyr Oct 8 '12 at 21:42

What about scipy.interpolate.splrep (with degree 1 and no smoothing):

``````>> tck = scipy.interpolate.splrep([1, 2, 3, 4, 5], [1, 4, 9, 16, 25], k=1, s=0)
>> scipy.interpolate.splev(6, tck)
34.0
``````

It seems to do what you want, since 34 = 25 + (25 - 16).

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It may be faster to use boolean indexing with large datasets, since the algorithm checks if every point is in outside the interval, whereas boolean indexing allows an easier and faster comparison.

For example:

``````# Necessary modules
import numpy as np
from scipy.interpolate import interp1d

# Original data
x = np.arange(0,10)
y = np.exp(-x/3.0)

# Interpolator class
f = interp1d(x, y)

# Output range (quite large)
xo = np.arange(0, 10, 0.001)

# Boolean indexing approach

# Generate an empty output array for "y" values
yo = np.empty_like(xo)

# Values lower than the minimum "x" are extrapolated at the same time
low = xo < f.x[0]
yo[low] =  f.y[0] + (xo[low]-f.x[0])*(f.y[1]-f.y[0])/(f.x[1]-f.x[0])

# Values higher than the maximum "x" are extrapolated at same time
high = xo > f.x[-1]
yo[high] = f.y[-1] + (xo[high]-f.x[-1])*(f.y[-1]-f.y[-2])/(f.x[-1]-f.x[-2])

# Values inside the interpolation range are interpolated directly
inside = np.logical_and(xo >= f.x[0], xo <= f.x[-1])
yo[inside] = f(xo[inside])
``````

In my case, with a data set of 300000 points, this means an speed up from 25.8 to 0.094 seconds, this is more than 250 times faster.

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This is nice, but it does not work if x0 is a float, if y[0] is np.nan, or if y[-1] is np.nan. –  Stretch Nov 27 '13 at 20:21

I'm afraid that there is no easy to do this in Scipy to my knowledge. You can, as I'm fairly sure that you are aware, turn off the bounds errors and fill all function values beyond the range with a constant, but that doesn't really help. See this question on the mailing list for some more ideas. Maybe you could use some kind of piecewise function, but that seems like a major pain.

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That's the conclusion I came to, at least with scipy 0.7, however this tutorial written 21 months ago suggests that the interp1d function has a high and low attribute which can be set to "linear", the tutorial is not clear which version of scipy this applies to: projects.scipy.org/scipy/browser/branches/Interpolate1D/docs/… –  Salim Fadhley Apr 30 '10 at 15:57
It looks like this is part of a branch that hasn't been assimilated into the main version yet so there might still be some problems with it. The current code for this is at projects.scipy.org/scipy/browser/branches/interpolate/… though you might want to scroll to the bottom of the page and click to download it as plain text. I think that this looks promising though I haven't tried it yet myself. –  Justin Peel Apr 30 '10 at 16:52

I did it by adding a point to my initial arrays. In this way I avoid defining self-made functions, and the linear extrapolation (in the example below: right extrapolation) looks ok.

import numpy as np
from scipy import interp as itp

xnew = np.linspace(0,1,51)
x1=xold[-2]
x2=xold[-1]
y1=yold[-2]
y2=yold[-1]
right_val=y1+(xnew[-1]-x1)*(y2-y1)/(x2-x1)
x=np.append(xold,xnew[-1])
y=np.append(yold,right_val)
f = itp(xnew,x,y)

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