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The data I have is always on a second degree polynomial (quadratic function). I want to find the peak of the interpolated function as accurately as possible.

Data sample points

So far I've been using interp1d and then extract the peak value using linspace and a simple for loop. Although you can use a large number of newly generated samples in linspace you can still be more precise using the derivative of the fitted polynomial.
I haven't found a way to do that using interp1d.

Now the only function I've found that returns the fitted polynomial coefficients is polyfit, but this fitted function is quite inaccurate (most of the time the function doesn't even go through the data points).

<code>interp1d</code> and <code>polyfit</code> functions

I've tried using UnivariateSpline and the fitted function seems to be quite accurate and it's very simple to get the derivative spline and its root.

Other polynomial fitting functions (BarycentricInterpolator, KroghInterpolator, ...) state that they are not computing polynomial coefficients for reasons of numerical stability.

How accurate is UnivariateSpline and its derivatives, or are there any better options out there?

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If all you need is to find the min/max of a second degree polynomial why not do this:

import matplotlib.pyplot as plt
from scipy.interpolate import KroghInterpolator
import numpy as np

x=range(-20,20)
y=[]
for i in x:
    y.append((i**2)+25)

x=x[1::5]
y=y[1::5]

f=KroghInterpolator(x,y)
xfine=np.arange(min(x),max(x),.5)
yfine=f(xfine)

val_interp=min(yfine)
print val_interp

plt.scatter(x,y)
plt.plot(xfine, yfine)
plt.show()
  • But this method still relies on the step size of np.arange, which is in this case 0.5. I'd like to get the maximum of the quadratic function down to float/double precision. – Tjaz Brelih Jul 8 '16 at 8:14
  • @TjazBrelih It does give you float/double point precision. Change y.append((i**2)+25) to y.append((i**2)+25.086) . Then run the program. The interpolation at 0.5 spacing finds the minimum value even though that value didn't exist in the original data you pass in. – Will.Evo Jul 9 '16 at 13:33
  • This only works if the function isn't shifted along the x axis. When you change y.append((i**2)+25) to y.append(((i+0.2)**2)+25), you wont find the true peak, only the max/min value of the interpolated function sampled at the interval of 0.5. – Tjaz Brelih Jul 11 '16 at 7:54
  • @TjazBrelih I have no idea what you are talking about. The script works fine even with a shift in x-axis...you just need to change the spacing of xfine to be a bit smaller (for your example a spacing of 0.1 works perfectly). Your original question asked for a way of finding the peak y value accurately...my solution does just that. Replace the bits of my code that generate data with your data and you have a solution. – Will.Evo Jul 11 '16 at 19:36
  • The problem is that the shift in x axis is essentialy random. Another thing is that I don't have just one set of data to interpolate, there are many and each has a shift of their own. This method would work if you would use the smallest possible spacing for np.arange. In the end I opted for polyfit method since it returns the actual coefficients of the quadratic function so you get the x and y coordinates of the peak by deriving them by "hand". – Tjaz Brelih Jul 12 '16 at 9:19
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In the end I went with polyfit. Although the fitted function didn't go exactly through the data points the end result was still good. From the returned coefficients I got the desired x and y coordinates of the peak.

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