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I have an energy spectrum from a cosmic ray detector. The spectrum follows an exponential curve but it will have broad (and maybe very slight) lumps in it. The data, obviously, contains an element of noise.

I'm trying to smooth out the data and then plot its gradient. So far I've been using the scipy sline function to smooth it and then the np.gradient().

As you can see from the picture, the gradient function's method is to find the differences between each point, and it doesn't show the lumps very clearly.

I basically need a smooth gradient graph. Any help would be amazing!

I've tried 2 spline methods:

def smooth_data(y,x,factor):
    print "smoothing data by interpolation..."
    xnew=np.linspace(min(x),max(x),factor*len(x))
    smoothy=spline(x,y,xnew)
    return smoothy,xnew

def smooth2_data(y,x,factor):
    xnew=np.linspace(min(x),max(x),factor*len(x))
    f=interpolate.UnivariateSpline(x,y)
    g=interpolate.interp1d(x,y)
    return g(xnew),xnew

edit: Tried numerical differentiation:

def smooth_data(y,x,factor):
    print "smoothing data by interpolation..."
    xnew=np.linspace(min(x),max(x),factor*len(x))
    smoothy=spline(x,y,xnew)
    return smoothy,xnew

def minim(u,f,k):
    """"functional to be minimised to find optimum u. f is original, u is approx"""
    integral1=abs(np.gradient(u))
    part1=simps(integral1)
    part2=simps(u)
    integral2=abs(part2-f)**2.
    part3=simps(integral2)
    F=k*part1+part3
    return F


def fit(data_x,data_y,denoising,smooth_fac):
    smy,xnew=smooth_data(data_y,data_x,smooth_fac)
    y0,xnnew=smooth_data(smy,xnew,1./smooth_fac)
    y0=list(y0)
    data_y=list(data_y)
    data_fit=fmin(minim, y0, args=(data_y,denoising), maxiter=1000, maxfun=1000)
    return data_fit

However, it just returns the same graph again!

Data, smoothed data and gradients

share|improve this question
    
What level of smoothing would make sense for you? the one that yields a derivative between about -10 and +1, with most of the values between -1 and +1? – EOL Apr 8 '13 at 4:22
    
Side note: I recommend that you read and apply PEP 8 to your coding "style". This will make your code easier to read, as most Python programmer follow it (or a good part of it). Little details like the usual spaces around = in assignments or after commas in parameter lists do make the code more legible. – EOL Apr 9 '13 at 11:26
up vote 6 down vote accepted

There is an interesting method published on this: Numerical Differentiation of Noisy Data. It should give you a nice solution to your problem. More details are given in another, accompanying paper. The author also gives Matlab code that implements it; an alternative implementation in Python is also available.

If you want to pursue the interpolation with splines method, I would suggest to adjust the smoothing factor s of scipy.interpolate.UnivariateSpline().

Another solution would be to smooth your function through convolution (say with a Gaussian).

The paper I linked to claims to prevent some of the artifacts that come up with the convolution approach (the spline approach might suffer from similar difficulties).

share|improve this answer
    
I've tried the numerical differentiation method: see the new attachment – Lucidnonsense Apr 7 '13 at 19:29
    
Line part2 = simps(u) is incorrect: part2 should instead be an array that contains the integral of u from 0 to each abscissa. Then you should try an exponentially varying smoothing coefficient in order to find the one that suits your needs best. If you really calculate the derivative by taking into account the step size in x, then I expect a good smoothing factor to be about 1e6, for a derivative that lies mostly between -1 and +1—while I may be wrong, you may want to try this value anyway, just in case my back-of-the-envelope calculation is correct. – EOL Apr 8 '13 at 4:50
    
Thanks, I will try that! – Lucidnonsense Apr 8 '13 at 11:10
    
PS: There is also no need to smooth your data beforehand, with the Numerical Differentiation of Noisy Data method. It looks like an interesting method. I am looking forward to your results! Good luck… – EOL Apr 8 '13 at 11:50
    
PPS: A good initial guess for the solution u might be the (noisy) derivative (instead of the function itself). In fact, the procedure described in the paper finds a derivative without smoothing the function. – EOL Apr 9 '13 at 9:51

I won't vouch for the mathematical validity of this; it looks like the paper from LANL that EOL cited would be worth looking into. Anyway, I’ve gotten decent results using SciPy’s splines’ built-in differentiation when using splev.

%matplotlib inline
from matplotlib import pyplot as plt
import numpy as np
from scipy.interpolate import splrep, splev

x = np.arange(0,2,0.008)
data = np.polynomial.polynomial.polyval(x,[0,2,1,-2,-3,2.6,-0.4])
noise = np.random.normal(0,0.1,250)
noisy_data = data + noise

f = splrep(x,noisy_data,k=5,s=3)
#plt.plot(x, data, label="raw data")
#plt.plot(x, noise, label="noise")
plt.plot(x, noisy_data, label="noisy data")
plt.plot(x, splev(x,f), label="fitted")
plt.plot(x, splev(x,f,der=1)/10, label="1st derivative")
#plt.plot(x, splev(x,f,der=2)/100, label="2nd derivative")
plt.hlines(0,0,2)
plt.legend(loc=0)
plt.show()

matplotlib output

share|improve this answer
    
Is it possible to use this method for non-evenly distributed data? Could I add my sets of measurements both for X and Y? – Spu Oct 20 '15 at 8:27
    
The documentation for the function used here (scipy.interpolate.splrep()) does not mention any restriction for non-evenly distributed data. Beyond just looking at the documentation, you can also certainly try by yourself by changing the value of x in the code. More generally, it is appreciated that you make some visible efforts at answering your own question, on Stack Overflow, so as to save others some time (and make them more likely to take the time to answer your question). – EOL Oct 20 '15 at 19:48
1  
@Spu, yes! I used splrep just two days ago to perform a cubic b-splines interpolatation of sample data acquired at non-uniform intervals so I could perform an FFT. – billyjmc Oct 21 '15 at 15:42

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