13

I've been looking for a way to do multiple Gaussian fitting to my data. Most of the examples I've found so far use a normal distribution to make random numbers. But I am interested in looking at the plot of my data and checking if there are 1-3 peaks.

I can do this for one peak, but I don't know how to do it for more.

For example, I have this data: http://www.filedropper.com/data_11

I have tried using lmfit, and of course scipy, but with no nice results.

Thanks for any help!

3
  • 1
    Your question is not entirely clear: do you want to fit a Gaussian to your (rather noisy) data? Do you want to find the location of the maxima? Is the data the sum of 1-3 Gaussians and you'd like to get the mean and standard variance of each?
    – Oliver W.
    Commented Nov 14, 2014 at 18:06
  • 1
    Hi! Thanks for the reply :) I want to fit one Gaussian for each peak.
    – astromath
    Commented Nov 15, 2014 at 17:52
  • " Is the data the sum of 1-3 Gaussians and you'd like to get the mean and standard variance of each?" exactly!
    – astromath
    Commented Nov 16, 2014 at 21:44

1 Answer 1

20

Simply make parameterized model functions of the sum of single Gaussians. Choose a good value for your initial guess (this is a really critical step) and then have scipy.optimize tweak those numbers a bit.

Here's how you might do it:

import numpy as np
import matplotlib.pyplot as plt
from scipy import optimize

data = np.genfromtxt('data.txt')
def gaussian(x, height, center, width, offset):
    return height*np.exp(-(x - center)**2/(2*width**2)) + offset
def three_gaussians(x, h1, c1, w1, h2, c2, w2, h3, c3, w3, offset):
    return (gaussian(x, h1, c1, w1, offset=0) +
        gaussian(x, h2, c2, w2, offset=0) +
        gaussian(x, h3, c3, w3, offset=0) + offset)

def two_gaussians(x, h1, c1, w1, h2, c2, w2, offset):
    return three_gaussians(x, h1, c1, w1, h2, c2, w2, 0,0,1, offset)

errfunc3 = lambda p, x, y: (three_gaussians(x, *p) - y)**2
errfunc2 = lambda p, x, y: (two_gaussians(x, *p) - y)**2

guess3 = [0.49, 0.55, 0.01, 0.6, 0.61, 0.01, 1, 0.64, 0.01, 0]  # I guess there are 3 peaks, 2 are clear, but between them there seems to be another one, based on the change in slope smoothness there
guess2 = [0.49, 0.55, 0.01, 1, 0.64, 0.01, 0]  # I removed the peak I'm not too sure about
optim3, success = optimize.leastsq(errfunc3, guess3[:], args=(data[:,0], data[:,1]))
optim2, success = optimize.leastsq(errfunc2, guess2[:], args=(data[:,0], data[:,1]))
optim3

plt.plot(data[:,0], data[:,1], lw=5, c='g', label='measurement')
plt.plot(data[:,0], three_gaussians(data[:,0], *optim3),
    lw=3, c='b', label='fit of 3 Gaussians')
plt.plot(data[:,0], two_gaussians(data[:,0], *optim2),
    lw=1, c='r', ls='--', label='fit of 2 Gaussians')
plt.legend(loc='best')
plt.savefig('result.png')

result of fitting

As you can see, there is almost no difference between these two fits (visually). So you can't know for sure if there were 3 Gaussians present in the source or only 2. However, if you had to make a guess, then check for the smallest residual:

err3 = np.sqrt(errfunc3(optim3, data[:,0], data[:,1])).sum()
err2 = np.sqrt(errfunc2(optim2, data[:,0], data[:,1])).sum()
print('Residual error when fitting 3 Gaussians: {}\n'
    'Residual error when fitting 2 Gaussians: {}'.format(err3, err2))
# Residual error when fitting 3 Gaussians: 3.52000910965
# Residual error when fitting 2 Gaussians: 3.82054499044

In this case, 3 Gaussians gives a better result, but I also made my initial guess fairly accurate.

9
  • Hello.Thank you very much for your answer.I had tried getting two separate Gaussians and then combining them,but I understand that was a wrong idea after I saw your solution.Could you please explain to me what the "center" and "offset" parameters are?Thank you very much for your help!
    – astromath
    Commented Nov 17, 2014 at 9:11
  • Those would be the mean of the Gaussian and a vertical offset that is given to it. Check my definition of Gaussian to verify ;-) Welcome to Stackoverflow. Don't forget to upvote or accept the answer if it helped you.
    – Oliver W.
    Commented Nov 17, 2014 at 11:46
  • Hi Oliver!Thank you again :)i do understand the script,but how did you guess'' the mean?I would use numpy for that ,but I feel that there is something more simple and faster that you did. Thank you once more :)
    – astromath
    Commented Nov 17, 2014 at 20:51
  • @astromath, my guesses for the mean were based merely on a visual inspection of the data. However, you could use one of the many peak detection algorithms to find two of the local maxima easily.
    – Oliver W.
    Commented Nov 17, 2014 at 21:25
  • OK thank you:)I have some scripts for that job.I will see what I can do.Again thank you very much Oliver :)
    – astromath
    Commented Nov 17, 2014 at 21:41

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.