I realize there are several articles that demonstrate how to fit a GMM to a 1D Gaussian with sklearn ( and , to name a few). However, in all of those cases, the data is present as single points where the distribution is Gaussian. In my case, I'm essentially have a frequency table (I'm working with spectroscopic data), where the distribution is Gaussian, but the individual points are unknown.
My distribution (i.e., the data I'm trying to fit) looks like this: 1D Gaussian Peak
I'd like to use GMM to deconvolve the 2 initial Gaussian distributions that make up this peak.
So far, I've tried the following (assume my data is a 200x2 array, with position in one column and AFU on the second) :
import numpy as np from sklearn import mixture import matplotlib.pyplot as plt def gengmm(nc=4, n_iter = 2): g = mixture.GMM(n_components=nc) # number of components g.init_params = "" # No initialization g.n_iter = n_iter # iteration of EM method return g
I tried to see if I could fit this peak to just a single Gaussian:
g = gengmm(1, 100) g.fit(data)
However, the mean and covariance I get don't define my data particularly well (notably, the mean for that Gaussian distribution is 127.5, which is not what is recovered with a 1 component GMM).
Is there an easier way to do this? (I realize I can just use a least-squares fit to recover the initial Gaussian, but again, I'm trying to ultimately use this to determine the two underlying Gaussians distributions that make up the final one.)