# Un-normalized Gaussian curve on histogram

I have data which is of the gaussian form when plotted as histogram. I want to plot a gaussian curve on top of the histogram to see how good the data is. I am using pyplot from matplotlib. Also I do NOT want to normalize the histogram. I can do the normed fit, but I am looking for an Un-normalized fit. Does anyone here know how to do it?

Thanks! Abhinav Kumar

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Does this example help? matplotlib.org/examples/api/histogram_demo.html –  DMH Jul 22 '13 at 3:21
No, its basically what I dont want. I dont want a normalized. –  Abhinav Kumar Jul 22 '13 at 3:53

As an example:

``````import pylab as py
import numpy as np
from scipy import optimize

# Generate a
y = np.random.standard_normal(10000)
data = py.hist(y, bins = 100)

# Equation for Gaussian
def f(x, a, b, c):
return a * py.exp(-(x - b)**2.0 / (2 * c**2))

# Generate data from bins as a set of points
x = [0.5 * (data[1][i] + data[1][i+1]) for i in xrange(len(data[1])-1)]
y = data[0]

popt, pcov = optimize.curve_fit(f, x, y)

x_fit = py.linspace(x[0], x[-1], 100)
y_fit = f(x_fit, *popt)

plot(x_fit, y_fit, lw=4, color="r")
``````

This will fit a Gaussian plot to a distribution, you should use the `pcov` to give a quantitative number for how good the fit is.

A better way to determine how well your data is Gaussian, or any distribution is the Pearson chi-squared test. It takes some practise to understand but it is a very powerful tool.

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Can we retrieve a, b and c for the fit you show above? I want to check with what I expect it to be. –  Abhinav Kumar Jul 30 '13 at 17:11
This is precisely `popt`. You will notice in getting the `y_fit` I have done `f(x_fit, *popt)` this is a trick to unpack the tuple of `popt` into the arguments of `f`. See the docs for more. –  Greg Jul 30 '13 at 22:04

An old post I know, but wanted to contribute my code for doing this, which simply does the 'fix by area' trick:

``````from scipy.stats import norm
from numpy import linspace
from pylab import plot,show,hist

def PlotHistNorm(data, log=False):
# distribution fitting
param = norm.fit(data)
mean = param[0]
sd = param[1]

#Set large limits
xlims = [-6*sd+mean, 6*sd+mean]

#Plot histogram
histdata = hist(data,bins=12,alpha=.3,log=log)

#Generate X points
x = linspace(xlims[0],xlims[1],500)

#Get Y points via Normal PDF with fitted parameters
pdf_fitted = norm.pdf(x,loc=mean,scale=sd)

#Get histogram data, in this case bin edges
xh = [0.5 * (histdata[1][r] + histdata[1][r+1]) for r in xrange(len(histdata[1])-1)]

#Get bin width from this
binwidth = (max(xh) - min(xh)) / len(histdata[1])

#Scale the fitted PDF by area of the histogram
pdf_fitted = pdf_fitted * (len(data) * binwidth)

#Plot PDF
plot(x,pdf_fitted,'r-')
``````
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Another way of doing this is to find the normalized fit and multiply the normal distribution with (bin_width*total length of data)

this will un-normalize your normal distribution

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