# python: plotting a histogram with a function line on top

I'm trying to do a little bit of distribution plotting and fitting in Python using SciPy for stats and matplotlib for the plotting. I'm having good luck with some things like creating a histogram:

``````seed(2)
alpha=5
loc=100
beta=22
data=ss.gamma.rvs(alpha,loc=loc,scale=beta,size=5000)
myHist = hist(data, 100, normed=True)
``````

Brilliant!

I can even take the same gamma parameters and plot the line function of the probability distribution function (after some googling):

``````rv = ss.gamma(5,100,22)
x = np.linspace(0,600)
h = plt.plot(x, rv.pdf(x))
``````

How would I go about plotting the histogram `myHist` with the PDF line `h` superimposed on top of the histogram? I'm hoping this is trivial, but I have been unable to figure it out.

• You're probably plotting the histogram and the plot in different figures. If you simply call the hist and plot function on the same figure then the 2 should be superimposed – Dhara Jul 3 '12 at 17:30
• @Dhara that was exactly it. I'm using ipython notebook and doing exactly that. – JD Long Jul 3 '12 at 21:08

just put both pieces together.

``````import scipy.stats as ss
import numpy as np
import matplotlib.pyplot as plt
alpha, loc, beta=5, 100, 22
data=ss.gamma.rvs(alpha,loc=loc,scale=beta,size=5000)
myHist = plt.hist(data, 100, normed=True)
rv = ss.gamma(alpha,loc,beta)
x = np.linspace(0,600)
h = plt.plot(x, rv.pdf(x), lw=2)
plt.show()
``````

to make sure you get what you want in any specific plot instance, try to create a `figure` object first

``````import scipy.stats as ss
import numpy as np
import matplotlib.pyplot as plt
# setting up the axes
fig = plt.figure(figsize=(8,8))
# now plot
alpha, loc, beta=5, 100, 22
data=ss.gamma.rvs(alpha,loc=loc,scale=beta,size=5000)
myHist = ax.hist(data, 100, normed=True)
rv = ss.gamma(alpha,loc,beta)
x = np.linspace(0,600)
h = ax.plot(x, rv.pdf(x), lw=2)
# show
plt.show()
``````
• the problem I was running into was that I am using ipython notebook so I'd run one plot, it would plot interactively then I would do some stuff and plot another, and it would end up in a new plot. Thanks for helping me figure this out! – JD Long Jul 3 '12 at 21:08

One could be interested in plotting the distibution function of any histogram. This can be done using `seaborn kde` function

``````import numpy as np # for random data
import pandas as pd  # for convinience
import matplotlib.pyplot as plt  # for graphics
import seaborn as sns  # for nicer graphics

v1 = pd.Series(np.random.normal(0,10,1000), name='v1')
v2 = pd.Series(2*v1 + np.random.normal(60,15,1000), name='v2')

# plot a kernel density estimation over a stacked barchart
plt.figure()
plt.hist([v1, v2], histtype='barstacked', normed=True);
v3 = np.concatenate((v1,v2))
sns.kdeplot(v3);
plt.show()
``````

from a coursera course on data visualization with python

Expanding on Malik's answer, and trying to stick with vanilla NumPy, SciPy and Matplotlib. I've pulled in Seaborn, but it's only used to provide nicer defaults and small visual tweaks:

``````import numpy as np
import scipy.stats as sps
import matplotlib.pyplot as plt

import seaborn as sns
sns.set(style='ticks')

# parameterise our distributions
d1 = sps.norm(0, 10)
d2 = sps.norm(60, 15)

# sample values from above distributions
y1 = d1.rvs(300)
y2 = d2.rvs(200)
# combine mixture
ys = np.concatenate([y1, y2])

# create new figure with size given explicitly
plt.figure(figsize=(10, 6))

# add histogram showing individual components
plt.hist([y1, y2], 31, histtype='barstacked', density=True, alpha=0.4, edgecolor='none')

# get X limits and fix them
mn, mx = plt.xlim()
plt.xlim(mn, mx)

# add our distributions to figure
x = np.linspace(mn, mx, 301)
plt.plot(x, d1.pdf(x) * (len(y1) / len(ys)), color='C0', ls='--', label='d1')
plt.plot(x, d2.pdf(x) * (len(y2) / len(ys)), color='C1', ls='--', label='d2')

# estimate Kernel Density and plot
kde = sps.gaussian_kde(ys)
plt.plot(x, kde.pdf(x), label='KDE')

# finish up
plt.legend()
plt.ylabel('Probability density')
sns.despine()
``````

gives us the following plot:

I've tried to stick with a minimal feature set while producing relatively nice output, notably using SciPy to estimate the KDE is very easy.