# cumulative distribution plots python

I am doing a project using python where I have two arrays of data. Let's call them pc and pnc. I am required to plot a cumulative distribution of both of these on the same graph. For pc it is supposed to be a less than plot i.e. at (x,y), y points in pc must have value less than x. For pnc it is to be a more than plot i.e. at (x,y), y points in pnc must have value more than x.

I have tried using histogram function - pyplot.hist. Is there a better and easier way to do what i want? Also, it has to be plotted on a logarithmic scale on the x-axis.

• It'd help if you showed your attempts so far - sample input data, desired output etc... Otherwise this reads as a "show me the code" question – Jon Clements Mar 14 '13 at 11:49
• To extend Jon's comment, people are much happier to help you fix the code you have rather than to generate code from scratch. No matter how buggy and non-functional your code is, show it and explain what a) you expect it to do and b) what it is currently doing. – tacaswell Mar 14 '13 at 13:14

You were close. You should not use plt.hist as numpy.histogram, that gives you both the values and the bins, than you can plot the cumulative with ease:

import numpy as np
import matplotlib.pyplot as plt

# some fake data
data = np.random.randn(1000)
# evaluate the histogram
values, base = np.histogram(data, bins=40)
#evaluate the cumulative
cumulative = np.cumsum(values)
# plot the cumulative function
plt.plot(base[:-1], cumulative, c='blue')
#plot the survival function
plt.plot(base[:-1], len(data)-cumulative, c='green')

plt.show()


• FYI, you forgot to include the np before the cumsum as your np.histogram command implies is needed. – ehsteve Dec 19 '13 at 18:27
• @ehsteve fixed answer. – Gabriel Feb 5 '14 at 18:26
• Using a histogram is both unnecessarily heavy and imprecise. – Eric O Lebigot Mar 23 '14 at 8:56
• @EOL but necessary for large arrays else you'll run out of memory. – aaren Mar 26 '14 at 10:54
• Indeed, but I take that this is not the particular case of the question, which is more about how to get the cumulative distribution than to do it in the case of a large array, and approximately. – Eric O Lebigot Mar 26 '14 at 13:51

Using histograms is really unnecessarily heavy and imprecise (the binning makes the data fuzzy): you can just sort all the x values: the index of each value is the number of values that are smaller. This shorter and simpler solution looks like this:

import numpy as np
import matplotlib.pyplot as plt

# Some fake data:
data = np.random.randn(1000)

sorted_data = np.sort(data)  # Or data.sort(), if data can be modified

# Cumulative counts:
plt.step(sorted_data, np.arange(sorted_data.size))  # From 0 to the number of data points-1
plt.step(sorted_data[::-1], np.arange(sorted_data.size))  # From the number of data points-1 to 0

plt.show()


Furthermore, a more appropriate plot style is indeed plt.step() instead of plt.plot(), since the data is in discrete locations.

The result is:

You can see that it is more ragged than the output of EnricoGiampieri's answer, but this one is the real histogram (instead of being an approximate, fuzzier version of it).

PS: As SebastianRaschka noted, the very last point should ideally show the total count (instead of the total count-1). This can be achieved with:

plt.step(np.concatenate([sorted_data, sorted_data[[-1]]]),
np.arange(sorted_data.size+1))
plt.step(np.concatenate([sorted_data[::-1], sorted_data[[0]]]),
np.arange(sorted_data.size+1))


There are so many points in data that the effect is not visible without a zoom, but the very last point at the total count does matter when the data contains only a few points.

• However for large arrays you want to go with the histogram approach as it doesn't require nearly as much memory. The plt.step method gives me a memory error with my 60 million element array. – aaren Mar 26 '14 at 10:52
• Agreed. I'm not sure whether the problem lies with plt.step or with the fact that this exact method uses maybe 3 times the memory of the array, or both… – Eric O Lebigot Mar 26 '14 at 14:05
• I agree: plt.step is probably the more appropriate approach for plotting "counts". One question: wouldn't you have to use plt.step(sorted_data, np.arange(1, data.size+1)) to get the correct counts? – user2489252 Jul 2 '14 at 20:53
• @SebastianRaschka: Good point. You are correct. A perfect solution would add this last point. This can be done by duplicating the last abscissa and adding the total count (5) at the last ordinate. I updated the answer, thanks! – Eric O Lebigot Jul 4 '14 at 3:19
• Thanks for the update. Your workaround looks definitely nicer than mine :) – user2489252 Jul 4 '14 at 6:08

After conclusive discussion with @EOL, I wanted to post my solution (upper left) using a random Gaussian sample as a summary:

import numpy as np
import matplotlib.pyplot as plt
from math import ceil, floor, sqrt

def pdf(x, mu=0, sigma=1):
"""
Calculates the normal distribution's probability density
function (PDF).

"""
term1 = 1.0 / ( sqrt(2*np.pi) * sigma )
term2 = np.exp( -0.5 * ( (x-mu)/sigma )**2 )
return term1 * term2

# Drawing sample date poi
##################################################

# Random Gaussian data (mean=0, stdev=5)
data1 = np.random.normal(loc=0, scale=5.0, size=30)
data2 = np.random.normal(loc=2, scale=7.0, size=30)
data1.sort(), data2.sort()

min_val = floor(min(data1+data2))
max_val = ceil(max(data1+data2))

##################################################

fig = plt.gcf()
fig.set_size_inches(12,11)

# Cumulative distributions, stepwise:
plt.subplot(2,2,1)
plt.step(np.concatenate([data1, data1[[-1]]]), np.arange(data1.size+1), label='$\mu=0, \sigma=5$')
plt.step(np.concatenate([data2, data2[[-1]]]), np.arange(data2.size+1), label='$\mu=2, \sigma=7$')

plt.title('30 samples from a random Gaussian distribution (cumulative)')
plt.ylabel('Count')
plt.xlabel('X-value')
plt.legend(loc='upper left')
plt.xlim([min_val, max_val])
plt.ylim([0, data1.size+1])
plt.grid()

# Cumulative distributions, smooth:
plt.subplot(2,2,2)

plt.plot(np.concatenate([data1, data1[[-1]]]), np.arange(data1.size+1), label='$\mu=0, \sigma=5$')
plt.plot(np.concatenate([data2, data2[[-1]]]), np.arange(data2.size+1), label='$\mu=2, \sigma=7$')

plt.title('30 samples from a random Gaussian (cumulative)')
plt.ylabel('Count')
plt.xlabel('X-value')
plt.legend(loc='upper left')
plt.xlim([min_val, max_val])
plt.ylim([0, data1.size+1])
plt.grid()

# Probability densities of the sample points function
plt.subplot(2,2,3)

pdf1 = pdf(data1, mu=0, sigma=5)
pdf2 = pdf(data2, mu=2, sigma=7)
plt.plot(data1, pdf1, label='$\mu=0, \sigma=5$')
plt.plot(data2, pdf2, label='$\mu=2, \sigma=7$')

plt.title('30 samples from a random Gaussian')
plt.legend(loc='upper left')
plt.xlabel('X-value')
plt.ylabel('probability density')
plt.xlim([min_val, max_val])
plt.grid()

# Probability density function
plt.subplot(2,2,4)

x = np.arange(min_val, max_val, 0.05)

pdf1 = pdf(x, mu=0, sigma=5)
pdf2 = pdf(x, mu=2, sigma=7)
plt.plot(x, pdf1, label='$\mu=0, \sigma=5$')
plt.plot(x, pdf2, label='$\mu=2, \sigma=7$')

plt.title('PDFs of Gaussian distributions')
plt.legend(loc='upper left')
plt.xlabel('X-value')
plt.ylabel('probability density')
plt.xlim([min_val, max_val])
plt.grid()

plt.show()


In order to add my own contribution to the community, here I share my function for plotting histograms. This is how I understood the question, plotting the histogram and the cumulative histograme at the same time :

def hist(data, bins, title, labels, range = None):
fig = plt.figure(figsize=(15, 8))
ax = plt.axes()
plt.ylabel("Proportion")
values, base, _ = plt.hist( data  , bins = bins, normed=True, alpha = 0.5, color = "green", range = range, label = "Histogram")
ax_bis = ax.twinx()
values = np.append(values,0)
ax_bis.plot( base, np.cumsum(values)/ np.cumsum(values)[-1], color='darkorange', marker='o', linestyle='-', markersize = 1, label = "Cumulative Histogram" )
plt.xlabel(labels)
plt.ylabel("Proportion")
plt.title(title)
ax_bis.legend();
ax.legend();
plt.show()
return


if anyone wonders how it looks like, please take a look (with seaborn activated):

Also, concerning the double grid (the white lines), I always used to struggle to have nice double grid. Here is an interesting way to circumvent the problem: How to put grid lines from the secondary axis behind the primary plot?

• if you expect negative values in your array, you probably want to take the absolute... otherwise the cumulative histogram will look off – dv3 May 18 '20 at 7:51

The simples way to generate this graph is with seaborn:

import seaborn as sns

sns.ecdfplot()


Here is the documentation: