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How can I plot the empirical CDF of an array of numbers in matplotlib in Python? I'm looking for the cdf analog of pylab's "hist" function.

One thing I can think of is:

from scipy.stats import cumfreq
a = array([...]) # my array of numbers
num_bins =  20
b = cumfreq(a, num_bins)
plt.plot(b)

Is that correct though? Is there an easier/better way?

thanks.

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7 Answers 7

up vote 6 down vote accepted

That looks to be (almost) exactly what you want. Two things:

First, the results are a tuple of four items. The third is the size of the bins. The second is the starting point of the smallest bin. The first is the number of points in the in or below each bin. (The last is the number of points outside the limits, but since you haven't set any, all points will be binned.)

Second, you'll want to rescale the results so the final value is 1, to follow the usual conventions of a CDF, but otherwise it's right.

Here's what it does under the hood:

def cumfreq(a, numbins=10, defaultreallimits=None):
    # docstring omitted
    h,l,b,e = histogram(a,numbins,defaultreallimits)
    cumhist = np.cumsum(h*1, axis=0)
    return cumhist,l,b,e

It does the histogramming, then produces a cumulative sum of the counts in each bin. So the ith value of the result is the number of array values less than or equal to the the maximum of the ith bin. So, the final value is just the size of the initial array.

Finally, to plot it, you'll need to use the initial value of the bin, and the bin size to determine what x-axis values you'll need.

Another option is to use numpy.histogram which can do the normalization and returns the bin edges. You'll need to do the cumulative sum of the resulting counts yourself.

a = array([...]) # your array of numbers
num_bins = 20
counts, bin_edges = numpy.histogram(a, bins=num_bins, normed=True)
cdf = numpy.cumsum(counts)
pylab.plot(bin_edges[1:], cdf)

(bin_edges[1:] is the upper edge of each bin.)

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5  
Just a quick note: this code doesn't actually give you the Empirical CDF (a step function increasing by 1/n at each of n datapoints). Instead, this code gives an estimate of the CDF based on a histogram-based estimate of the PDF. This histogram-based estimate can be manipulated/biased by careful/improper selection of the bins, so it's not as good a characterization of the true CDF as the actual ECDF. –  David B. May 23 '12 at 2:02
    
I also dislike the point that this imposes binning; see Dave's short answer, which simply uses numpy.sort for plotting the CDF without binning. –  hans_meine Feb 20 at 9:58

You can use the ECDF function from the scikits.statsmodels library:

import numpy as np
import scikits.statsmodels as sm
import matplotlib.pyplot as plt

sample = np.random.uniform(0, 1, 50)
ecdf = sm.tools.ECDF(sample)

x = np.linspace(min(sample), max(sample))
y = ecdf(x)
plt.step(x, y)

With version 0.4 scicits.statsmodels was renamed to statsmodels. ECDF is now located in the distributions module (while statsmodels.tools.tools.ECDF is depreciated).

import numpy as np
import statsmodels.api as sm # recommended import according to the docs
import matplotlib.pyplot as plt

sample = np.random.uniform(0, 1, 50)
ecdf = sm.distributions.ECDF(sample)

x = np.linspace(min(sample), max(sample))
y = ecdf(x)
plt.step(x, y)
plt.show()
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2  
@bmu (and @Luca): awesome; thank you for kindly making the code current with the current statsmodel! –  ars Jun 7 '12 at 4:15

I almost always do:

# a is the data array
sorted=np.sort( a )
yvals=np.arange(len(sorted))/float(len(sorted))
plt.plot( sorted, yvals )

Which works for me even if there are >O(1e6) data values. If you really need to down sample I'd set

sorted=np.sort(a)[::down_sampling_step]

Edit to respond to comment/edit on why I use the yvals as defined above. The following are some technical details.

The empirical CDF is usually formally defined as

CDF(x) = "number of samples <= x"/"number of samples"

we are evaluating this empirical CDF at the sample points this would yield yvals = [1/N, 2/N ... 1]. This estimator is an unbiased estimator that will converge to the true CDF in the limit of infinite samples Wikipedia ref..

I tend to use yvals = [0, 1/N, 2/N ... (N-1)/N] since (a) it is easier to code/more idomatic, (b) but is still formally justified since one can always exchange CDF(x) with 1-CDF(x). In some particular cases it is useful to define

yvals=(arange(len(sorted))+0.5)/len(sorted)

which is intermediate between these two conventions. Which, in effect, says "there is a 1/(2N) chance of a value less than the lowest one I've seen in my sample, and a 1/(2N) chance of a value greater than the largest one I've seen so far.

However, for large samples, and reasonable distributions, the convention given in the main body of the answer is easy to write, is an unbiased estimator of the true CDF, and works with the downsampling methodology.

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This answer should receive more upvotes, since it is the only one so far that does not impose binning. I only simplified the code a little bit, using linspace. –  hans_meine Feb 20 at 9:56
    
@hans_meine your edit, i.e. yvals=linspace(0,1,len(sorted)), produces yvals that are not an unbiased estimator of the true CDF. –  Dave Feb 20 at 13:03
    
Then, we should've used linspace with endpoint = False, right? –  hans_meine Feb 21 at 11:49
    
Yes, I believe that that would work. –  Dave Feb 21 at 14:23

Have you tried the cumulative=True argument to pyplot.hist?

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Very good remark. Still, that imposes binning; see Dave's answer using np.sort. –  hans_meine Feb 20 at 9:57

What do you want to do with the CDF ? To plot it, that's a start. You could try a few different values, like this:

from __future__ import division
import numpy as np
from scipy.stats import cumfreq
import pylab as plt

hi = 100.
a = np.arange(hi) ** 2
for nbins in ( 2, 20, 100 ):
    cf = cumfreq(a, nbins)  # bin values, lowerlimit, binsize, extrapoints
    w = hi / nbins
    x = np.linspace( w/2, hi - w/2, nbins )  # care
    # print x, cf
    plt.plot( x, cf[0], label=str(nbins) )

plt.legend()
plt.show()

Histogram lists various rules for the number of bins, e.g. num_bins ~ sqrt( len(a) ).

(Fine print: two quite different things are going on here,

  • binning / histogramming the raw data
  • plot interpolates a smooth curve through the say 20 binned values.

Either of these can go way off on data that's "clumpy" or has long tails, even for 1d data -- 2d, 3d data gets increasingly difficult.
See also Density_estimation and using scipy gaussian kernel density estimation ).

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I have a trivial addition to AFoglia's method, to normalize the CDF

n_counts,bin_edges = np.histogram(myarray,bins=11,normed=True) 
cdf = np.cumsum(n_counts)  # cdf not normalized, despite above
scale = 1.0/cdf[-1]
ncdf = scale * cdf

Normalizing the histo makes its integral unity, which means the cdf will not be normalized. You've got to scale it yourself.

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If you want to display the actual true ECDF (which as David B noted is a step function that increases 1/n at each of n datapoints), my suggestion is to write code to generate two "plot" points for each datapoint:

a = array([...]) # your array of numbers
sorted=np.sort(a)
x2 = []
y2 = []
y = 0
for x in sorted: 
    x2.extend([x,x])
    y2.append(y)
    y += 1.0 / len(a)
    y2.append(y)
plt.plot(x2,y2)

This way you will get a plot with the n steps that are characteristic of an ECDF, which is nice especially for data sets that are small enough for the steps to be visible. Also, there is no no need to do any binning with histograms (which risk introducing bias to the drawn ECDF).

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