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Suppose I create a histogram using scipy/numpy, so I have two arrays: one for the bin counts, and one for the bin edges. If I use the histogram to represent a probability distribution function, how can I efficiently generate random numbers from that distribution?

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Can you clarify this some? Do you want a certain number of random numbers per histogram interval or do you want random numbers based off a weight function that is based off a polynomial interpolation of the histogram values? –  Ophion Jul 23 '13 at 22:10
    
Returning the bin center is fine. Interpolation or fitting isn't necessary. –  xvtk Jul 23 '13 at 22:45

3 Answers 3

up vote 11 down vote accepted

It's probably what np.random.choice does in @Ophion's answer, but you can construct a normalized cumulative density function, then choose based on a uniform random number:

from __future__ import division
import numpy as np
import matplotlib.pyplot as plt

data = np.random.normal(size=1000)
hist, bins = np.histogram(data, bins=50)

bin_midpoints = bins[:-1] + np.diff(bins)/2
cdf = np.cumsum(hist)
cdf = cdf / cdf[-1]
values = np.random.rand(10000)
value_bins = np.searchsorted(cdf, values)
random_from_cdf = bin_midpoints[value_bins]

plt.subplot(121)
plt.hist(data, 50)
plt.subplot(122)
plt.hist(random_from_cdf, 50)
plt.show()

enter image description here


A 2D case can be done as follows:

data = np.column_stack((np.random.normal(scale=10, size=1000),
                        np.random.normal(scale=20, size=1000)))
x, y = data.T                        
hist, x_bins, y_bins = np.histogram2d(x, y, bins=(50, 50))
x_bin_midpoints = x_bins[:-1] + np.diff(x_bins)/2
y_bin_midpoints = y_bins[:-1] + np.diff(y_bins)/2
cdf = np.cumsum(hist.ravel())
cdf = cdf / cdf[-1]

values = np.random.rand(10000)
value_bins = np.searchsorted(cdf, values)
x_idx, y_idx = np.unravel_index(value_bins,
                                (len(x_bin_midpoints),
                                 len(y_bin_midpoints)))
random_from_cdf = np.column_stack((x_bin_midpoints[x_idx],
                                   y_bin_midpoints[y_idx]))
new_x, new_y = random_from_cdf.T

plt.subplot(121, aspect='equal')
plt.hist2d(x, y, bins=(50, 50))
plt.subplot(122, aspect='equal')
plt.hist2d(new_x, new_y, bins=(50, 50))
plt.show()

enter image description here

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Yes, this will certainly work! Can it be generalized to higher dimensional histograms? –  xvtk Jul 23 '13 at 22:44
1  
@xvtk I've edited my answer with a 2D histogram. You should be able to apply the same scheme for higher dimensional distributions. –  Jaime Jul 24 '13 at 14:52
1  
If you are using python 2, you need to add the "from future import division" import, or change the cdf normalization line to cdf = cdf / float(cdf[-1]) –  Noam Peled Apr 7 at 9:22
1  
You are absolutely right, Noam. It has become so second nature to me to have that be the first line of every Python I write, that i keep forgetting it isn't standard behavior. Have edited my answer. –  Jaime Apr 7 at 11:32
    
I've also added to your code (as a new answer) an example how to generate random numbers from the kde (kernel density estimation) of the histogram, which captures better the "generator mechanism" of the histogram. –  Noam Peled Apr 8 at 13:34

Perhaps something like this. Uses the count of the histogram as a weight and chooses values of indices based on this weight.

import numpy as np

initial=np.random.rand(1000)
values,indices=np.histogram(initial,bins=20)
values=values.astype(np.float32)
weights=values/np.sum(values)

#Below, 5 is the dimension of the returned array.
new_random=np.random.choice(indices[1:],5,p=weights)
print new_random

#[ 0.55141614  0.30226256  0.25243184  0.90023117  0.55141614]
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@Jaime solution is great, but you should consider using the kde (kernel density estimation) of the histogram. A great explanation why it's problematic to do statistics over histogram, and why you should use kde instead can be found here

I edited @Jaime's code to show how to use kde from scipy. It looks almost the same, but captures better the histogram generator.

from __future__ import division
import numpy as np
import matplotlib.pyplot as plt
from scipy.stats import gaussian_kde

def run():
    data = np.random.normal(size=1000)
    hist, bins = np.histogram(data, bins=50)

    x_grid = np.linspace(min(data), max(data), 1000)
    kdepdf = kde(data, x_grid, bandwidth=0.1)
    random_from_kde = generate_rand_from_pdf(kdepdf, x_grid)

    bin_midpoints = bins[:-1] + np.diff(bins) / 2
    random_from_cdf = generate_rand_from_pdf(hist, bin_midpoints)

    plt.subplot(121)
    plt.hist(data, 50, normed=True, alpha=0.5, label='hist')
    plt.plot(x_grid, kdepdf, color='r', alpha=0.5, lw=3, label='kde')
    plt.legend()
    plt.subplot(122)
    plt.hist(random_from_cdf, 50, alpha=0.5, label='from hist')
    plt.hist(random_from_kde, 50, alpha=0.5, label='from kde')
    plt.legend()
    plt.show()


def kde(x, x_grid, bandwidth=0.2, **kwargs):
    """Kernel Density Estimation with Scipy"""
    kde = gaussian_kde(x, bw_method=bandwidth / x.std(ddof=1), **kwargs)
    return kde.evaluate(x_grid)


def generate_rand_from_pdf(pdf, x_grid):
    cdf = np.cumsum(pdf)
    cdf = cdf / cdf[-1]
    values = np.random.rand(1000)
    value_bins = np.searchsorted(cdf, values)
    random_from_cdf = x_grid[value_bins]
    return random_from_cdf

enter image description here

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