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Python has a number of ways to generate different distributions of random numbers, see the documentation for the random module. Unfortunately they aren't terribly understandable without the appropriate math background, especially considering the required parameters.

I'd like to know if any of those methods are capable of producing random numbers with a distribution that obeys Benford's Law, and what parameter values are appropriate. Namely for a population of integers, those integers should start with a '1' about 30% of the time, '2' about 18% of the time, etc.

Using Jan Dvorak's answer I put together the following code, and it appears to work perfectly.

def benfords_range_gen(stop, n):
    """ A generator that returns n random integers
    between 1 and stop-1 and whose distribution
    meets Benford's Law i.e. is logarithmic.
    multiplier = math.log(stop)
    for i in range(n):
        yield int(math.exp(multiplier * random.random()))

>>> from collections import Counter
>>> Counter(str(i)[0] for i in benfords_range_gen(10000, 1000000))
Counter({'1': 300696, '2': 176142, '3': 124577, '4': 96756, '5': 79260, '6': 67413, '7': 58052, '8': 51308, '9': 45796})
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Isn't this the same as picking a random number uniformly between log(min) and log(max) and outputting 10 raised to that number? – David Schwartz Jan 28 '13 at 6:21
Given what Benford's law is, try floor(10^random()) – Jan Dvorak Jan 28 '13 at 6:24
@JanDvorak: Yep. For 1,000,000 trials, I get: {1: 0.301143, 2: 0.175899, 3: 0.125316, 4: 0.097045, 5: 0.079359, 6: 0.066662, 7: 0.057795, 8: 0.050963, 9: 0.045818}. In Python, it'd be int(10**random.random()) – Blender Jan 28 '13 at 6:27
@Blender so, it's correct it seems – Jan Dvorak Jan 28 '13 at 6:27
@JanDvorak, if you're serious then propose it as an answer. I like the fact that it doesn't depend on any of the fancy distribution models, just a simple transformation of the usual equal probabilities. – Mark Ransom Jan 28 '13 at 6:33
up vote 20 down vote accepted

Benford's law describes the distribution of the first digits of a set of numbers if the numbers are chosen from a wide range on the logarithmic scale. If you prepare a log-uniform distribution over one decade, it will respect the law as well. 10^[0,1) will produce that distribution.

This will produce the desired distribution: math.floor(10**random.random())

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Just playing around.

A much more inefficient, but perhaps more visible implementation for those, like myself, who are not so math inclined...

An easy way to create any desired distribution is to fill a list with the desired percentages of an item, and then use random.choice(<list>), since this returns a uniform selection of items in the list.

import random
probs = [30.1, 17.6, 12.5, 9.7, 7.9, 6.7, 5.8, 5.1, 4.6]
nums = [1, 2, 3, 4, 5, 6, 7, 8, 9]
population = sum([[n] * int(p * 10) for n, p in zip(nums, probs)], [])

max_value = 100
min_value = 1
result_pop = []
target_pop_size = 1000
while len(result_pop) < target_pop_size:
    s = str(random.choice(population))
    while True:
        r = random.randint(min_value, max_value)
        if str(r).startswith(s):
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