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I would like to generate a list of n strictly positive values such that the list has a predetermined mean and standard deviation (can be close/not exact). I was using the uniform distribution's equations for expectation and variance and solving for 'a' and 'b', but the system of equations (for the specific mean and std. dev. I wanted) had no solutions for a, b >= 0. I was wondering if there was a plug-and-chug method to do this in any programming language, but hopefully in Python. Thanks!

Ex: generate list of 84 positive values with mean ~= 60/84 = 0.71, std.dev. ~= 1.7

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In response to deleted comment suggesting I use normal distribution with specified mean/std dev: Yes, and I have tried that, but using the example mean and std dev, a normal dist is bound to generate some negative values. my goal is to have no negative values in my list. –  sgchako Apr 18 at 18:00
If maintaining the mean and standard deviation is important, I suspect that you are making some assumption about the distribution of those values. Aside from being strictly positive, do you have other requirements, or can the probability function totally arbitrary? –  Taro Sato Apr 18 at 18:14
@TaroSato the fn can be totally arbitrary. The only thing I am concerned with are the mentioned constraints. –  sgchako Apr 18 at 18:18
Also, do you need to ensure that a set of values having its mean and standard deviation "very close" to those predefined? I ask because if you draw a set of values from some probability distribution, with a small sample your mean and standard deviation computed from that sample can be quite a bit different from those of the parent population. In practice, we don't do this kind of thing (we only make an assumption about the probability distribution), but it is not clear from the question what the goal really is. –  Taro Sato Apr 18 at 18:18
Yes, that is another problem I ran into with an earlier approach I tried. Sample mean and variance being very close is okay, but far is not (even if the distribution does have the assumed mean and std dev). What is really important is the sample mean/sample variance. I really could not care what the distribution looks like. Hopefully I've made the problem clear at this point. let me know if i can further clarify –  sgchako Apr 18 at 18:20

4 Answers 4

up vote 1 down vote accepted


Use NumPy to generate samples from a gamma distribution with scale parameter theta = variance / mean and shape parameter k = mean / theta.


>> import numpy

>> mu = 0.71
>> var = 1.7**2 
>> theta = var / mean 
>> k = mu / theta

>> samples = numpy.random.gamma(k, theta, 1000)

>> numpy.mean(samples)

>> numpy.std(samples) 


The constraints you provide underspecify the distribution. Some of the comments you made in response to another answer would have been helpful as part of the question. In particular, it seems as if you might be trying to model arrivals in a queue, e.g. a Poisson process. As you pointed out, the mean and variance of a Poisson distribution are the same, the lambda parameter. However, consider the lambda itself as a random variable. The conjugate prior to the Poisson distribution the Gamma distribution.

With shape parameter k > 0 and scale parameter theta > 0, the gamma distribution has mean = k * theta and variance = k * theta^2. Therefore, theta is variance / mean > 0 and k is mean / theta > 0. Since the gamma distribution has positive support, this conveniently answers your question.

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This worked very well. I added an if else block to resample if the resulting list did not have mean/std.dev within a 5% margin of error of my desired mean/std.dev. Thanks! –  sgchako Apr 21 at 3:51

Assume a (continuous) uniform distribution with the minimum a and the maximum b. Such distribution has the mean and variance:

mean = (a + b) / 2

var = (b - a)^2 / 12

where the standard deviation is simply sqrt(var). Given the mean and variance (and therefore standard deviation), the set of equations can be solved for a and b:

a = mean - sqrt(3 * var)

b = mean + sqrt(3 * var)

For creating a list having this set of mean and variance, you simply want to generate n equally separated points within [a, b]. A Python code snippet follows:

#!/usr/bin/env python2.7
from math import sqrt

def uniform(mean, std, n):
    a = mean - sqrt(3.) * std
    b = mean + sqrt(3.) * std
    xs = [(b - a) * (i / (n - 1.)) + a for i in range(n)]
    return xs

for target_mean, target_std, n in [(10, 1, 100),
                                   (0.71, 1.7, 84)]:
    xs = uniform(target_mean, target_std, n)
    print xs

    mean = 1. * sum(xs) / n
    var = sum([(x - mean)**2 / n for x in xs])

    print 'mean: {} ({})'.format(mean, target_mean)
    print 'std: {} ({})'.format(sqrt(var), target_std)

    if not min(xs) > 0:
        print 'WARNING: but this is not strictly positive'


Note that a certain combination of mean and variance yields negative values, so you need to conditionally exclude them. You can alternatively choose some other probability distribution function that only draws strictly positive numbers. How easy it is to relate the mean and variance to the parameters that characterize the distribution really depends. I arbitrarily picked uniform because it is simple.

However, I find the premise of the original question a bit contrived, so depending on the problem doing this sort of thing might not actually be desirable.

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Thanks Taro Sato for your work! Your comment about certain combinations of mean and variance yielding negative values is something I ran into earlier, and described in my original post. I guess there is no way to do this for certain predetermined means/variances. –  sgchako Apr 18 at 19:27
With any distribution you must assume, there are certain restrictions in the way mean and standard deviation can be chosen so that you cannot choose everything freely, arbitrary and hope the values drawn are strictly positive. With my example, you just need to choose mean and standard deviation so that the minimum b are positive. You could do something similar with different distribution, but then some other restrictions are imposed (like with Poisson, the mean and variance is related one-to-one). You simply cannot pick everything arbitrarily. Otherwise you need something by brute force. –  Taro Sato Apr 18 at 19:35
Are there any ways to implement a brute force method (like plug-and-chug) in Python? Something to solve a system like sum a_i = x, sum (a_i)^2 = y, with a_i >= 0 & x,y predetermined? It that were possible with some plug-and-chug solution, I could generate a suitable list that way. Just never implemented something like that before, don't know how to tell the computer to try numbers until it gets something that works. –  sgchako Apr 18 at 19:42
Not that I know that's efficient enough or really not contrived. I just don't find the premise of the question making sense (which is the reason why I think it is not a proper approach to the question you are really trying to solve). The mean and standard deviation is a way of characterizing probability distribution, so if you are saying the distribution really does not matter, then I have to question why you care so much about the mean and standard deviation to begin with (because without a distribution, they are not very meaningful for interpretation). –  Taro Sato Apr 18 at 19:51
The problem I am tackling is basically data justification (not malicious, i promise :) ). For instance, say you were observing a queue at a pizza parlor and measuring arrival times of customers. You would get a list of n entry times (each of course being positive). The list would have a mean and a standard deviation. The distribution of arrival times at this pizza shop is unknown, of course (so does not really matter). What I am trying to do is, given some predetermined mean and standard deviation, generate a list of arrival times that will result in said mean & std. dev. –  sgchako Apr 18 at 20:13

Saying a "distribution is unknown" is different than "does not really matter" (both statements are in the same comment to Taro Sato’s answer). One way to get a desired mean and standard deviation is to set M=mean+var^2/mean and have some samples barely positive and the other samples be M. By making the samples correctly, you’ll get the mean and standard deviation. In the case you listed: M=4.78, 12 samples of M, and 68 samples of .001 would give mean=.718 and std.dev.=1.71. But arrival times are not accurately modeled as some 0 and some M.

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The requirement for construction of distribution with given mean and deviation is impossible to be satisfied if deviation is greater than distance from mean to any bound. To see this let's first notice that in sample

x1, x2, ..., mean, ... , xn

with mean mi = sum(x_i)/n

deviation is bounded:

dev < xmax - mean, and dev < mean - xmin. Without providing formula it is quite intuitive since the meaning of it is average deviation from the mean - how could it be greater than the maximum deviation ( max of ( mean - xmin, xmax - mean)) from the mean?

So if deviation is greater than max of [ mean - xmin, xmax - mean] then we have error. Now let's take a look at two other cases:

  • when it is in range (0, min of[ mean - xmin, xmax - mean])

  • and when it is in range (0, max of[ mean - xmin, xmax - mean]) but not in range (0, min of[ mean - xmin, xmax - mean]), ( so it is greater than one bound, but less then other one)

When it is in range (0, min of[ mean - xmin, xmax - mean])

Bernoulli distribution

This is simple to construct some distribution that yields sample with mean mi and deviation d with all values in range [xmin, xmax]. The simple case of two points distribution with

x1 = mi - d, x2 = mi + d

has the expectation of mi and deviation of d.

#include <boost/random.hpp>
#include <boost/random/bernoulli_distribution.hpp>

double generate_from_bernoulli_distribution(double mi, double d,
                                                        double a, double b) {
    if (b <= a || d < 0) throw std::out_of_range( "invalid parameters");
    if (d > std::min(mi - a, b - mi)) throw std::out_of_range( " invalid
                                                         standard deviation");
    double x1 = mi - d, x2 = mi + d;
    boost::mt19937 rng; // I don't seed it on purpouse (it's not relevant)
    boost::bernoulli_distribution<> bd;
            boost::bernoulli_distribution<> > var_ber( rng, bd);
    double bernoulli = var_ber();
    return ( x1 + bernoulli * 2 * d); // return x1 on 0, or x2 on 1

void generate_n_from_bernoulli_distribution( double mi, double d, double a, 
                                   double b, std::vector<double>& res, int n) {
    if (b <= a || d < 0) throw std::out_of_range( "invalid parameters");
    if (d > std::min(mi - a, b - mi)) throw std::out_of_range( " invalid
                                                          standard deviation");
    double x1 = mi - d, x2 = mi + d;

    boost::mt19937 rng; // I don't seed it on purpouse (it's not relevant)
    boost::bernoulli_distribution<> bd;
            boost::bernoulli_distribution<> > var_ber( rng, bd);

    int i = 0;
    for (; i < n; ++i) {
        double bernoulli = var_ber();
        res.push_back( x1 + bernoulli * 2 * d); // push_back x1 on 0, or x2 on 1


int main()
  double rc = generate_from_bernoulli_distribution( 4, 1, 0, 10);
  std::vector<double> sample;
  generate_n_from_bernoulli_distribution( 4, 1, 0, 10, sample, 100);
  return 0;

The case of Bernoulli, two points distribution is the first to consider as it has the weakest requirements. Sometimes it will be possible to draw also from other distributions, for example from uniform distribution.

Uniform distribution

The first two moments of uniform distribution (the mean and variance) in terms of its range [a, b] are given by

enter image description here

enter image description here


a = mi - alpha b = mi + alpha alpha is any real number

So there are infote number of uniform distributions that yield mean mi. All of them are just centered over mi. Additional requirement, for a variance gives us single solution for a, b:

enter image description here

enter image description here

 * generates intervals for a uniform distribution
 * with a given mean and deviation
 * @param mi    mean
 * @param d     deviation
 * @param a     left bound
 * @param b     right bound
 * @return 
void uniform_distribution_intervals( double mi, double d, double& a, double& b) {
    a = mi - d * std::sqrt(3.0);
    b = mi + d * std::sqrt(3.0);

It is clear that not always it is possible to find uniform distribution for a given mi, d, which will have left bound greater than 0. In this case

uniform_distribution_intervals( 60/84, 1.7, a, b);

unfortunately returns a = -2.9444863728670914, b = 2.9444863728670914.

when it is in range (0, max of[ mean - xmin, xmax - mean]) but not in range (0, min of[ mean - xmin, xmax - mean])

left as useful exercise

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I'm having trouble following what you're saying. I think you're trying to say that you'll run into trouble if the standard deviation is significantly larger than the mean. By "deviation", do you mean the maximum distance between any sample and the mean? –  Teepeemm Apr 22 at 16:38
no, I say standard deviation can't be max that max of ( mean - xmin, xmax - mean)). By standard deviation I mean en.wikipedia.org/wiki/Standard_deviation –  0d0a Apr 22 at 16:58

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