# Implementing the Central Limit Theorem - Which Random Number Generator?

so basically I'm trying to run an stochastic experiment. It's very simple. Basically I wanted to see if what the central limit theorem says holds.

So simply put the idea of the central limit theorem is, that if we sample infinite samples of the same size from our stochastic experiment, the means of those samples are normally distributed.

So consider a dice. That dice is a magic dice and if you throw it, you can only get a 1,3,4 or 6. So you can't get a 2 and a 5. The probabilities are as follows:

``````P = 2/6
P = 1/6
P = 1/6
P = 2/6
``````

Now if we take a sample size of 4, i.e. we throw the dice 4 times, write down what we got, take the mean and do that for lets say 100'000 times, we should, when plotted as an histogram, see a normal distribution.

I implemented that like this using python:

``````""" Set up the probability space """
experiment = [1,1,3,4,6,6]

""" Experiment configuration """
n = 4
m = 100000
bins = 20

def throwDice():
result = []

for i in range(0,n):
k = randrange(0,6)
print(k)
result.append(experiment[k])

return result

def sampleMeans():
means = []

for i in range(0,m):
means.append(sum(throwDice())/4)

return means

def createHistrogram():
means = sampleMeans()

plt.hist(means, bins)
plt.show()

""" Run he experiment """
createHistrogram()
``````

which got me this it's not surprising, that we have "holes" in e.g. 2.75 and 4.75 since we are missing 2 and 5 i.e. there are less possible samples which have a mean of 2.75 and 4.75. Same argument can be done for the others.

Now while everything looks good, my question is actually about the random generator of python. Is it fine to do it like this? What kind of random number generator would be best suited for such a simple "numerical experiment"?

• First: You don't let the sample size go to infinity but the amount of samples. Second: I just assumed that if one generates the data for a stochastic numerical experiment using a RNG, one has to make sure it doesn't introduce a bias. I'm not talking about a bias inherent to a specific RNG. You pointed out correctly in another comment, that the CLT doesn't restrict the type of distribution we pull data from, so it's unlikely one runs into a problem here. I'm still new to stochastic and especially coding stochastic experiments so I wasn't sure if my data generation is valid. Aug 4, 2020 at 8:24
• Also: Yeah true the sample size is hardcoded - it was late. I actually wanted to make it variable but in the end, so that's a "bug" but it doesn't matter. Aug 4, 2020 at 8:29
• I want to add: If you increase the sampel size n, you get closer to the normal distribution. So it's a nicer fit - you make the error smaller but the limit in the theorem is about the number of such samples. Aug 4, 2020 at 8:48

According to the documentation Python random, the `random` library uses `Almost all module functions depend on the basic function random(), which generates a random float uniformly in the semi-open range [0.0, 1.0)`, so it's Uniform distribution.
Since most modules are pseudo-random, it is not good to confirm your experiment (because it is either follow or not follow the distribution). I think you should generate pure random number from `random.org` to test the result.