# Fitting For Discrete Data: Negative Binomial, Poisson, Geometric Distribution

In scipy there is no support for fitting discrete distributions using data. I know there are a lot of subject about this.

For example if i have an array like below:

x = [2,3,4,5,6,7,0,1,1,0,1,8,10,9,1,1,1,0,0]

I couldn't apply for this array:

``````from scipy.stats import nbinom
param = nbinom.fit(x)
``````

But i would like to ask you up to date, is there any way to fit for these three discrete distributions and then choose the best fit for the discrete dataset?

• What do you mean, there is no support? What about docs.scipy.org/doc/scipy/reference/generated/…? Dec 12, 2019 at 16:00
• i edited my question @mkrieger1 Dec 12, 2019 at 16:04
• What is `x` supposed to mean? What did you expect `nbinom.fit(x)` to do? `scipy.stats.nbinom` has no `fit` method. Dec 12, 2019 at 16:28
• i know that "no fit method". i want to learn is there any way to fit these discrete distributions and getting its parameters or not... @mkrieger1 Dec 12, 2019 at 16:30
• There is no generic method to fit arbitrary discrete distribution, as there is an infinite number of them, with potentially unlimited parameters. There are methods to fit a particular distribution, though, e.g. Method of Moments. If you only need these three I can show how to use it Dec 12, 2019 at 17:27

You can use Method of Moments to fit any particular distribution.

Basic idea: get empirical first, second, etc. moments, then derive distribution parameters from these moments.

So, in all these cases we only need two moments. Let's get them:

``````import pandas as pd
# for other distributions, you'll need to implement PMF
from scipy.stats import nbinom, poisson, geom

x = pd.Series(x)
mean = x.mean()
var = x.var()
likelihoods = {}  # we'll use it later
``````

Note: I used pandas instead of numpy. That is because numpy's `var()` and `std()` don't apply Bessel's correction, while pandas' do. If you have 100+ samples, there shouldn't be much difference, but on smaller samples it could be important.

Now, let's get parameters for these distributions. Negative binomial has two parameters: p, r. Let's estimate them and calculate likelihood of the dataset:

``````# From the wikipedia page, we have:
# mean = pr / (1-p)
# var = pr / (1-p)**2
# without wiki, you could use MGF to get moments; too long to explain here
# Solving for p and r, we get:

p = 1 - mean / var  # TODO: check for zero variance and limit p by [0, 1]
r = (1-p) * mean / p
``````

UPD: Wikipedia and scipy are using different definitions of p, one treating it as probability of success and another as probability of failure. So, to be consistent with scipy notion, use:

``````p = mean / var
r = p * mean / (1-p)
``````

END OF UPD

UPD2:

I'd suggest using @thilak's code log likelihood instead. It allows to avoid loss of precision, which is especially important on large samples.

END OF UPD2

Calculate likelihood:

``````likelihoods['nbinom'] = x.map(lambda val: nbinom.pmf(val, r, p)).prod()
``````

Same for Poisson, there is only one parameter:

``````# from Wikipedia,
# mean = variance = lambda. Nothing to solve here
lambda_ = mean
likelihoods['poisson'] = x.map(lambda val: poisson.pmf(val, lambda_)).prod()
``````

Same for Geometric distribution:

``````# mean = 1 / p  # this form fits the scipy definition
p = 1 / mean

likelihoods['geometric'] = x.map(lambda val: geom.pmf(val, p)).prod()
``````

``````best_fit = max(likelihoods, key=lambda x: likelihoods[x])
print("Best fit:", best_fit)
print("Likelihood:", likelihoods[best_fit])
``````

Let me know if you have any questions

• thank you so much. I have one more question, I'd appreciate it if you could answer it. I know that my dataset is discrete but let's say I wanted to see if it fits the normal distribution or not. Is it possible? Is there any way to do this like Method of Moments? Dec 12, 2019 at 20:59
• and also, can we apply this method to mixture models? like binomial mixture? Dec 12, 2019 at 21:14
• @Salih yes, it works for continuous distributions like Gaussian. In some cases, however, it is hard or even impossible to estimate all parameters. For example, for a mixture of two binomials you'll need three parameters and thus three moment; it is already unpleasant to solve. It gets even worse once you add more components into the mixture. Dec 12, 2019 at 22:03
• @Maral, how do I do it if I want to do it for binomial mixture for two? Could you please show me the way? Dec 13, 2019 at 7:16
• @Salih Sorry, but I will not. It already deviates from the scope of the original question, so maybe it's better to post a separate question for that. Also, it is actually five parameters, not three, and as I mentioned it gets really unpleasant to solve it in a closed form. In practice, mixture models are usually estimated using EM algorithm and gaussians. Dec 13, 2019 at 15:03

In addition to Marat's great answer, I would most certainly recommend taking log of the probability mass function. Some information on why log likelihood is preferred over likelihood- https://math.stackexchange.com/questions/892832/why-we-consider-log-likelihood-instead-of-likelihood-in-gaussian-distribution

I would rewrite the code for Negative Binomial to-

``````log_likelihoods = {}
log_likelihoods['nbinom'] = x.map(lambda val: nbinom.logpmf(val, r, p)).sum()
``````

Note that I have used-

``````best_fit = max(log_likelihoods, key=lambda x: log_likelihoods[x])