5

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?

9
  • What do you mean, there is no support? What about docs.scipy.org/doc/scipy/reference/generated/…?
    – mkrieger1
    Dec 12, 2019 at 16:00
  • i edited my question @mkrieger1
    – Salih
    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.
    – mkrieger1
    Dec 12, 2019 at 16:28
  • 2
    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
    – Salih
    Dec 12, 2019 at 16:30
  • 2
    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
    – Marat
    Dec 12, 2019 at 17:27

2 Answers 2

8

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()

Finally, let's get the best fit:

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

7
  • 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?
    – Salih
    Dec 12, 2019 at 20:59
  • and also, can we apply this method to mixture models? like binomial mixture?
    – Salih
    Dec 12, 2019 at 21:14
  • 1
    @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.
    – Marat
    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?
    – Salih
    Dec 13, 2019 at 7:16
  • 1
    @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.
    – Marat
    Dec 13, 2019 at 15:03
1

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-

  • logpmf instead of pmf
  • sum instead of product

And to find out the best distribution-

best_fit = max(log_likelihoods, key=lambda x: log_likelihoods[x])
print("Best fit:", best_fit)
print("log_Likelihood:", log_likelihoods[best_fit])

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.