I have been looking for a way to fit data to a beta binomial distribution and estimate alpha and beta, similar to the way the vglm package in VGAM library does. I have not been able to find how to do this in python. There is a scipy.stats.beta.fit() , but nothing for a beta binomial distribution. Is there a way to do this?
2 Answers
I have not seen estimation for betabinomial in Python.
If you just want to estimate the parameters, then you can use scipy.optimize to minimize the loglikelihood function which you can write yourself or copy code after a internet search.
You can subclass rv_discrete
in order to use the framework of scipy.stats.distributions, but discrete distributions in scipy do not have a fit
method.
If you want to use statsmodels, then you could subclass GenericLikelihoodModel
http://statsmodels.sourceforge.net/devel/dev/generated/statsmodels.base.model.GenericLikelihoodModel.html which uses scipy.optimize but defines most of the things we need for Maximum Likelihood estimations.
However, you need to write the code for the loglikelihood function. This would provide the usual maximum likelihood results such as standard errors for the parameters and various tests.
If you need betabinomial regression, then the mean variance parameterization as used in the R package gamlss would be more common, and can reuse the link
functions to constrain the parameters to be in the valid domain.
As a related example: This is the gist with the GenericLikelihoodModel prototype that lead to a pull request for BetaRegression for statsmodels: http://gist.github.com/brentp/089c7d6d69d78d26437f

1scipy has scipy.stats.beta.fit(). What would be the difference between the alpha and beta parameters of this and something built for the beta binomial? Commented Feb 9, 2015 at 17:05

I never tried, so I'm basing it on comparing the wikipedia description of beta and betabinomial. I think, if
n
is constant, then the alpha and beta estimates should be the same. Ifn
fluctuates, then estimating betabinomial would have a different weighting of the observations than estimating beta, where the weights will depend on the size of n. A proportion based on a larger n would have a smaller variance and would have more weight than a proportion based on a smaller n.– JosefCommented Feb 10, 2015 at 4:18 
1The beta distribution (implemented in scipy.stats.beta) has support in the range [0,1], while the betabinomial distribution has support in the integers. They are two completely different distributions for two completely different types of data; you cannot fit betabinomial data using a beta distribution. (Think of the betabinomial distribution as a binomial distribution in which you don't precisely know the success probability.)– DannyCommented Sep 29, 2015 at 11:27

I mentioned betaregression as an example of implementing a maximum likelihood model. However, if we divide (beta)binomial count data by the exposure (number of trials), then we get a proportion that we could fit with a beta distribution assuming it is a good approximation to the underlying distribution of the proportions.– JosefCommented Sep 29, 2015 at 12:26