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I would like my program to automatically choose the distribution that has the best fitness and use this distribution's probability density function to calculate the probability

  1. Use scipy.stats.rv_continuous.fit to get the parameter of fitting, e.g.

    paras = scipy.stats.norm.fit(data_array)

  2. Use scipy.stats.kstest to test the fitness

    fitness = scipy.stats.kstest(data_array, paras)

  3. Choose the distribution that gives the lowest kstest score

  4. Calculate the probability, e.g.

    scipy.stats.norm.pdf(my_values, paras)

I am not sure whether this is a rigorously correct way to choose the best-fit distribution. Currently it works well for normal distribution.

My problem is how to parse the argument to scipy.stats.rv_continuous.pdf(). For some distributions there are three parameters calculated from scipy.stats.rv_continuous.fit(), including the shape, loc and scale. I tried to parse directly like

scipy.stats.rv_continuous.pdf(my_values, paras[0], paras[1], paras[2])

this will give me two values for pdf for one point.

I also tried to parse in this way

scipy.stats.rv_continuous.pdf(my_values, paras[0], paras[1], paras[2])

But the outcome is wierd. Does anybody ever want to do something like this and meet some problem of the same kind?

My goal is to replace the gaussian with any better distributions in the Naive Bayesian classification, in hope to improve the prediction accuracy.

share|improve this question
If your main question is about how to choose the most "rigorously correct way to choose the best-fit distribution", rather than how to code the process up in scipy, you might be better off asking on Cross Validated – Marius Jan 19 '14 at 23:12
Hi @GeauxEric, did you ever solve this? I would like to do something similar (moving to sums of various distributions if simple distributions fail and final kernel density estimation). The answer to your variable parameter problem is to use *paras in the function call. Beyond that I'm thinking that a general and robust solution to this is not a trivial problem. – Ed Smith Jun 22 '15 at 13:52
Hi @Ed Smith, I did not manage to solve the problem automatically. Since I found several distributions are enough to describe my model, I pass the arguments of those distributions manually. – GeauxEric Jun 27 '15 at 14:55
Hi @GeauxEric, thanks for the reply. I think I'll end up with a similar solution... – Ed Smith Jun 29 '15 at 7:24

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