Generating a mixture of binomial distributions

I want to generate a mixture of binomial distribution. Why I need it is because I want to have a normal discrete mixture of gaussian distributions. Is there any scipy library available for it or can you please guide me for the algorithm.

I know in general for predefined distributions one can use ppf. But for this function I don't think there is any straightforward way of using ppf.

Sampling from each and mixing them also seems problematic because I don't know how many instances I have to choose from different distributions.

At the end what I want to have is something like this:

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what exactly do you mean by 'generate a mixture of distributions'? –  ev-br Mar 14 '13 at 16:16
–  Cupitor Mar 14 '13 at 16:44
so you want to draw random numbers from a weighted sum of several gaussians? –  ev-br Mar 14 '13 at 16:57
but if you have cdf-s for each of them, then the cdf of a sum is a sum of cdf-s, is it not? –  ev-br Mar 14 '13 at 17:07
There is always rejection sampling –  ev-br Mar 14 '13 at 18:16

Thanks to @sega_sai,@askewchan, and @Zhenya, I made the code myself and I believ due to implementation this would be the most efficient one. There are two function the first one makes the mixtures of "binoNumber" binomial distributions all having the same N=maximum-minimum parameter and same p=0.5 but are shifted according random centers I generated for them.

``````global binoInitiated
binoInitiated=False;
def binoMixture(minimum,maximum,sampleSize):
global centers
binoNumber=10;
if (not binoInitiated):
centers=np.random.randint(minimum,maximum+1,binoNumber)
sigma=maximum-minimum-2
sam=np.array([]);
while sam.size<sampleSize:
i=np.random.choice(binoNumber);
temp=np.random.binomial(sigma, 0.5,1)+centers[i]-sigma/2+1
sam=np.append(sam,temp)
return sam
``````

This function is to draw the an approximate PDF for the distribution made beforehand. Thanks to @EnricoGiampieri who I used his code to make this part.

``````def binoMixtureDrawer(minimum,maximum):
global binoInitiated
global centers
sam=binoMixture(minimum,maximum,50000)
# this create the kernel, given an array it will estimate the probability over that values
kde = gaussian_kde( sam )
# these are the values over wich your kernel will be evaluated
dist_space = linspace( min(sam), max(sam), 500 )
# plot the results
fig.plot( dist_space, kde(dist_space),'g')
``````
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Here is an easy way of generating arbitrary mixtures of binomial (and other) distributions. It relies on a fact that if you want to get samples (Nsamp) from the mixture P(x)=sum(w[i]*P_i(x), i=1..Nmix), then you can do that by sampling Nsamp from each of the P_i(x). Then get another Nsamp samples of another random variable which is equal to i with the probability w[i]. This random variable can be used to select from which of the P_i(x) the given sample will be coming:

``````import numpy as np,numpy.random, matplotlib.pyplot as plt

#parameters of the binomial distributions: pairs of (n,p)
binomsP = np.array([.5, .5, .5])
binomsCen = np.array([15, 45, 95]) # centers of binomial distributions
binomsN = (binomsCen/binomsP).astype(int)

fractions = [0.2, 0.3, 0.5]
#mixing fractions of the binomials
assert(sum(fractions)==1)

nbinoms = len(binomsN)
npoints = 10000
cumfractions = np.cumsum(fractions)
def mapper(x):
# convert the random number between 0 and 1 to
# the ID of the distribution according to the mixing fractions
return np.digitize(x, cumfractions)

x0 = np.random.binomial(binomsN[None, :],
binomsP[None, :], size=(npoints, nbinoms))

x = x0[:, mapper(np.random.uniform(size=npoints))]
plt.hist(x, bin=150, range=(0, 150))
``````

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I don't understand your code that much and therefore I would be really grateful to get some explanation. Thank you –  Cupitor Mar 15 '13 at 1:14
@sega_sai why copy the arrays as you pass them to the `binomial` function? –  askewchan Mar 15 '13 at 4:03
@askewchan Copying was a remnant of the code when the underlying objects were lists instead of arrays. Fixed now –  sega_sai Mar 15 '13 at 10:24
@Naji I've added a bit more explanation to the answer –  sega_sai Mar 15 '13 at 10:31
That is exactly what I'm doing for the more general case of different mixing fractions. –  sega_sai Mar 15 '13 at 12:43

Unless you find a smart way of computing the inverse cdf (in which case do let us know!), the rejection sampling is a sureproof way. A wikipedia entry gives a general description. What I've found in practice, you need to be a bit careful with the 'instrumental' distribution: specifically it should not decay much faster than the target distribution -- if it does, you're likely to lose the contribution of the tails.

The way I'd do it, I'd start from a flat instrumental distribution: generate a pair of uniform random numbers `x` and `y`, where `y` is from [0, 1) and `x` is from `[0, L)`, where `L` is large enough. Then compare `y` and `cdf(x)`, repeat until convergence. If that works, you're all set. If that's not good enough, use a non-flat instrumental distribution: if the tail of the mixture is gaussian, you're probably best off using a gaussian one.

As a side note, if you're dealing with binomial distribution, you need to watch out for over/underflow --- depending on the parameters, you might need to use a gaussian approximation.

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