# mars.tensor.random.binomial#

mars.tensor.random.binomial(n, p, size=None, chunk_size=None, gpu=None, dtype=None)[source]#

Draw samples from a binomial distribution.

Samples are drawn from a binomial distribution with specified parameters, n trials and p probability of success where n an integer >= 0 and p is in the interval [0,1]. (n may be input as a float, but it is truncated to an integer in use)

Parameters
• n (int or array_like of ints) – Parameter of the distribution, >= 0. Floats are also accepted, but they will be truncated to integers.

• p (float or array_like of floats) – Parameter of the distribution, >= 0 and <=1.

• size (int or tuple of ints, optional) – Output shape. If the given shape is, e.g., (m, n, k), then m * n * k samples are drawn. If size is None (default), a single value is returned if n and p are both scalars. Otherwise, mt.broadcast(n, p).size samples are drawn.

• chunk_size (int or tuple of int or tuple of ints, optional) – Desired chunk size on each dimension

• gpu (bool, optional) – Allocate the tensor on GPU if True, False as default

• dtype (data-type, optional) – Data-type of the returned tensor.

Returns

out – Drawn samples from the parameterized binomial distribution, where each sample is equal to the number of successes over the n trials.

Return type

Tensor or scalar

scipy.stats.binom

probability density function, distribution or cumulative density function, etc.

Notes

The probability density for the binomial distribution is

$P(N) = \binom{n}{N}p^N(1-p)^{n-N},$

where $$n$$ is the number of trials, $$p$$ is the probability of success, and $$N$$ is the number of successes.

When estimating the standard error of a proportion in a population by using a random sample, the normal distribution works well unless the product p*n <=5, where p = population proportion estimate, and n = number of samples, in which case the binomial distribution is used instead. For example, a sample of 15 people shows 4 who are left handed, and 11 who are right handed. Then p = 4/15 = 27%. 0.27*15 = 4, so the binomial distribution should be used in this case.

References

1

Dalgaard, Peter, “Introductory Statistics with R”, Springer-Verlag, 2002.

2

Glantz, Stanton A. “Primer of Biostatistics.”, McGraw-Hill, Fifth Edition, 2002.

3

Lentner, Marvin, “Elementary Applied Statistics”, Bogden and Quigley, 1972.

4

Weisstein, Eric W. “Binomial Distribution.” From MathWorld–A Wolfram Web Resource. http://mathworld.wolfram.com/BinomialDistribution.html

5

Wikipedia, “Binomial distribution”, http://en.wikipedia.org/wiki/Binomial_distribution

Examples

Draw samples from the distribution:

>>> import mars.tensor as mt

>>> n, p = 10, .5  # number of trials, probability of each trial
>>> s = mt.random.binomial(n, p, 1000).execute()
# result of flipping a coin 10 times, tested 1000 times.


A real world example. A company drills 9 wild-cat oil exploration wells, each with an estimated probability of success of 0.1. All nine wells fail. What is the probability of that happening?

Let’s do 20,000 trials of the model, and count the number that generate zero positive results.

>>> (mt.sum(mt.random.binomial(9, 0.1, 20000) == 0)/20000.).execute()
# answer = 0.38885, or 38%.