scipy.stats.dirichlet#

scipy.stats.dirichlet = <scipy.stats._multivariate.dirichlet_gen object>[source]#

A Dirichlet random variable.

The alpha keyword specifies the concentration parameters of the distribution.

New in version 0.15.0.

Parameters
xarray_like

Quantiles, with the last axis of x denoting the components.

alphaarray_like

The concentration parameters. The number of entries determines the dimensionality of the distribution.

random_state{None, int, numpy.random.Generator,

If seed is None (or np.random), the numpy.random.RandomState singleton is used. If seed is an int, a new RandomState instance is used, seeded with seed. If seed is already a Generator or RandomState instance then that instance is used.

Alternatively, the object may be called (as a function) to fix
concentration parameters, returning a “frozen” Dirichlet
random variable:
rv = dirichlet(alpha)
  • Frozen object with the same methods but holding the given concentration parameters fixed.

Notes

Each \(\alpha\) entry must be positive. The distribution has only support on the simplex defined by

\[\sum_{i=1}^{K} x_i = 1\]

where \(0 < x_i < 1\).

If the quantiles don’t lie within the simplex, a ValueError is raised.

The probability density function for dirichlet is

\[f(x) = \frac{1}{\mathrm{B}(\boldsymbol\alpha)} \prod_{i=1}^K x_i^{\alpha_i - 1}\]

where

\[\mathrm{B}(\boldsymbol\alpha) = \frac{\prod_{i=1}^K \Gamma(\alpha_i)} {\Gamma\bigl(\sum_{i=1}^K \alpha_i\bigr)}\]

and \(\boldsymbol\alpha=(\alpha_1,\ldots,\alpha_K)\), the concentration parameters and \(K\) is the dimension of the space where \(x\) takes values.

Note that the dirichlet interface is somewhat inconsistent. The array returned by the rvs function is transposed with respect to the format expected by the pdf and logpdf.

Examples

>>> from scipy.stats import dirichlet

Generate a dirichlet random variable

>>> quantiles = np.array([0.2, 0.2, 0.6])  # specify quantiles
>>> alpha = np.array([0.4, 5, 15])  # specify concentration parameters
>>> dirichlet.pdf(quantiles, alpha)
0.2843831684937255

The same PDF but following a log scale

>>> dirichlet.logpdf(quantiles, alpha)
-1.2574327653159187

Once we specify the dirichlet distribution we can then calculate quantities of interest

>>> dirichlet.mean(alpha)  # get the mean of the distribution
array([0.01960784, 0.24509804, 0.73529412])
>>> dirichlet.var(alpha) # get variance
array([0.00089829, 0.00864603, 0.00909517])
>>> dirichlet.entropy(alpha)  # calculate the differential entropy
-4.3280162474082715

We can also return random samples from the distribution

>>> dirichlet.rvs(alpha, size=1, random_state=1)
array([[0.00766178, 0.24670518, 0.74563305]])
>>> dirichlet.rvs(alpha, size=2, random_state=2)
array([[0.01639427, 0.1292273 , 0.85437844],
       [0.00156917, 0.19033695, 0.80809388]])

Methods

``pdf(x, alpha)``

Probability density function.

``logpdf(x, alpha)``

Log of the probability density function.

``rvs(alpha, size=1, random_state=None)``

Draw random samples from a Dirichlet distribution.

``mean(alpha)``

The mean of the Dirichlet distribution

``var(alpha)``

The variance of the Dirichlet distribution

``entropy(alpha)``

Compute the differential entropy of the Dirichlet distribution.