SciPy

scipy.stats.nct

scipy.stats.nct(*args, **kwds) = <scipy.stats._continuous_distns.nct_gen object>[source]

A non-central Student’s t continuous random variable.

As an instance of the rv_continuous class, nct object inherits from it a collection of generic methods (see below for the full list), and completes them with details specific for this particular distribution.

Notes

If \(Y\) is a standard normal random variable and \(V\) is an independent chi-square random variable (chi2) with \(k\) degrees of freedom, then

\[X = \frac{Y + c}{\sqrt{V/k}}\]

has a non-central Student’s t distribution on the real line. The degrees of freedom parameter \(k\) (denoted df in the implementation) satisfies \(k > 0\) and the noncentrality parameter \(c\) (denoted nc in the implementation) is a real number.

The probability density above is defined in the “standardized” form. To shift and/or scale the distribution use the loc and scale parameters. Specifically, nct.pdf(x, df, nc, loc, scale) is identically equivalent to nct.pdf(y, df, nc) / scale with y = (x - loc) / scale. Note that shifting the location of a distribution does not make it a “noncentral” distribution; noncentral generalizations of some distributions are available in separate classes.

Examples

>>> from scipy.stats import nct
>>> import matplotlib.pyplot as plt
>>> fig, ax = plt.subplots(1, 1)

Calculate a few first moments:

>>> df, nc = 14, 0.24
>>> mean, var, skew, kurt = nct.stats(df, nc, moments='mvsk')

Display the probability density function (pdf):

>>> x = np.linspace(nct.ppf(0.01, df, nc),
...                 nct.ppf(0.99, df, nc), 100)
>>> ax.plot(x, nct.pdf(x, df, nc),
...        'r-', lw=5, alpha=0.6, label='nct pdf')

Alternatively, the distribution object can be called (as a function) to fix the shape, location and scale parameters. This returns a “frozen” RV object holding the given parameters fixed.

Freeze the distribution and display the frozen pdf:

>>> rv = nct(df, nc)
>>> ax.plot(x, rv.pdf(x), 'k-', lw=2, label='frozen pdf')

Check accuracy of cdf and ppf:

>>> vals = nct.ppf([0.001, 0.5, 0.999], df, nc)
>>> np.allclose([0.001, 0.5, 0.999], nct.cdf(vals, df, nc))
True

Generate random numbers:

>>> r = nct.rvs(df, nc, size=1000)

And compare the histogram:

>>> ax.hist(r, density=True, histtype='stepfilled', alpha=0.2)
>>> ax.legend(loc='best', frameon=False)
>>> plt.show()
../_images/scipy-stats-nct-1.png

Methods

rvs(df, nc, loc=0, scale=1, size=1, random_state=None)

Random variates.

pdf(x, df, nc, loc=0, scale=1)

Probability density function.

logpdf(x, df, nc, loc=0, scale=1)

Log of the probability density function.

cdf(x, df, nc, loc=0, scale=1)

Cumulative distribution function.

logcdf(x, df, nc, loc=0, scale=1)

Log of the cumulative distribution function.

sf(x, df, nc, loc=0, scale=1)

Survival function (also defined as 1 - cdf, but sf is sometimes more accurate).

logsf(x, df, nc, loc=0, scale=1)

Log of the survival function.

ppf(q, df, nc, loc=0, scale=1)

Percent point function (inverse of cdf — percentiles).

isf(q, df, nc, loc=0, scale=1)

Inverse survival function (inverse of sf).

moment(n, df, nc, loc=0, scale=1)

Non-central moment of order n

stats(df, nc, loc=0, scale=1, moments=’mv’)

Mean(‘m’), variance(‘v’), skew(‘s’), and/or kurtosis(‘k’).

entropy(df, nc, loc=0, scale=1)

(Differential) entropy of the RV.

fit(data)

Parameter estimates for generic data. See scipy.stats.rv_continuous.fit for detailed documentation of the keyword arguments.

expect(func, args=(df, nc), loc=0, scale=1, lb=None, ub=None, conditional=False, **kwds)

Expected value of a function (of one argument) with respect to the distribution.

median(df, nc, loc=0, scale=1)

Median of the distribution.

mean(df, nc, loc=0, scale=1)

Mean of the distribution.

var(df, nc, loc=0, scale=1)

Variance of the distribution.

std(df, nc, loc=0, scale=1)

Standard deviation of the distribution.

interval(alpha, df, nc, loc=0, scale=1)

Endpoints of the range that contains alpha percent of the distribution

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