scipy.stats.gaussian_kde#

class scipy.stats.gaussian_kde(dataset, bw_method=None, weights=None)[source]#

Representation of a kernel-density estimate using Gaussian kernels.

Kernel density estimation is a way to estimate the probability density function (PDF) of a random variable in a non-parametric way. gaussian_kde works for both uni-variate and multi-variate data. It includes automatic bandwidth determination. The estimation works best for a unimodal distribution; bimodal or multi-modal distributions tend to be oversmoothed.

Parameters:
datasetarray_like

Datapoints to estimate from. In case of univariate data this is a 1-D array, otherwise a 2-D array with shape (# of dims, # of data).

bw_methodstr, scalar or callable, optional

The method used to calculate the estimator bandwidth. This can be ‘scott’, ‘silverman’, a scalar constant or a callable. If a scalar, this will be used directly as kde.factor. If a callable, it should take a gaussian_kde instance as only parameter and return a scalar. If None (default), ‘scott’ is used. See Notes for more details.

weightsarray_like, optional

weights of datapoints. This must be the same shape as dataset. If None (default), the samples are assumed to be equally weighted

Notes

Bandwidth selection strongly influences the estimate obtained from the KDE (much more so than the actual shape of the kernel). Bandwidth selection can be done by a “rule of thumb”, by cross-validation, by “plug-in methods” or by other means; see [3], [4] for reviews. gaussian_kde uses a rule of thumb, the default is Scott’s Rule.

Scott’s Rule [1], implemented as scotts_factor, is:

n**(-1./(d+4)),

with n the number of data points and d the number of dimensions. In the case of unequally weighted points, scotts_factor becomes:

neff**(-1./(d+4)),

with neff the effective number of datapoints. Silverman’s Rule [2], implemented as silverman_factor, is:

(n * (d + 2) / 4.)**(-1. / (d + 4)).

or in the case of unequally weighted points:

(neff * (d + 2) / 4.)**(-1. / (d + 4)).

Good general descriptions of kernel density estimation can be found in [1] and [2], the mathematics for this multi-dimensional implementation can be found in [1].

With a set of weighted samples, the effective number of datapoints neff is defined by:

neff = sum(weights)^2 / sum(weights^2)

as detailed in [5].

gaussian_kde does not currently support data that lies in a lower-dimensional subspace of the space in which it is expressed. For such data, consider performing principle component analysis / dimensionality reduction and using gaussian_kde with the transformed data.

References

[1] (1,2,3)

D.W. Scott, “Multivariate Density Estimation: Theory, Practice, and Visualization”, John Wiley & Sons, New York, Chicester, 1992.

[2] (1,2)

B.W. Silverman, “Density Estimation for Statistics and Data Analysis”, Vol. 26, Monographs on Statistics and Applied Probability, Chapman and Hall, London, 1986.

[3]

B.A. Turlach, “Bandwidth Selection in Kernel Density Estimation: A Review”, CORE and Institut de Statistique, Vol. 19, pp. 1-33, 1993.

[4]

D.M. Bashtannyk and R.J. Hyndman, “Bandwidth selection for kernel conditional density estimation”, Computational Statistics & Data Analysis, Vol. 36, pp. 279-298, 2001.

[5]

Gray P. G., 1969, Journal of the Royal Statistical Society. Series A (General), 132, 272

Examples

Generate some random two-dimensional data:

>>> import numpy as np
>>> from scipy import stats
>>> def measure(n):
...     "Measurement model, return two coupled measurements."
...     m1 = np.random.normal(size=n)
...     m2 = np.random.normal(scale=0.5, size=n)
...     return m1+m2, m1-m2
>>> m1, m2 = measure(2000)
>>> xmin = m1.min()
>>> xmax = m1.max()
>>> ymin = m2.min()
>>> ymax = m2.max()

Perform a kernel density estimate on the data:

>>> X, Y = np.mgrid[xmin:xmax:100j, ymin:ymax:100j]
>>> positions = np.vstack([X.ravel(), Y.ravel()])
>>> values = np.vstack([m1, m2])
>>> kernel = stats.gaussian_kde(values)
>>> Z = np.reshape(kernel(positions).T, X.shape)

Plot the results:

>>> import matplotlib.pyplot as plt
>>> fig, ax = plt.subplots()
>>> ax.imshow(np.rot90(Z), cmap=plt.cm.gist_earth_r,
...           extent=[xmin, xmax, ymin, ymax])
>>> ax.plot(m1, m2, 'k.', markersize=2)
>>> ax.set_xlim([xmin, xmax])
>>> ax.set_ylim([ymin, ymax])
>>> plt.show()
../../_images/scipy-stats-gaussian_kde-1.png
Attributes:
datasetndarray

The dataset with which gaussian_kde was initialized.

dint

Number of dimensions.

nint

Number of datapoints.

neffint

Effective number of datapoints.

New in version 1.2.0.

factorfloat

The bandwidth factor, obtained from kde.covariance_factor. The square of kde.factor multiplies the covariance matrix of the data in the kde estimation.

covariancendarray

The covariance matrix of dataset, scaled by the calculated bandwidth (kde.factor).

inv_covndarray

The inverse of covariance.

Methods

evaluate(points)

Evaluate the estimated pdf on a set of points.

__call__(points)

Evaluate the estimated pdf on a set of points.

integrate_gaussian(mean, cov)

Multiply estimated density by a multivariate Gaussian and integrate over the whole space.

integrate_box_1d(low, high)

Computes the integral of a 1D pdf between two bounds.

integrate_box(low_bounds, high_bounds[, maxpts])

Computes the integral of a pdf over a rectangular interval.

integrate_kde(other)

Computes the integral of the product of this kernel density estimate with another.

pdf(x)

Evaluate the estimated pdf on a provided set of points.

logpdf(x)

Evaluate the log of the estimated pdf on a provided set of points.

resample([size, seed])

Randomly sample a dataset from the estimated pdf.

set_bandwidth([bw_method])

Compute the estimator bandwidth with given method.

covariance_factor()

Computes the coefficient (kde.factor) that multiplies the data covariance matrix to obtain the kernel covariance matrix.