Minimum Covariance Determinant (MCD): robust estimator of covariance.
The Minimum Covariance Determinant covariance estimator is to be applied on Gaussian-distributed data, but could still be relevant on data drawn from a unimodal, symmetric distribution. It is not meant to be used with multi-modal data (the algorithm used to fit a MinCovDet object is likely to fail in such a case). One should consider projection pursuit methods to deal with multi-modal datasets.
Read more in the User Guide.
Specify if the estimated precision is stored.
If True, the support of the robust location and the covariance estimates is computed, and a covariance estimate is recomputed from it, without centering the data. Useful to work with data whose mean is significantly equal to zero but is not exactly zero. If False, the robust location and covariance are directly computed with the FastMCD algorithm without additional treatment.
The proportion of points to be included in the support of the raw MCD estimate. Default is None, which implies that the minimum value of support_fraction will be used within the algorithm: (n_samples + n_features + 1) / 2 * n_samples. The parameter must be in the range (0, 1].
Determines the pseudo random number generator for shuffling the data. Pass an int for reproducible results across multiple function calls. See Glossary.
The raw robust estimated location before correction and re-weighting.
The raw robust estimated covariance before correction and re-weighting.
A mask of the observations that have been used to compute the raw robust estimates of location and shape, before correction and re-weighting.
Estimated robust location.
For an example of comparing raw robust estimates with the true location and covariance, refer to Robust vs Empirical covariance estimate.
Estimated robust covariance matrix.
Estimated pseudo inverse matrix. (stored only if store_precision is True)
A mask of the observations that have been used to compute the robust estimates of location and shape.
Mahalanobis distances of the training set (on which fit is called) observations.
Number of features seen during fit.
Added in version 0.24.
n_features_in_,)
Names of features seen during fit. Defined only when X has feature names that are all strings.
Added in version 1.0.
References
[Rouseeuw1984]P. J. Rousseeuw. Least median of squares regression. J. Am Stat Ass, 79:871, 1984.
[Rousseeuw]A Fast Algorithm for the Minimum Covariance Determinant Estimator, 1999, American Statistical Association and the American Society for Quality, TECHNOMETRICS
[ButlerDavies]R. W. Butler, P. L. Davies and M. Jhun, Asymptotics For The Minimum Covariance Determinant Estimator, The Annals of Statistics, 1993, Vol. 21, No. 3, 1385-1400
Examples
>>> import numpy as np
>>> from sklearn.covariance import MinCovDet
>>> from sklearn.datasets import make_gaussian_quantiles
>>> real_cov = np.array([[.8, .3],
... [.3, .4]])
>>> rng = np.random.RandomState(0)
>>> X = rng.multivariate_normal(mean=[0, 0],
... cov=real_cov,
... size=500)
>>> cov = MinCovDet(random_state=0).fit(X)
>>> cov.covariance_
array([[0.7411, 0.2535],
[0.2535, 0.3053]])
>>> cov.location_
array([0.0813 , 0.0427])
Apply a correction to raw Minimum Covariance Determinant estimates.
Correction using the empirical correction factor suggested by Rousseeuw and Van Driessen in [RVD].
The data matrix, with p features and n samples. The data set must be the one which was used to compute the raw estimates.
Corrected robust covariance estimate.
References
[RVD]A Fast Algorithm for the Minimum Covariance Determinant Estimator, 1999, American Statistical Association and the American Society for Quality, TECHNOMETRICS
Compute the Mean Squared Error between two covariance estimators.
The covariance to compare with.
The type of norm used to compute the error. Available error types: - ‘frobenius’ (default): sqrt(tr(A^t.A)) - ‘spectral’: sqrt(max(eigenvalues(A^t.A)) where A is the error (comp_cov - self.covariance_).
If True (default), the squared error norm is divided by n_features. If False, the squared error norm is not rescaled.
Whether to compute the squared error norm or the error norm. If True (default), the squared error norm is returned. If False, the error norm is returned.
The Mean Squared Error (in the sense of the Frobenius norm) between self and comp_cov covariance estimators.
Fit a Minimum Covariance Determinant with the FastMCD algorithm.
Training data, where n_samples is the number of samples and n_features is the number of features.
Not used, present for API consistency by convention.
Returns the instance itself.
Get metadata routing of this object.
Please check User Guide on how the routing mechanism works.
A MetadataRequest encapsulating routing information.
Get parameters for this estimator.
If True, will return the parameters for this estimator and contained subobjects that are estimators.
Parameter names mapped to their values.
Getter for the precision matrix.
The precision matrix associated to the current covariance object.
Compute the squared Mahalanobis distances of given observations.
For a detailed example of how outliers affects the Mahalanobis distance, see Robust covariance estimation and Mahalanobis distances relevance.
The observations, the Mahalanobis distances of the which we compute. Observations are assumed to be drawn from the same distribution than the data used in fit.
Squared Mahalanobis distances of the observations.
Re-weight raw Minimum Covariance Determinant estimates.
Re-weight observations using Rousseeuw’s method (equivalent to deleting outlying observations from the data set before computing location and covariance estimates) described in [RVDriessen].
The data matrix, with p features and n samples. The data set must be the one which was used to compute the raw estimates.
Re-weighted robust location estimate.
Re-weighted robust covariance estimate.
A mask of the observations that have been used to compute the re-weighted robust location and covariance estimates.
References
[RVDriessen]A Fast Algorithm for the Minimum Covariance Determinant Estimator, 1999, American Statistical Association and the American Society for Quality, TECHNOMETRICS
Compute the log-likelihood of X_test under the estimated Gaussian model.
The Gaussian model is defined by its mean and covariance matrix which are represented respectively by self.location_ and self.covariance_.
Test data of which we compute the likelihood, where n_samples is the number of samples and n_features is the number of features. X_test is assumed to be drawn from the same distribution than the data used in fit (including centering).
Not used, present for API consistency by convention.
The log-likelihood of X_test with self.location_ and self.covariance_ as estimators of the Gaussian model mean and covariance matrix respectively.
Set the parameters of this estimator.
The method works on simple estimators as well as on nested objects (such as Pipeline). The latter have parameters of the form <component>__<parameter> so that it’s possible to update each component of a nested object.
Estimator parameters.
Estimator instance.
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