silhouette_score#
- sklearn.metrics.silhouette_score(X, labels, *, metric='euclidean', sample_size=None, random_state=None, **kwds)[source]#
Compute the mean Silhouette Coefficient of all samples.
The Silhouette Coefficient is calculated using the mean intra-cluster distance (
a
) and the mean nearest-cluster distance (b
) for each sample. The Silhouette Coefficient for a sample is(b - a) / max(a, b)
. To clarify,b
is the distance between a sample and the nearest cluster that the sample is not a part of. Note that Silhouette Coefficient is only defined if number of labels is2 <= n_labels <= n_samples - 1
.This function returns the mean Silhouette Coefficient over all samples. To obtain the values for each sample, use
silhouette_samples
.The best value is 1 and the worst value is -1. Values near 0 indicate overlapping clusters. Negative values generally indicate that a sample has been assigned to the wrong cluster, as a different cluster is more similar.
Read more in the User Guide.
- Parameters:
- X{array-like, sparse matrix} of shape (n_samples_a, n_samples_a) if metric == “precomputed” or (n_samples_a, n_features) otherwise
An array of pairwise distances between samples, or a feature array.
- labelsarray-like of shape (n_samples,)
Predicted labels for each sample.
- metricstr or callable, default=’euclidean’
The metric to use when calculating distance between instances in a feature array. If metric is a string, it must be one of the options allowed by
pairwise_distances
. IfX
is the distance array itself, usemetric="precomputed"
.- sample_sizeint, default=None
The size of the sample to use when computing the Silhouette Coefficient on a random subset of the data. If
sample_size is None
, no sampling is used.- random_stateint, RandomState instance or None, default=None
Determines random number generation for selecting a subset of samples. Used when
sample_size is not None
. Pass an int for reproducible results across multiple function calls. See Glossary.- **kwdsoptional keyword parameters
Any further parameters are passed directly to the distance function. If using a scipy.spatial.distance metric, the parameters are still metric dependent. See the scipy docs for usage examples.
- Returns:
- silhouettefloat
Mean Silhouette Coefficient for all samples.
References
Examples
>>> from sklearn.datasets import make_blobs >>> from sklearn.cluster import KMeans >>> from sklearn.metrics import silhouette_score >>> X, y = make_blobs(random_state=42) >>> kmeans = KMeans(n_clusters=2, random_state=42) >>> silhouette_score(X, kmeans.fit_predict(X)) np.float64(0.49...)
Gallery examples#
A demo of K-Means clustering on the handwritten digits data
demo of DBSCAN clustering algorithm
demo of affinity propagation clustering algorithm
Selecting the number of clusters with silhouette analysis on KMeans clustering
Clustering text documents using k-means