| layout | title | displayTitle |
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global |
Clustering |
Clustering |
This page describes clustering algorithms in MLlib. The guide for clustering in the RDD-based API also has relevant information about these algorithms.
Table of Contents
- This will become a table of contents (this text will be scraped). {:toc}
k-means is one of the most commonly used clustering algorithms that clusters the data points into a predefined number of clusters. The MLlib implementation includes a parallelized variant of the k-means++ method called kmeans||.
KMeans is implemented as an Estimator and generates a KMeansModel as the base model.
| Param name | Type(s) | Default | Description |
|---|---|---|---|
| featuresCol | Vector | "features" | Feature vector |
| Param name | Type(s) | Default | Description |
|---|---|---|---|
| predictionCol | Int | "prediction" | Predicted cluster center |
Examples
{% include_example scala/org/apache/spark/examples/ml/KMeansExample.scala %}
{% include_example java/org/apache/spark/examples/ml/JavaKMeansExample.java %}
{% include_example python/ml/kmeans_example.py %}
Refer to the R API docs for more details.
{% include_example r/ml/kmeans.R %}
LDA is implemented as an Estimator that supports both EMLDAOptimizer and OnlineLDAOptimizer,
and generates a LDAModel as the base model. Expert users may cast a LDAModel generated by
EMLDAOptimizer to a DistributedLDAModel if needed.
Examples
Refer to the Scala API docs for more details.
{% include_example scala/org/apache/spark/examples/ml/LDAExample.scala %}
Refer to the Java API docs for more details.
{% include_example java/org/apache/spark/examples/ml/JavaLDAExample.java %}
Refer to the Python API docs for more details.
{% include_example python/ml/lda_example.py %}
Refer to the R API docs for more details.
{% include_example r/ml/lda.R %}
Bisecting k-means is a kind of hierarchical clustering using a divisive (or "top-down") approach: all observations start in one cluster, and splits are performed recursively as one moves down the hierarchy.
Bisecting K-means can often be much faster than regular K-means, but it will generally produce a different clustering.
BisectingKMeans is implemented as an Estimator and generates a BisectingKMeansModel as the base model.
Examples
{% include_example scala/org/apache/spark/examples/ml/BisectingKMeansExample.scala %}
{% include_example java/org/apache/spark/examples/ml/JavaBisectingKMeansExample.java %}
{% include_example python/ml/bisecting_k_means_example.py %}
Refer to the R API docs for more details.
{% include_example r/ml/bisectingKmeans.R %}
A Gaussian Mixture Model
represents a composite distribution whereby points are drawn from one of k Gaussian sub-distributions,
each with its own probability. The spark.ml implementation uses the
expectation-maximization
algorithm to induce the maximum-likelihood model given a set of samples.
GaussianMixture is implemented as an Estimator and generates a GaussianMixtureModel as the base
model.
| Param name | Type(s) | Default | Description |
|---|---|---|---|
| featuresCol | Vector | "features" | Feature vector |
| Param name | Type(s) | Default | Description |
|---|---|---|---|
| predictionCol | Int | "prediction" | Predicted cluster center |
| probabilityCol | Vector | "probability" | Probability of each cluster |
Examples
{% include_example scala/org/apache/spark/examples/ml/GaussianMixtureExample.scala %}
{% include_example java/org/apache/spark/examples/ml/JavaGaussianMixtureExample.java %}
{% include_example python/ml/gaussian_mixture_example.py %}
Refer to the R API docs for more details.
{% include_example r/ml/gaussianMixture.R %}